LAND Area 241,752 sq km Highest Point Ben Nevis 1,343 m above sea level Lowest Point Holme Fen 3 m below sea level |
CLIMATE Average Temperatures London January 4 ° C |
July 18 ° C Edinburgh January 3 ° C July 15 ° C Average Annual Precipitation London 590 mm Edinburgh 680 mm |
POPULATION Population 58,395,000 (1994 estimate) Population Density 242 persons / sq km (1994 estimate) Urban / Rural population 92% Urban 8% Rural Largest Cities London (Greater) 6,933,000 Birmingham 1,017,000 Leeds 724,500 Glasgow 681,000 Ethnic Groups 94,5% English, Scottish, Welsh, or Irish 5,5% Other Languages Official Language English Other Languages Welsh, Scots-Gaelic, other minority languages Religions 54% Anglicanism 13% Roman Catholicism 33% Other including other Protestant denominations, Islam, Judaism, Hinduism, and Sikhism |
ECONOMY
Gross Domestic Product
US $ 1,023,900,000,000 (1994)
Chief Economic Products
Agriculture
Wheat, barley, potatoes, sugar beets, oilseed rape, livestock, animal products.
Fishing
Mackerel, herring, cod, plaice
Mining
Coal, limestone, petroleum and natural gas.
Manufacturing
Machinery and transport equipment, food products, chemical products, minerals and metal products.
Employment Statistics
58% Trade and Services
23% Manufacturing and Industry
16% Business and Finance
2% Agriculture, Forestry, and Fishing
1% Military and Defense
Major Exports
Industrial and electrical machinery, automatic data processing equipment, road vehicles, petroleum.
Major Imports
Road vehicles, industrial and electrical machinery, automatic data processing equipment, petroleum, paper and paperboard, textiles, food.
Major Trading Partners
Germany, the United States, France, the Netherlands, Italy, Japan
Text B: "HISTORY OF LONDON"
The Romans were the first to settle and occupy the Celtic fortress of Londinium. Construction of a bridge in 100 AD made London an important junction: it soon became a busy commercial and administrative settlement, and in the 2nd century AD a wall was built round the city.
The Roman Empire fell in the 5th century. London have maintained its trading activity. In the 9th century Danish invaders destroyed much of the city. They were followed by the Saxons led by King Alfred the Great, who entered the city in 886. The Danes remained a powerful force in England, however, and it was not until the reign of Edward the Confessor, which began in 1042, that civic stability was re-established, to be cemented by the Norman Conquest in 1066.
William the Conqueror centred his power at the Tower of London, and his White Tower is still the heart of this impressive monument.
The City soon united its economic power with political independence. Late in the 12th century it elected its own Lord Mayor. From 1351 it elected its own council, and by the end of the 14th century the reigning sovereign could not enter the City without permission.
In the reign of Elizabeth I had the arts a renaissance with such great dramatists as Shakespeare, Marlowe, and Ben Jonson.
In 1665, London had been devastated first by the Great Plague, and then by the Fire of London, which destroyed most of the city the following year. During the reconstruction of the city, following the original street pattern, the architect Sir Christopher Wren was given responsibility for the design of a number of State-funded buildings, including St. Paul's Cathedral.
The western part of London was developed under the Hanoverian Kings: great squares were laid out such as those of Grosvenor, Cavendish, Berkeley, and Hanover, and more bridges were built across the river. Public services were improved, such as the water supply and sewerage systems, and the streets were paved.
In the 19th century London's population began to rise still more rapidly: it increased sixfold over the century as a whole, thanks to influx from all over the British Isles, from Britain's colonies, and from continental Europe. The Industrial Revolution was creating huge numbers of jobs, but never enough to satisfy the hopes of all the poor people who came to the capital. The novels of Charles Dickens tell us about the social problems of that period.
The First World War had little effect on London, but the Depression that followed in the late 1920s and early 1930s hit the whole country, including the capital. There were hunger marches and riots. London was to pay far more dearly during World War II. The intensive bombing of London (The Blitz) in 1940-1941 took the lives of 10,000 people and left 17,000 injured. Countless historic buildings were damaged, including the Houses of Parliament.
After the war London was to re-emerge as a radically different city. The docks had been so severely damaged that reconstruction, a very expensive process, was not reasonable. By the end of the 1950s most of the war damage had been repaired. New skyscrapers were built, outdoing each other in height and spectacular design. The 30-storey Post Office Tower was built in 1965. It is 189 m high. Other significant post-war developments include the 183 m National Westminster Bank Building (1979); and Britain's highest building, the 244 m Canary Wharf Tower on the Docklands site, near to a new City airport.
General understanding:
1) What was the original name of London? Why was it so important for Romans?
2) Who was King Alfred the Great? When did he enter the city?
3) What is still the reminder of William the Conqueror?
4) How was Britain governed in 12th-14th centuries?
5) How did plague influence the history of London?
6) Who was in charge of the reconstruction of the city? Why did it need reconstruction?
7) Why did the population of London grow in the 19 th century?
8) How did the First World War affect the history of London? What about the WWII?
9) How did London change after the WWII?
10) What are the names of skyscraper buildings in London?
GRAMMAR
Модальні дієслова та їх еквіваленти.
Модальні дієслова показують ставлення мовця до дії, вираженої інфінітивом. Наприклад, порівняйте:
You can speak English. Ви можете (умієте) говорити по-англійськи.
You must speak English. Ви повинні говорити по-англійськи.
You may speak English. Ви можете говорити по-англійськи. (Вас зрозуміють.)
Як бачимо, в одному і тому ж реченні зміна модального дієслова змінює зміст усього речення, тобто змінюється ставлення до дії, вираженої інфінітивом.
Модальні дієслова не мають форм у всіх часах, для цього вживаються їх еквіваленти (замінники).
Питальні і негативні пропозиції з модальними дієсловами будуються без допоміжних дієслів: Can you help me? - Yes, I can. - No, I can't. Ви можете допомогти мені? - Так. - Ні.
До основних модальним відносяться дієслова:
can - могти, бути в стані, could - минулий час
передбачає наявність фізичної, розумової та інших можливостей, що дозволяють зробити що-небудь:
I can swim. - Я можу (я вмію) плавати.
I could translate this text .- (Я міг, був у стані) перевести цей текст.
У майбутньому у дієслова can є замінник - конструкція to be able to (бути в змозі що-небудь зробити): I shall be able to help you when I am free. - Я зможу допомогти тобі, коли звільнюся.
may - мати можливість, отримати дозвіл (робити що-небудь),
might - минулий час
May I help you? - Можна вам допомогти? - Yes, you may. - Так, можна.
У майбутньому часі у модального дієслова may є замінник - конструкція to be allowed to (Отримати дозвіл зробити що-небудь).
Чи не will be allowed to take the book. Йому дозволять взяти книгу.
must - повинен, зобов'язаний.
You must write it down now. - Ви повинні написати це зараз.
Замінниками дієслова must є дієслова to have to і to be to, які мають деякі додаткові відтінками значення. Дієслово to have to означає повинність, викликане обставинами, вимушену необхідність, у той час як дієслово to be to - повинність, пов'язане з розкладом, планом або заздалегідь зробленої домовленістю.
She had to stay at home. - Вона змушена була (їй довелося) залишитися вдома.
The train was to arrive at 8 in the evening. - Поїзд повинен був прибути о 8 вечора. (За розкладом).
Після модальних дієслів і деяких їхніх еквівалентів інфінітив вживається без частки to.
Замінниками модального дієслова must є також модальні дієслова ought to, should (у значенні ради, рекомендації, докору) і shall (запитується дозвіл на здійснення дії).
You should enter the Institute. Вам слід вступити до інституту (рекомендація, рада),
У поєднанні з перфектний інфінітивом дієслово should висловлює жаль про невиконане дії і перекладається «слід було б».
You should have helped them. Вам слід було б допомогти їм. (Але ви не зробили цього).
Shall I read? Мені слід читати?
Модальне дієслово would може мати такі
значення:
1) Чемна прохання. Would you help me? He допоможете ви мені?
2) Повторюваність дії в минулому. Чи не would often help me. Він, бувало, часто допомагав мені.
3) Стійке небажання здійснювати будь-які дії. Чи не wouldn't listen to me. Він ніяк не хотів слухати мене. -
Модальне дієслово need - «треба, треба» вживається, в основному, в негативних пропозиціях. You needn't do it now. Вам не потрібно робити це зараз.
Exercise 6.7. Analyse the use of modal verbs and translate the following sentences:
1. Who can answer my question?
2. Nobody could translate this text.
3. He ought to do this task at once.
4. Must I attend this meeting? - No, you needn't.
5. You should have shown your notes to the teacher.
6. I asked him, but he wouldn't listen to me.
7. They should visit her, she is in the hospital.
8. Last summer we would often go to the country.
9. Your son can do this work himself.
10. Would you tell me the way to the station?
11. Your friend might have informed us.
12. May I leave for a while? - Yes, you may.
13. She should be more attentive at the lessons.
14. You needn't come so early.
Exercise 6.8. Insert necessary modal verbs:
1. I. .. not go to the theatre with them last night, I. .. revise the grammar rules and the words for the test. 2. My friend lives a long way from his office and ... get up early. 3. All of us ... be in time for classes. 4. When my friend has his English, he ... stay at the office after work. He (not) ... stay at the office on Tuesday, Thursday and Saturday and ... get home early. 5 .... you ... work hard to do well in your English? 6. «... we discuss this question now? »« No, we ... We ... do it tomorrow afternoon. »7. I'm glad you ... come. 8. «... you ... come and have dinner with us tomorrow? »« I'd love to. »9. «Please send them this article.» «Oh, ... I do it now? »
Exercise 6.9. Translate into English using modal verbs:
1. Ми обов'язково повинні писати диктант сьогодні? - Так, завтра ми будемо вчити нові слова. 2. Вчора мені довелося відповісти на всі ці листи. 3. Віктора теж запросити на обід? - Так, зробіть це, будь ласка. 4. Вам довелося залишитися вдома, бо була погана погода? 5. Ви обов'язково повинні прийти і подивитися нашу нову квартиру .- З задоволенням. 6. Я радий, що мені не довелося закінчувати цю роботу вчора. 7. Я не люблю пізно лягати спати, але іноді мені доводиться. 8. Можна мені піти погуляти зараз? - Ні, не можна. Ти повинен скоро лягати спати. 9. Вам слід відвідати вашого друга. Він вчора не прийшов на урок. 10. Чому ти не прийшла? - Я не могла, я повинна була допомогти мамі по будинку. 11. Вам не потрібно йти до бібліотеки, у нас багато книг будинку, і ви можете взяти будь-яку, яку хочете.
UNIT 7
THE UNITED STATES OF AMERICA
I. Приголосні звуки [q], [¶].
II. Text A: «The USA»,
Text В: «Transport Sustem of the USA».
III. § 1. Узгодження часів у головному і підрядному реченнях.
§ 2. Пасивний стан
Приголосний звук [q]
У російській мові подібного звуку немає. Звук [q] - глухий. При його вимові мову розпластаний і не напружений, кінчик язика утворює вузьку щілину плоску, нещільно притискаючись до нього. У цю щілину з силою проходить струмінь повітря. Кінчик мови не повинен сильно виступати за верхні зуби або занадто щільно притискатися до губ. Зуби мають бути оголені, особливо нижні, так, щоб нижня губа не стосувалася верхніх зубів і не наближалася до них.
Приголосний звук [¶]
При вимові звуку [¶] органи мови займають таке ж положення, як і при вимові звуку [q]. Звук [¶] відрізняється від звуку [q] лише дзвінкістю.
Exercise A through - fifth - myth thief - booth - tooth thank - think - thought theatre - theory - theft | threat - three - thunder threw - throat - thumb faith - heart - path bath - booth - broth Exercise З |
Exercise У thermometer - thick - thin thirst - thirty - thorough | this - that - these - those there - though them - they - the |
Text A: «THE UNITED STATES OF AMERICA»
The United States of America is the 4 th largest country in the world after Russia, Canada and China. It occupies the central part of the North American continent.
The United States of America is a federal republic, consisting of 50 states including the states of Alaska and Hawaii. Outlying areas include Puerto Rico, American Samoa, Guam, and the US Virgin Islands.
The northern boundary is partly formed by the Great Lakes and the St Lawrence River; the southern boundary is partly formed by the Rio Grande. United States also has a sea-border with Russia.
The total area of the United States (including the District of Columbia) is about 9,809,000 sq km.
The country is washed by 3 oceans: the Arctic, the Atlantic and the Pacific. The country has many lakes, with the Great Lakes included. There are also many rivers on the US territory. The longest of them are the Mississippi, the Missouri, the Columbia, the Rio Grande and some others. On the US territory there are mountains and lowlands. The highest mountains are the Rocky Mountains, the Cordillera and the Sierra Nevada. The highest peak, Mount McKinley, is located in Alaska.
The climate conditions are rather different. The country is rich in natural and mineral resources: oil, gas, iron ore, coal and various metals.
The USA is a highly developed industrial and agricultural country. The main industrial branches are aircraft, rocket, automobile, electronics, radio-engineering and others.
Americans are made up from nearly all races and nations. The country population is over 250 min. The national symbol of the USA is its national flag «Stars and Stripes», having 50 white stars and 13 white and red stripes on its field, symbolising the number of the original and present day states.
Officially the country comprises 50 states and one District of Columbia. The states differ in size, population and economic development. Each state has its own capital. The capital of the USA is Washington. It is situated in the District of Columbia on the banks of the Potomac river and is named after the 1 st US President - George Washington. There are many large cities in the country: New York, Los Angeles, Chicago, Philadelphia, Detroit, San Francisco-, Cleveland and some others.
The United States of America is a federal state, headed by the President. According to the US Constitution the powers of the Government are divided into 3 branches: legislative, executive and judicial.
The legislative power belongs to the Congress consisting of the Senate and the House of Representatives. The Senate represents the states while the House of Representatives - the population. The executive power belongs to the President and his Administration (Vice-President and Cabinet of Ministers). The judicial power belongs to the Supreme Court and the system of Federal, state and district courts.
There are several political parties in the USA, the largest of them are the Republican (symbolised by a donkey) and the Democratic (symbolised by an elephant).
Vocabulary:
outlying areas - зовнішні території
District of Columbia - округ Колумбія
to pass - проходити через
frontier - кордон
to include - включати
lowlands - низини
peak - вершина, пік
to be located - розташовуватися
aircraft - повітряне судно
to be made up from - бути складеним, складатися з
stripe - смуга
to symbolize - символізувати
legislative power - законодавча влада
to represent - представляти
to belong - належати
donkey - осел
ADD TO YOUR ACTIVE VOCABULARY:
a) Great Plains - Великі рівнини
Appalachian mountains - гори Аппалачі
Rocky mountains - Скелясті гори
b) driveway - проїзд, виїзд
sidewalk - тротуар
drive-thru shop - магазин, покупки в якому виробляються через вікно автомобіля
toll-road - платна дорога (магістраль)
toll-free road - безкоштовна дорога
highway, parkway, thruway - автомагістралі
turnpike - головна магістраль
shopping mall-- торговий центр
shopping plaza - відкрита торговельна площа, торговий ряд
free delivery - безкоштовна доставка
telephone order - телефонне замовлення
sale - розпродаж
discount - знижка
seasons sale - сезонний розпродаж
clearance sale - розпродаж покладів товарів
discount coupon - купон на знижку
free gift - безкоштовний подарунок
Exercise 7.1. Translate into English:
1. США - четверта за розміром країна після Росії, Канади і Китаю.
2. Зовнішні межі включають в себе Пуерто Ріко, Американське Самоа і Віргінські острова.
3.48 Штатів межують на півночі з Канадою, а на півдні з Мексикою.
4. США має морський кордон з Російською Федерацією.
6. США омивається трьома океанами: Північним Льодовитим, Атлантичним і Тихим.
7. США - високорозвинена промислова держава з безліччю галузей.
8. Аерокосмічна та електронні галузі промисловості США займають особливе місце в економіці США.
9. Кожен штат має свою столицю.
Text В: «TRANSPORT SYSTEM OF THE USA»
The development of transport facilities was very important in the growth of the United States. The first travel routes were natural waterways. No surfaced roads existed until the 1790s, when the first turnpikes were built. Besides the overland roads, many canals were constructed between the late 18th century and 1850 to link navigable rivers and lakes in the eastern United States and in the Great Lakes region. Steam railways began to appear in the East in the 1820s. The first transcontinental railway was constructed between 1862 and 1869 by the Union Pacific and Central Pacific companies, both of which received large subsidies from the federal government. Transcontinental railways were the chief means of transport used by European settlers who populated the West in the latter part of the 19th century. The railways continued to expand until 1917, when their length reached a peak of about 407,000 km. Since then motor transport became a serious competitor to the railway both for passengers and freight.
Air transport began to compete with other modes of transport after World War I. Passenger service began to gain importance in 1920s, but not until the beginning of commercial jet craft after World War II did air transport become a leading mode of travel.
During the early 1990s railways annually handled about 37,5 per cent of the total freight traffic; trucks carried 26 per cent of the freight, and oil pipelines conveyed 20 per cent. Approximately 16 per cent was shipped on inland waterways. Although the freight handled by airlines amounted to only 0,4 per cent of the total, much of the cargo consisted of high-priority or high-value items.
Private cars carry about 81 per cent of passengers. Airlines are the second leading mover of people, carrying more than 17 per cent of passengers. Buses are responsible for 1,1 per cent, and railways carry 0,6 per cent of passengers.
Roads and Railways
The transport network spreads into all sections of the country, but the web of railways and highways is much more dense in the eastern half of the United States.
In the early 1990s the United States had about 6,24 million km of streets, roads, and highways. The National Interstate Highway System, 68,449 km in length in the early 1990s, connected the nation's principal cities and carried about one-fifth of all the road and street traffic.
More than 188 million motor vehicles were registered in the early 1990s. More than three-quarters were cars - one for every two persons in the country. About one-fifth of the vehicles were lorries. Amtrak (the National Railroad Passenger Corporation), a federally subsidized concern, operates almost all the inter-city passenger trains in the United States; it carried more than 22 million passengers annually in the early 1990s.
General understanding:
1. What were the first routes in the US?
2. When was the first transcontinental railway constructed?
3. What was the length of railroads in 1917?
4. When did air transport start to gain importance?
5. How many motor vehicles were registered in US in early 90s?
6. What is Amtrak? How many passengers did it carry annually in the early 90s?
GRAMMAR
§ 1. Узгодження часів у головному і підрядному реченнях
В англійській складнопідрядному реченні з підрядним додатковим (питання «що?», «Хто?», «Чого?» І т. д.) дотримуються правила узгодження часів у головному і підрядному реченнях. Ці правила зводяться до наступного:
1. Якщо дієслово-присудок головного речення стоїть в сьогоденні або майбутньому часі, то дієслово-присудок підрядного додаткового речення може стояти в будь-якій часовій формі, необхідної глуздом, наприклад:
Чи не says you are right. - Він говорить, що ти правий.
Чи не will tell why he was not at school yesterday. - Він скаже, чому він не був у школі вчора.
2. Якщо дієслово-присудок головного речення стоїть в минулому часі (зазвичай - у Past Indefinite), то й дієслово додаткового підрядного речення повинен стояти в одному з минулих часів, в тому числі - в майбутньому з точки зору минулого (Future in the Past).
He said he would not go to school tomorrow. - Він сказав, що не піде в школу завтра.
При цьому для позначення дії, одночасного з дією, вираженим присудком головного речення, вживається Past Continuous (У російською мовою - теперішній час) або Past Indefinite.
Чи не told me he was preparing for his exam. - Він сказав мені, що готується до іспиту.
Для позначення дії, попереднього дії, вираженої присудком головного речення, зазвичай вживається Past Perfect. На російську мову дієслово-присудок підрядного в даному випадку перекладається дієсловом у минулому часі:
I didn't know he had left for Moscow. - Я не знав, що він поїхав до Москви.
При вказівці певного часу (in 1980, yesterday) попереднє час висловлюється за допомогою Past Indefinite. Наприклад: I thought you were born in 1980.
Для вираження майбутнього часу з точки зору минулого часу вживається форма Future in the Past де допоміжне дієслово wil l змінюється на would, яка на російську мову перекладається майбутнім часом:
Чи не told me that he would meet me at the Institute. - Він сказав мені, що зустріне мене в інституті.
Exercise 7.2. Open the brackets. Pay attention to the Sequence of Tenses. Translate the sentences into English.
1. I did not know that you already (to read) this book 2. He did it better than I (to expect). 3. He said that the bus (to be) here soon. 4.1 think it all happened soon after the meeting (to end). 5. They decided that they (to bring) us all the necessary books. 6. He said that he (can) not do it without my help. 7. He asked the students whether they ever (to see) such a book. 8. It was decided that we (to start) our work at eight o'clock. 9. I told you that I (to leave) for Minsk on the following day. 10. The boy did not know that he already (receive) a good mark. 12. He wanted to know what (to become) of the books. 13. The visitors were told that the secretary just (to go out) and (to come back) in half an hour. 14. He said we (may) keep the books as long as we (to like). 15. We thought that he not (to be able) to make his work in time and therefore (to offer) to help her. 16. When I came they (to tell) me that he (to leave) half an hour before. 17. It was soon clear to the teacher that the control work (to be) a difficult one. 18. I decided that next year I (to go) to see my old friend again. I not (to see) him since he (to go) to Moscow.
§ 2. Пасивний стан (Passive Voice).
Форми пасивного стану англійських дієслів утворюються за допомогою допоміжного дієслова to be у відповідному часі, особі і числі і причастя II (Participle II) смислового дієслова:
Present Indefinite | The letter is written |
Past Indefinite | The letter was written |
Future Indefinite | The letter will be written |
Present Continuous | The letter is being written |
Past Continuous | The letter was being written |
Future Continuous | The letter will be being written |
Present Perfect | The letter has been written |
Past Perfect | The letter had been written |
Future Perfect | The letter will have been written |
Дієслово-присудок в пасивному стані показує, що підмет пропозиції є об'єктом дії з боку іншої особи або предмета.
Порівняйте: I bought a book. - Я купив книгу.
The book was bought (by me). - Книга була куплена (мною).
Дієслова в пасивному стані на російську мову переводяться
1. дієсловом бути + коротка форма причастя пасивного стану:
The letter was sent yesterday. Лист було надіслано вчора.
2. дієсловом із часткою-ся (-сь):
This problem was discussed last week. Ця проблема обговорювалася на минулому тижні.
3. невизначено-особовим обігом, тобто дієсловом у дійсній заставі 3 особи множини, типу «говорять», «сказали»:
English is spoken in many countries. Англійською мовою говорять у багатьох країнах.
4. дієсловом у дійсній заставі (за наявності виконавця дії):
Pupils are taught at school by the teachers. Учнів навчають у школі вчителі.
Exercise 7.3. Translate into English. Determine the Tense and Voice of the verb:
1. He left for Moscow. 2. The news will be of great interest. 3. They were speaking to him. 4. She studied many subjects. 5. He was much spoken about. 6. New subjects will be studied next term. 7. I am working now. 8. The text has already been written by them. 9. He studies at our school. 10. You are playing chess, aren't you? 11. The text is being translated at the moment. 12. Do you work at this lab? 13. When I saw him, he was going home. 14. They will have passed their exams by 3 o'clock. 15. This book was written by our teacher. 16. We shall be writing our tests at 10 o'clock. 17. The work will have been done when he comes. 18. We translated this text. 19. The letter had been written before we came. 20. We shall inform you. 21. These toys are made in Japan. 22. Does he work here? 23. Is he working now? 24. The conference will be held in May. 25. Rostov was named after Dmitry Rostovsky. 26.What are you doing here? 27. This work must be done at once. 28. You may take my book. 29. I am often asked at the lessons. 30. This article was being translated when I came.
Exercise 7.4. Translate into English. Determine the Tense and Voice of the verb:
l.They can be seen in our library every day. 2. The delegation is headed by the Prime Minister. 3. The child was often left home alone. 4. These houses were built last year. 5. All letters had been written when we came. 6. This film is much spoken about. 7. The machine is being tested now. 8. His work has been already finished. 9.1 was told to wait for him. 10.Your letter will have been answered by Monday. 11. The experiment was being carried out from ten till twelve o'clock. 12.Children under sixteen will not be admitted here.
Exercise 7.5. Put the verbs in brackets in the right form:
1. I'm not reading these books today. They (return) to the library. 2. The paintings (exhibit) till the end of the month. 3. Why your home task (not do)? 4. She was taken to the hospital today, and (operate) tomorrow morning. 5. This room (use) only on special occasions. 6. Bicycles must not (leave) here. 7. This newspaper (not read). The pages (not cut). 8. Dictionaries may not (use) at the examination. 9. Usually this street (sweep) every day, but it (not sweep) yesterday. 10. This book (leave) in the classroom yesterday; it (find) by the teacher. 11. Thousands of new houses (build) every year. 12. This room (not use) for a long time. 13. The children are very excited this morning. They (take) to the circus this afternoon.
Exercise 7.6. Translate into English:
1. Ця книга була прочитана усіма. 2. Лист буде відправлено завтра. 3. Її часто запитують? 4. На ваше запитання дадуть відповідь завтра. 5. Текст перекладався вчора з двох до трьох. 6. Робота тільки що завершена нами. 7. Ці книги вже будуть опубліковані до кінця року. 8. Наша контрольна робота зараз перевіряється? 9. Про нову книжку будуть багато говорити. 10. У нашому місті зараз будується багато нових будівель. 11. Ключі були загублені вчора. 12. Хлопчика візьмуть у кіно. 13. Вам сказали про це? 14. Телеграма вже отримана?
Exercise 7.7. Translate into English:
1. Він сказав мені, що текст буде переведений до 10 години завтра. 2. Всі картини, які ви тут бачите, написані одним і тим же художником. 3. Лист буде відправлено завтра. 4. Робота буде закінчена в термін. 5. За доктором послали? Зробіть це як можна швидше. У дитини висока температура. 6. Ця книга була написана до того, як автор став знаменитим. 7. Сотні нових будинків будуть побудовані до кінця цього року. 8. Ця історія давно забута всіма. 9. Мені запропонували дуже цікаву роботу. 10. Він серйозний чоловік. На нього завжди можна покластися. 11. За старою жінкою доглядає її молодша дочка. 12. На вечорі нам показали прекрасний фільм. 13. Його вдарили м'ячем. 14. З ним необхідно негайно поговорити з цього питання. 15. Вам поставлять декілька питань на іспиті. 16. Їй було дано список учасників зборів. 17. Промова була заслухана з великою увагою. 18. Вам пояснять, як дістатися до залізничного вокзалу. 19. Про цю п'єсу зараз багато говорять. 20. Делегацію потрібно зустріти завтра о 9 годині ранку в аеропорту.
UNIT 8
HIGHER EDUCATION IN THE UK
I. Приголосні звуки [w], [h].
II. Text A: «Higher Education In the UK».
III. § 1. Складне доповнення (Complex object).
§ 2. Причастя і герундій.
Приголосний звук [w]. При проголошенні губи округлені та значно висунуті вперед, а задня частина мови займає приблизно таке ж положення, як при проголошенні російського [у]. Струмінь повітря, що видихається з силою проходить через утворену між губами круглу щілину. Губи енергійно розсуваються.
Приголосний звук [h]. При проголошенні приголосного задня спина мови змикається з опущеним м'яким небом, і повітря проходить через носову порожнину.
Exercise A what - why - where whip - wheat - while | Exercise З wall - wallet - walk walnut - waltz - won |
Exercise У war - wharf - water wedding - wage - wait waitress - waist - waste weather - woman - wind | Exercise D wing - king - sting sing - nothing - something everything - anything - ring |
Text A: "HIGHER EDUCATION IN THE UK»
Education after 16 is voluntary in United Kingdom. Students, who live in England, Wales, and Northern Ireland must take at the age of 16 the examinations for the General Certificate of Secondary Education (GCSE). In Scotland students receive the Scottish Certificate of Education. After this exam students can choose to stay on in school or attend colleges of further education.
British universities are self-governing and are guaranteed academic independence. Funding for education and research is provided by funding councils set up by Parliament. The number of universities jumped in 1992 when polytechnics and some other higher education establishments were given the right to become universities. By the end of 1994, there were some 90 universities, almost half of them former polytechnics, including the Open University.
Many of the colleges of Oxford and Cambridge universities were founded in the 12th and 13th centuries. All other universities in Britain were founded in the 19 th and 20 th centuries. The Open University, based in Milton Keynes, England, was founded in 1969. It uses extension techniques of correspondence courses, television and radio programmes, and video cassettes, supported by local study centres and summer schools, to provide higher education opportunities to a wide variety of people.
During the 1960s there was a significant increase in the number of new universities, reflecting a fast growth in student numbers. During the 1980s, an expansion in higher education places led to another large jump in student numbers. In the 1992-1993 academic year there were more than 1,4 million students in full or part-time higher education in Great Britain, compared with just under 850,000 a decade earlier. About one quarter of young people are in higher education in England, Wales, and Scotland; one third in Northern Ireland. About 90 per cent of students get state grants to cover tuition fees and living costs.
The size of the grant is determined by parents income. Since the late 1980s, however, grants have been frozen; students can apply for a student loan.
Vocabulary:
voluntary - добровільне
attend - відвідувати
self-governing - самоврядний
funding - фінансування
funding councils - поради з фінансування
to set up - засновувати
significant - значний
polytechnics - політехнічні інститути
extension techniques - технології дистанційної освіти
to reflect - відображати
decade - десятиріччя
state grants - державні гарантії
tuition fee - плата за навчання
parents income - дохід батьків
student loan - студентський позику
ADD TO YOUR ACTIVE VOCABULARY:
a) high-school diploma - шкільний атестат
graduation ceremony - випускний іспит
Bachelor of Science (BS) - бакалавр природничих наук
Bachelor of Art (BA) - бакалавр гуманітарних наук
Master of Art (MA) - магістр мистецтв
Master of Science (MS) - магістр природничих наук
Doctor of Philosophy (Ph.D.) - доктор філософії
undergraduate student - студент 1-4 (5) курсів
graduate student - студент 5-6 курсів
graduate school of robotics - магістратура (аспірантура) за спеціальністю робототехніка
b) room (lodging) and board - проживання та харчування
personal expenses - особисті витрати
books and supplies - книги та матеріали
to be eligible for admission - бути підходящою кандидатурою для вступу
to enrol - зараховувати
enrollment - зарахування
admissions office - приймальна комісія
student services office - департамент по роботі зі студентами
university bursar's (скарбник) office - бухгалтерія університету (офіс скарбника)
Exercise 8.1. Translate into English:
1) У віці 16 років кожен житель Великобританії зобов'язаний здати іспити на отримання Сертифікату про середню освіту.
2) Британські університети є повністю самоврядними.
3) У 1992 році Політехнічним інститутам була надано право стати університетами.
4) Відкритий університет, широко відомий своїми технологіями дистанційного навчання, був заснований в 1969 році.
5) У 60-і роки в Сполученому королівстві намітилося значне зростання числа університетів.
6) Розмір гранту на навчання визначається виходячи з доходу батьків.
GRAMMAR
§ 1. Складне доповнення (Complex object)
Складне доповнення - це поєднання іменника чи займенника в об'єктному відмінку (напр. me, him, us, them) з інфінітивом або дієприкметником I. Існує в трьох основних варіантах:
1. З інфінітивом без частки to або з причастям 1 після дієслів сприйняття
see I saw him drive the car. I saw them working in the lab.
watch We watched the plane land. We watched the children playing in the yard.
notice Nobody noticed him go out. He didn't notice that happen.
feel She felt somebody touch her hand. They didn't feel the train start.
hear I didn't hear you come into the room. I heard her playing piano.
У першому випадку (вищеперераховані дієслова з інфінітивом без частки to) підкреслюється факт дії, у другому (ці ж дієслова з причастям I) - процес дії.
I saw him enter the house. - Я бачив, як він увійшов до будинку.
I saw him entering the house. - Я бачив, як він заходив до будинку.
2. З інфінітивом без частки to після дієслів
to let: Don't let them play in the street.
to make: Don't make me laugh.
3. З інфінітивом з часткою to після дієслів
to want I want you to find me a place in the first row.
to expect I expect you to come in time.
to believe I believe her to be a very good teacher.
to know I know him to be a good student.
to advise I advise you to enter the institute.
to consider The climate in England is considered to be mild.
to order He is ordered not to be late.
to allow They allow to use dictionaries at the exam.
to like I would like you to finish your work,
to find I find your story to be very interesting.
Exercise 8.2. Put the verbs in brackets in the right form:
1. He made me (do) it all over again. 2. Her father made her (learn) the lessons. 3. If you want us (make) the work quickly you should let us (start) at once. 4. Would you like me (read) now? 5. They won't let us (leave) the classroom till our control work has been checked. 6. He wouldn't let the children (play) in his study. 7. Please let me (know) the results of your exam as soon as possible. 8. He made us (wait) for two hours. 9. I let him (go) early as he had done his task. 10. I'd like him (enter) the university but I can't make him (do) it. 11. I want her (learn) English. 12. I heard the door (open) and saw my friend (come) into the room. 13. I heard her (play) the piano. 14. I saw him (go out) of the house. 15. The teacher advised us (use) dictionaries. 16. Her father doesn't allow her (go) to the cinema alone. 17. We expect our basketball team (win) next game. 18. We don't want you (tell) anything. 19. I saw them (open) the window. 20. That is too difficult for you to do, let me (help) you.
Exercise 8.3. Translate into English:
1. Ви хочете, щоб діти грали тут? 2. Ви хочете, щоб ми зустрілися сьогодні? 3. Ви очікуєте, робота буде зроблена скоро? 4. Ми очікуємо, що вони добре проведуть у нас час. 5. Я хочу, щоб він закінчив цю роботу. 6. Ми чули, що вона знає, коли ми складаємо іспит. 7. Ви хочете, щоб ми обговорили це питання сьогодні? 8. Ми очікуємо, що на цьому місці буде побудований новий будинок. 9. Ви хотіли б, щоб робота була зроблена сьогодні?
§ 2. Причастя і герундій. Їх відмінність
(Participle I)
Причастя I (дієприкметник теперішнього часу), утворене за допомогою закінчення-ing, має активну і пасивні форми:
активна (недосконалий вид) - asking,
активна (досконалий вигляд) - having asked.
пасивні (недосконалий) - being asked,
пасивні (досконалий) - having been asked.
Причастя I вживається у функції:
1. Визначення:
The man sitting at the table is our teacher. - Людина, що сидить за столом - наш учитель.
The houses being built in our town are not very high. - Удома, що будуються в нашому місті, невисокі.
2. Обставини:
Going home I met an old friend. - Йдучи додому, я зустрів старого друга.
Having finished work I went home. - Закінчивши роботу, я пішов додому.
Причастя II (Participle II)
Причастя II (дієприкметник минулого часу) завжди пасивно. Утворюється воно додатком суфікса-ed до основи правильного дієслова або шляхом чергування звуків у корені неправильного дієслова.
Причастя II вживається у функції:
1. Визначення.
The book translated from English is interesting. - Книга, перекладена з англійської мови, цікава.
2. Обставини (причини і часу):
Given the task he began to work. - Коли йому дали завдання він почав працювати.
Вживання герундія і його відмінність від причастя I
Причастя - неособиста форма дієслова, проміжна між дієсловом і прикметником:
The boy playing in the yard is my brother, - Хлопчик, (який?) Грає у дворі, - мій брат.
Герундій також є неособистої формою дієслова, проміжною між іменником і дієсловом:
Smoking is harmful. - Куріння (що?) Шкідливо.
Іншими словами, причастя-більшою мірою «прикметник» за своїми функціями, герундій - «іменник».
Герундій вживається:
1. як що підлягає:
Reading is useful.
2. Як частина присудка після дієслів to finish, to start, to continue, to go on, to keep та ін
He started reading the book.
3. як прийменниково додаток: I am fond of reading.
4. як пряме доповнення: Do you mind my reading here?
5. як обставина часу: After reading he closed the book.
6. як обставина способу дії: Instead of reading he went to the movies.
Активна форма герундія: giving, beating.
Пасивна форма герундія: being given, being beaten.
Exercise 8.4. Open the brackets using the gerund:
1. The grass in the garden is very dry, it needs (water). 2. It's very warm outside. You don't need (put on) yourcoat. 3. The house is old, and it wants (repair). 4. Famous people don't need (introduce) themselves. 5. The carpet is covered with dust, it needs (sweep). 6. The shoes are very dirty, they need (polish). 7. These shoes have a hole, they want (mend). 8. The table cloth is quite clean, it doesn't want (wash) yet. 9. The room needed (clean). 10. (Learn) foreign languages is very useful. 12. I know my hair wants (cut) but I never have time to go to the hairdresser's. 13. John needed (cheer up) when he heard that he'd failed his exams. 14. You should tidy up the garden. - Yes, it needs (tidy). The roses want (water), the peaches want (pick), the grass wants (cut).
UNIT 9
MY FUTURE PROFESSION
I. Звуки [au], [dr], [br], [gr], [tr], [fr], [q r].
II. Text A: «My future profession»,
Text B: «The Future of the engineering profession»
III. § 1. Придаткові пропозиції умови і часу, дія яких віднесено до майбутнього.
§ 2. Умовний спосіб в умовних реченнях.
Exercise A now - how - brown out - now - house louse - mouse - cows out - loud - without Exercise У | brain - brakes - brand brunch - branch - brave Brazil - breach - break breath - broth - breathe Exercise D treasure - trainer - trench |
draw - dribble - draft drag - drab - drank drain - dragon - drama drape - dreadful - drugs Dresden - dress - dry drill - drop - drink drive - drown - drum drift - drier - droopy Exercise З brown - bread - brace | track - trade - traffic troops - trend - trail translate - transmit - trance Exercise E France - French - fruit fry - frame - free three - thread - throat threat - through - thrill thirty - throne - threaten |
Text A: "MY FUTURE PROFESSION"
Hi, there! Here is Ann Sokolova again. I am afraid this will be my last meeting with you because I need to pack my suitcase. I am leaving for Sochi tonight. I have passed all the exams successfully and I'm free till the 1 st of September.
As I have already told you, I was always good in mathematics and physics. My parents bought me a computer when I was in the 10 th form. Since then I knew that I would become a specialist in computer technologies - a computer engineer.
Computer industry is developing so fast, that it comprises almost all spheres of professional life. No business now is possible without computers. This is especially true about automated manufacturing of products and robotics. Computer control of automated production opens new horizons for the cheap and quality production of goods. Information is now generated, transmitted, received, and stored electronically through computer networks on a scale unprecedented in history, and there is every indication that the explosive rate of growth in this field will continue.
Computer engineering is a general field. It deals with both electric and electronic industries.
Electronic engineering deals with the research, design, integration, and application of circuits and devices used in the transmission and processing of information.
Engineers in the field of electric and electronic engineering are concerned with all aspects of electrical communications, from fundamental questions such as «What is information?» To the highly practical, such as the design of telephone systems. In designing communication systems, engineers rely on various branches of advanced mathematics, such as Fourier analysis, linear systems theory, linear algebra, differential equations, and probability theory.
Engineers work on control systems which are used extensively in automated manufacturing and in robotics.
Major developments in the field of communications and control have been the replacement of analogue systems with digital systems; fibre optics are used now instead of copper cables. Digital systems offer far greater immunity to electrical noise. Fibre optics are likewise immune to interference; they also have great carrying capacity, and are extremely light and inexpensive to manufacture.
Computer engineering is now the most rapidly growing field. The electronics of computers is the design and manufacture of memory systems, of central processing units, and of peripheral devices. The most prospective industry now is the Very Large Scale Integration (VLSI) and new computer architectures. The field of computer science is closely related to computer engineering; however, the task of making computers more «intelligent» (artificial intelligence), through creation of sophisticated programs or development of higher level machine languages or other means, is generally regarded as the dream of computer science.
One current trend in computer engineering is microminiaturization. Engineers continue to work to fit greater and greater numbers of circuit elements onto smaller and smaller chips.
Another trend is towards increasing the speed of computer operations through the use of parallel processors and superconducting materials.
So, as you see, there are a lot of employment opportunities in my field. I don't worry about finding a job. The most important thing for me now is to study well and to graduate from the Academy.
Vocabulary:
to comprise - включати в себе
automated manufacturing of products - автоматизоване виробництво товарів
robotics - робототехніка
horizons - горизонти
cheap - дешевий
to generate - генерувати, виробляти
to transmit - передавати
to store - зберігати
scale - масштаб
unprecedented in history - не має прецедентів в історії
indication - вказівка, свідоцтво
explosive - вибуховий
to deal with - мати справу з, займатися чим-небудь
integration - інтеграція
application - додаток, використання
circuits - електричні схеми, ланцюги
device - пристрій
transmission - передача
processing - обробка
to rely - покладатися
Fourier analysis - аналіз Фур'є
linear systems theory - теорія лінійних систем
linear algebra - лінійна алгебра
differential equations - диференціальні рівняння
probability theory - теорія ймовірності
extensively - широко
replacement - заміщення
fibre optics - оптоволоконні технології
copper - мідь
digital - цифровий
immunity - захищеність, несприйнятливість
carrying capacity - пропускна здатність
light - легкий
rapidly growing - швидко зростаючий
artificial intelligence - штучний розум
sophisticated - складний
superconducting - надпровідність
ADD TO YOUR ACTIVE VOCABULARY:
a) mechanical engineer - інженер-механік
electric engineer - інженер-електрик
electronic engineer - інженер електронік
computer engineer - інженер-комп'ютерник
military engineer - військовий інженер
b) prestigious job (work) - престижна робота
well-paid job - високооплачувана робота
employee - найманий робітник
employer - наймодавець
businessman - підприємець, бізнесмен
state-employed - державний службовець
white-collar worker - «білий комірець», працівник розумової праці
blue-collar worker - «синій комірець», працівник фізичної праці
skilled worker - кваліфікований робітник
unskilled worker - некваліфікований робітник
experienced worker - досвідчений працівник
c) to be hired for a job - бути найнятим на виконання роботи
to look for a new job (work, position) - шукати нову роботу
to apply for a new job - претендувати на будь-яку посаду
application for a position of - заява на будь-яку посаду
resume - резюме
CV (curriculum vitae) - автобіографія
to be fired - бути звільненим
to retire - йти на пенсію
to be unemployed - бути безробітним
Exercise 9.1. Translate into English:
1. Батьки купили мені комп'ютер, коли я вчилася (ся) в десятому класі.
2. Ніякої сучасний бізнес не можливий без комп'ютерної техніки.
3. Комп'ютерна індустрія - найбільш бистроразвівающеся виробництво.
4. Комп'ютерне управління автоматизованими виробничими лініями відкриває нові горизонти дешевого і якісного виробництва товарів.
5. Великим досягненням у сфері комунікації є заміна аналогових систем на ціфорвие.
6. В даний час оптоволоконні цифрові технології забезпечують більш якісну і доступну зв'язок, ніж аналогові системи.
Exercise 9.2. How do you see your future profession? Please answer the following questions:
1) What kind of work are you interested in?
a) well paid
b) interesting
c) in a large and famous company
d) quiet
e) in an industry which has a future
f) prestigious
g) not to sit the whole day in the office
h) to travel a lot
2) What position would you like to have?
a) to manage people - manager
b) to work for someone else - an employee
c) to be your own boss - self-employed, businessman
d) to be responsible for everything - top manager, director
e) to work for the state - state employee
Exercise 9.3. Please discuss with your group advantages and disadvantages of your future profession. Do you think that engineering profession is prestigios? Is it well-paid? How difficult is it to find a good work in this field?
Text B «THE FUTURE OF THE ENGINEERING PROFESSION»
Among various recent trends in the engineering profession computerization is the most widespread. The trend in modern engineering offices is also towards computerization. Computers are increasingly used for solving complex problems as well as for handling, storing, and generating the enormous volume of data modern engineers must work with.
Scientific methods of engineering are applied in several fields not connected directly to manufacture and construction. Modern engineering is characterized by the broad application of what is known as systems engineering principles.
Engineers in industry work not only with machines but also with people, to determine, for example, how machines can be operated most efficiently by workers. A small change in the location of the controls of a machine or of its position with relation to other machines or equipment, or a change in the muscular movements of the operator, often results in greatly increased production. This type of engineering work is called time-study engineering.
A related field of engineering, human-factors engineering, also known as ergonomics, received wide attention in the late 1970s and 1980s when the safety of nuclear reactors was questioned following serious accidents that were caused by operator errors, design failures, and malfunctioning equipment.
Human-factors engineering seeks to establish criteria for the efficient, human-centred design of, among other things, the large, complicated control panels that monitor and govern nuclear reactor operations.
General understanding:
1. What is the most widespread trend in the engineering profession?
2. What are computers used for in modern engineering?
3. What approaches are used in modern engineering?
4. What is «ergonomics»?
5. What does human-factors engineering deal with?
GRAMMAR
§ 1. Придаткові пропозиції умови і часу, дія яких віднесено до майбутнього
У додаткових пропозиціях умови і часу з спілками
If (якщо),
when (коли),
after (після),
before (перед тим, як),
as soon as (як тільки),]
unless (якщо не),
until (до тих пір, поки не),
майбутній час замінюється формою теперішнього часу, але на російську мову перекладається майбутнім, наприклад:
If you help me, I shall do this work. - Якщо ти допоможеш мені, я зроблю цю роботу.
As soon as I get free, I'll come to you. - Як тільки я звільнюся, я прийду до тебе.
We shall not begin until you come. - Ми не почнемо, поки ти не прийдеш.
Exercise 9.4. Open the brackets and put the verbs in the right form:
1. He (go) out when the weather (get) warmer. 2. I (wait) for you until you (come) back from school. 3. I'm afraid the train (start) before we (come) to the station. 4. We (go) to the country tomorrow if the weather (to be) fine. 5. We (not pass) the examination next year if we not (work) harder. 6. If you (not drive) more carefully you (have) an accident. 7. You (be) late if you (not take) a taxi. 8. I (finish) reading this book before I (go) to bed. 9. You must (send) us a telegram as soon as you (arrive). 10. We (have) a picnic tomorrow if it (be) a fine day. 11. We (go) out when it (stop) raining. 12. We (not to have) dinner until you (come). 13. I'm sure they (write) to us when they (know) our new address.
Прочитайте приклади і запам'ятайте найбільш уживані суфікси іменників
-ег/ог - teacher, writer, actor, doctor
-Ist - scientist, artist, dentist
-Ment - government, movement, development
- (T) ion - revolution, translation, operation
-ity/ty - popularity, honesty, ability
-sion/ssion - revision, session, discussion,
-Ness - happiness, illness, darkness
Прочитайте приклади і запам'ятайте найбільш уживані суфікси і префікси дієслів.
re-- rewrite, rebuild, reconstruct,
mis-- misprint, misunderstand, miscount.
Прочитайте приклади і запам'ятайте найбільш уживані суфікси і префікси прикметників.
un-- unhappy, unable, uncomfortable
dis-- dishonest, discouraging, disconnectng
Прочитайте приклади і запам'ятайте основні суфікси числівників.
-Teen - fifteen, sixteen, eighteen
-Ty - twenty, thirty, sixty, ninety
-Th - fourth, seventh, eighteenth
Exercise 9.5. Make up adjectives from the following words:
colour, beauty, peace, use, hope, truth, rain, help, power, pain, care.
§ 2. Умовний спосіб в умовних реченнях
Умовний спосіб виражає можливість, нереальність, імовірно дії.
Дійсного способу.
If I learn his address I shall write to him. - Якщо я дізнаюся його адресу, я йому напишу.
Умовний спосіб:
If I knew his address I would write to him. - Якби я знав його адресу (зараз), я написав би йому (зараз або в найближчому майбутньому). Дієслово в підрядному реченні - у формі Past Indefinite, в головному - у формі Future in the Past.
У випадку, якщо дія, що описується умовний спосіб, відноситься до минулого часу, в головному реченні використовується форма майбутнього досконалого з точки зору минулого Future Perfect in the Past, а в підрядному - минуле вчинене Past Perfect.
If I had known his address I would have written to him. - Якби я знав його адреса (у минулому), я написав би йому (у минулому ж).
I wish I lived not far from here. (Теперішній час).-Шкода, що я не живу поблизу.
I wish I had lived not far from here (минулий час). - Шкода, що я не жив поблизу.
Exercise 9.6. Translate into Russian:
1. If I came later I would be late for the lesson. 2. If he had known the time-table he wouldn't have missed the train. 3. It would be better if you learned the oral topics. 3. I wish I had known this before the examination. 4. I would have come to you if you had not lived so far away. 5. If I had seen you yesterday I would have given you my text-book. 6. If I were in your place I wouldn't buy the tickets beforehand. 7. If I had known that you needed help I would have helped you.
UNIT 1
METALS
I. Text A: «Metals», Text B: «Steel», Text C: «Methods of steel heat treatment»
II. Famous Scientists. Dmitry Ivanovlch Mendeleyev.
Text A: «METALS»
Metals are materials most widely used in industry because of their properties. The study of the production and properties of metals is known as metallurgy.
The separation between the atoms in metals is small, so most metals are dense. The atoms are arranged regularly and can slide over each other. That is why metals are malleable (can be deformed and bent without fracture) and ductile (can be drawn into wire). Metals vary greatly in their properties. For example, lead is soft and can be bent by hand, while iron can only be worked by hammering at red heat.
The regular arrangement of atoms in metals gives them a crystalline structure. Irregular crystals are called grains. The properties of the metals depend on the size, shape, orientation, and composition of these grains. In general, a metal with small grains will be harder and stronger than one with coarse grains.
Heat treatment such as quenching, tempering, or annealing controls the nature of the grains and their size in the metal. Small amounts of other metals (less than 1 per cent) are often added to a pure metal. This is called alloying (легування) and it changes the grain structure and properties of metals.
All metals can be formed by drawing, rolling, hammering and extrusion, but some require hot-working. Metals are subject to metal fatigue and to creep (the slow increase in length under stress) causing deformation and failure. Both effects are taken into account by engineers when designing, for example, airplanes, gas-turbines, and pressure vessels for high-temperature chemical processes. Metals can be worked using machine-tools such as lathe, milling machine, shaper and grinder.
The ways of working a metal depend on its properties. Many metals can be melted and cast in moulds, but special conditions are required for metals that react with air.
Vocabulary:
property - властивість
metallurgy - металургія
separation - поділ, отстояния
dense - щільний
arrangement - розташування
regularly - регулярно, правильно
to slide - ковзати
malleable - ковкий, податливий, здатний деформуватися
bent pp of bend - гнути
to fracture - ламати
ductile - еластичний, ковкий
to draw - волочити, тягнути
wire - дріт
lead - свинець
iron - залізо, чавун
grain - зерно
to depend - залежати
size - розмір, величина
shape - форма, формувати
composition - склад
coarse - грубий, великий
treatment - обробка
quenching - загартування
tempering - відпустка після гарту, нормалізація
annealing - відпал, відпустку
rolling - прокатка
to hammer - кувати (напр. молотом)
extrusion - екструзія
metal fatigue - втома металу
creep - повзучість
stress - тиск,
failure - пошкодження, руйнування
vessel - посудина, котел, судно
lathe - токарний верстат
milling machine - фрезерний верстат
shaper - стругальний верстат
grinder - шліфувальний верстат
to melt - плавити, плавитися розплавити
to cast - відливати, відлити
mould - форма (для виливки)
General understanding:
1. What are metals and what do we call metallurgy?
2. Why are most metals dense?
3. Why are metals malleable?
4. What is malleability?
5. What are grains?
6. What is alloying?
7. What is crystalline structure?
8. What do the properties of metals depend on?
9. What changes the size of grains in metals?
10. What are the main processes of metal forming?
11. How are metals worked?
12. What is creeping?
Exercise 1.1. Find the following words and word combinations in the text:
1. Властивості металів
2. відстань між атомами
3. правильне розташування
4. сильно відрізняються за своїми властивостями
5. кристалічна структура
6. розмір зерен
7. форма зерен
8. гарт
9. відпал
10.волоченіе
11.прокатка
12.ковка
13.екструзія
14. структура і властивості зерна
15. гаряча обробка
16. втома металу
17. повзучість металу
18. плавка і виливок у форми
19. способи обробки металів
Exercise 1.2. Complete the following sentences:
1. Metals are ...
2. Metallurgy is ...
3. Most metals are ...
4. The regular arrangement of atoms in metals ...
5. Irregular crystals ...
6. The properties of the metals depend ...
7. Metals with small grains will be ...
8 .... controls the nature of the grains in the metal.
9. Alloying is ...
10. All metals can be formed by ...
11. Creep is ...
12. Metals can be worked using ...
Exercise 1.3. Explain in English the meaning of the following words:
1. malleability
2. crystalline structure
3. grains
4. heat treatment
5. alloying
6. creep
Exercise 1.4. Translate into English:
1. Метали - щільні матеріали тому, що між атомами в металах малу відстань.
2. Метали мають кристалічну структуру з-за правильного розташування атомів.
3. Чим менше зерна, тим твердіше метал.
4. Загартування і відпал змінюють форму і розмір зерен в металах.
5. Легування змінює структуру зерен і властивості металів.
6. Метал деформується і руйнується з-за втоми і повзучості.
Text В: «STEEL»
The most important metal in industry is iron and its alloy - steel. Steel is an alloy of iron and carbon. It is strong and stiff, but corrodes easily through rusting, although stainless and other special steels resist corrosion. The amount of carbon in a steel influences its properties considerably. Steels of low carbon content (mild steels) are quite ductile and are used in the manufacture of sheet iron, wire, and pipes. Medium-carbon steels containing from 0.2 to 0.4 per cent carbon are tougher and stronger and are used as structural steels. Both mild and medium-carbon steels are suitable for forging and welding. High-carbon steels contain from 0.4 to 1.5 per cent carbon, are hard and brittle and are used in cutting tools, surgical instruments, razor blades and springs. Tool steel, also called silver steel, contains about 1 per cent carbon and is strengthened and toughened by quenching and tempering.
The inclusion of other elements affects the properties of the steel. Manganese gives extra strength and toughness. Steel containing 4 per cent silicon is used for transformer cores or electromagnets because it has large grains acting like small magnets. The addition of chromium gives extra strength and corrosion resistance, so we can get rust-proof steels. Heating in the presence of carbon or nitrogen-rich materials is used to form a hard surface on steel (case-hardening). High-speed steels, which are extremely important in machine-tools, contain chromium and tungsten plus smaller amounts of vanadium, molybdenum and other metals.
Vocabulary:
alloy - сплав
carbon - вуглець
stiff - жорсткий
to corrode - роз'їдати, іржавіти
rusty - іржавий
stainless - нержавіючий
to resist - чинити опір
considerably - значно, значно
tough - міцний, жорсткий, міцний, витривалий
forging - кування
welding - зварювання
brittle - крихкий, ламкий
cutting tools - ріжучі інструменти
surgical instruments - хірургічні інструменти
blade - лезо
spring - пружина
inclusion - включення
to affect - впливати
manganese - марганець
silicon - кремній
rust-proof - нержавіючий
nitrogen - азот
tungsten - вольфрам
General understanding:
1. What is steel?
2. What are the main properties of steel?
3. What are the drawbacks of steel?
4. What kinds of steel do you know? Where are they used?
5. What gives the addition of manganese, silicon and chromium to steel?
6. What can be made of mild steels (medium-carbon steels, high-carbon steels)?
7. What kind of steels can be forged and welded?
8. How can we get rust-proof (stainless) steel?
9. What is used to form a hard surface on steel?
10. What are high-speed steels alloyed with?
Exercise 1.5. Find the following words and word combinations in the text:
1. сплав заліза і вуглецю
2. міцний і жорсткий
3. легко коррозіруєт
4. нержавіюча сталь
5. низький вміст вуглецю
6. ковкість
7. листове залізо, дріт, труби
8. конструкційні сталі
9. придатні для кування і зварювання
10. твердий і крихкий
11. ріжучі інструменти
12. хірургічні інструменти
13. інструментальна сталь
14.упрочнять
15. додавання марганцю (кремнію, хрому, вольфраму, молібдену, ванадію)
Text З: «METHODS OF STEEL HEAT TREATMENT»
Quenching is a heat treatment when metal at a high temperature is rapidly cooled by immersion in water or oil. Quenching makes steel harder and more brittle, with small grains structure.
Tempering is a heat treatment applied to steel and certain alloys. Hardened steel after quenching from a high temperature is too hard and brittle for many applications and is also brittle. Tempering, that is re-heating to an intermediate temperature and cooling slowly, reduces this hardness and brittleness. Tempering temperatures depend on the composition of the steel but are frequently between 100 and 650 ° C. Higher temperatures usually give a softer, tougher product. The color of the oxide film produced on the surface of the heated metal often serves as the indicator of its temperature.
Annealing is a heat treatment in which a material at high temperature is cooled slowly. After cooling the metal again becomes malleable and ductile (capable of being bent many times without cracking).
All these methods of steel heat treatment are used to obtain steels with certain mechanical properties for certain needs.
Vocabulary:
to immerse - занурювати
to apply - застосовувати
intermediate - проміжний
oxide film - оксидна плівка
annealing - відпал, відпустку
cracking - розтріскування
General understanding:
1. What can be done to obtain harder steel?
2. What makes steel more soft and tough?
3. What makes steel more malleable and ductile?
4. What can serve as the indicator of metal temperature while heating it?
5. What temperature range is used for tempering?
6. What are the methods of steel heat treatment used for?
Exercise 1.6. Translate into English the following words and word combinations:
1. температура нормалізації
2. дрібнозерниста структура
3. швидке охолодження
4. загартована сталь
5. склад сталі
6. окісна плівка
7. індикатор температури
8. повільне охолодження
FAMOUS PEOPLE OF SCIENCE
Dmitry Ivanovich Mendeleyev
Dmitry Ivanovich Mendeleyev is a famous Russian chemist. He is best known for his development of the periodic table of the properties of the chemical elements. This table displays that elements 'properties are changed periodically when they are arranged according to atomic weight.
Mendeleyev was born in 1834 in Tobolsk, Siberia. He studied chemistry at the University of St. Petersburg, and in 1859 he was sent to study at the University of Heidelberg. Mendeleyev returned to St. Petersburg and became Professor of Chemistry at the Technical Institute in 1863. He became Professor of General Chemistry at the University of St. Petersburg in 1866. Mendeleyev was a well-known teacher, and, because there was no good textbook in chemistry at that time, he wrote the two-volume «Principles of Chemistry» which became a classic textbook in chemistry.
In this book Mendeleyev tried to classify the elements according to their chemical properties. In 1869 he published his first version of his periodic table of elements. In 1871 he published an improved version of the periodic table, in which he left gaps for elements that were not known at that time. His table and theories were proved later when three predicted elements: gallium, germanium, and scandium were discovered.
Mendeleyev investigated the chemical theory of solution. He found that the best proportion of alcohol and water in vodka is 40%. He also investigated the thermal expansion of liquids and the nature of petroleum.
In 1893 he became director of the Bureau of Weights and Measures in St. Petersburg and held this position until his death in 1907.
UNIT 2
METALWORKING
I. Text A: Metalworking processes: Rolling. Extrusion,
Text B: Drawing. Forging. Sheet metal forming,
Text C: Metalworking and Metal Properties.
II. Famous scientists. Mikhail Vasilyevich Lomonosov.
Text A: «METALWORKING PROCESSES»
Metals are important in industry because they can be easily deformed into useful shapes. A lot of metalworking processes have been developed for certain applications. They can be divided into five broad groups:
1. rolling,
2. extrusion,
3. drawing,
4. forging,
5. sheet-metal forming.
During the first four processes metal is subjected to large amounts of strain (deformation). But if deformation goes at a high temperature, the metal will recrystallize - that is, new strain-free grains will grow instead of deformed grains. For this reason metals are usually rolled, extruded, drawn, or forged above their recrystallization temperature. This is called hot working. Under these conditions there is no limit to the compressive plastic strain to which the metal can be subjected.
Other processes are performed below the recrystallization temperature. These are called cold working. Cold working hardens metal and makes the part stronger. However, there is a limit to the strain before a cold part cracks.
Rolling
Rolling is the most common metalworking process. More than 90 percent of the aluminum, steel and copper produced is rolled at least once in the course of production. The most common rolled product is sheet. Rolling can be done either hot or cold. If the rolling is finished cold, the surface will be smoother and the product stronger.
Extrusion
Extrusion is pushing the billet to flow through the orifice of a die. Products may have either a simple or a complex cross section. Aluminum window frames are the examples of complex extrusions.
Tubes or other hollow parts can also be extruded. The initial piece is a thick-walled tube, and the extruded part is shaped between a die on the outside of the tube and a mandrel held on the inside.
In impact extrusion (also called back-extrusion) (штампування видавлюванням), the workpiece is placed in the bottom of a hole and a loosely fitting ram is pushed against it. The ram forces the metal to flow back around it, with the gap between the ram and the die determining the wall thickness. The example of this process is the manufacturing of aluminum beer cans.
Vocabulary:
useful - корисний
shape - форма, формувати
rolling - прокатка
extrusion - екструзія, видавлювання
drawing - волочіння
forging - кування
sheet - лист
to subject - піддавати
amount - кількість
condition - стан, умова
perform - виконувати, проводити
to harden - робитися твердим, упрочняться
at least - принаймні
common - загальний
billet - заготівля, болванка
orifice - отвір
die - штамп, пуансон, матриця, фільєри, волочильна дошка
cross section - поперечний переріз
window frame - рама вікна
tube - труба
hollow - порожнистий
initial - початковий, початковий
thick-walled - товстостінний
mandrel - оправлення, сердечник
impact - удар
loosely - вільно, із зазором
fitting - зд. посадка
ram - пуансон, плунжер
force - сила
gap - проміжок, зазор
to determine - встановлювати, визначати
General understanding:
1. Why are metals so important in industry?
2. What are the main metalworking processes?
3. Why are metals worked mostly hot?
4. What properties does cold working give to metals?
5. What is rolling? Where is it used?
6. What is extrusion? What shapes can be obtained after extrusion?
7. What are the types of extrusion?
Exercise 2.1. Find the following in the text:
1. можуть легко деформуватися
2. потрібні форми
3. піддавати великим деформацій
4. зерна вільні від деформації
5. температура перекристалізації
6. пластична деформація стиснення
7. самий звичайний процес обробки металу
8. звичайнісіньке виріб прокату
9. отвір фільєри
10. початковий
11. складний перетин
12. пустотілі деталі
13. вільно входить плунжер
14. зазор між плунжером (пуансоном) та штампом
15. товщина стінки
Exercise 2.2. Translate into English:
1. Здатність металу перекрісталлізовивают при високій температурі використовується при гарячій
обробці.
2. Перекристалізація - це зростання нових, вільних від деформації зерен.
3. Під час гарячої обробки метал може піддаватися дуже великий пластичної деформації стиснення.
4. Холодне робить метал твердіше і міцніше, але деякі метали мають межа деформації.
5. Листовий прокат може здійснюватися гарячим або холодним.
6. Поверхня холоднокатаного листа більш гладка і він міцніший.
7. Поперечний перетин фільєри для екструзії може бути простим або складним.
8. Алюмінієві і мідні сплави є найкращими для екструзії з-за їх пластичності при деформації.
9. Алюмінієві банки, тюбики для зубної пасти є прикладами використання штамповки.
10. Товщина стінки алюмінієвої банки визначається зазором між пунсонів і штампом.
Text В: «DRAWING»
Drawing consists of pulling metal through a die. One type is wire drawing. The diameter reduction that can be achieved in one die is limited, but several dies in series can be used to get the desired reduction.
Sheet metal forming
Sheet metal forming (штампування листового металу) is widely used when parts of certain shape and size are needed. It includes forging, bending and shearing. One characteristic of sheet metal forming is that the thickness of the sheet changes little in processing. The metal is stretched just beyond its yield point (2 to 4 percent strain) in order to retain the new shape. Bending can be done by pressing between two dies. Shearing is a cutting operation similar to that used for cloth.
Each of these processes may be used alone, but often all three are used on one part. For example, to make the roof of an automobile from a flat sheet, the edges are gripped and the piece pulled in tension over a lower die. Next an upper die is pressed over the top, finishing the forming operation (штампування), and finally the edges are sheared off to give the final dimensions.
Forging
Forging is the shaping of a piece of metal by pushing with open or closed dies. It is usually done hot in order to reduce the required force and increase the metal's plasticity.
Open-die forging is usually done by hammering a part between two flat faces. It is used to make parts that are too big to be formed in a closed die or in cases where only a few parts are to be made. The earliest forging machines lifted a large hammer that was then dropped on the workpiece, but now air or steam hammers are used, since they allow greater control over the force and the rate of forming. The part is shaped by moving or turning it between blows.
Closed-die forging is the shaping of hot metal within the walls of two dies that come together to enclose the workpiece on all sides. The process starts with a rod or bar cut to the length needed to fill the die. Since large, complex shapes and large strains are involved, several dies may be used to go from the initial bar to the final shape. With closed dies, parts can be made to close tolerances so that little finish machining is required.
Two closed-die forging operations are given special names. They are upsetting and coining. Coining takes its name from the final stage of forming metal coins, where the desired imprint is formed on a metal disk that is pressed in a closed die. Coining involves small strains and is done cold. Upsetting involves a flow of the metal back upon itself. An example of this process is the pushing of a short length of a rod through a hole, clamping the rod, and then hitting the exposed length with a die to form the head of a nail or bolt.
Vocabulary:
to pull - тягнути
reduction - скорочення
to achieve - досягати
in series - серія, послідовно
beyond - вище, понад
yield point - точка плинності металу
to retain - зберігати, утримувати
to bend - гнути
shearing - обрізка, відрізання
edge - край
to grip - схоплювати
lower die - нижній штамп
upper die - верхній штамп
forming operation - операція штампування
dimension - вимірювання, розміри
required - необхідний
increase - збільшення
open-die forging - кування у відкритому штампі (підкладному)
hammering - кування, бити
within - всередині, у межах
to enclose - укладати
rod - прут, стрижень
bar - прут, брусок
involved - включений
tolerance - допуск
upsetting - висадка, видавлювання
blow - удар
coining - карбування
imprint - відбиток
clamp - затиск
to hit - вдаряти
General understanding:
1. How can the reduction of diameter in wire drawing be achieved?
2. What is sheet metal forming and where it can be used?
3. What is close-die forging?
4. What is forging?
5. What are the types of forging?
6. What types of hammers are used now?
7. Where are coining and upsetting used?
8. What process is used in wire production?
9. Describe the process of making the roof of a car.
Exercise 2.3. Find the following word combinations in the text:
1. протягування металу через фильеру
2. волочіння дроту
3. зменшення діаметра
4. товщина листа
5. розтягувати вище крапки плинності
6. зберегти нову форму
7. краю відрізаються
8. кінцеві розміри
9. зменшити необхідне зусилля
10. збільшити пластичність металу
11. повітряні або парові молоти
12. сила і швидкість штампування
13. усередині стінок двох штампів
14. обробна обробка
15. малі допуски
Exercise 2.4. Translate into English:
1. При волочіння дроту діаметр отвору волочильне дошки щораз зменшується.
2. Штампування листового металу включає в себе ковку, вигин і обрізання.
3. Невелика деформація листа при розтягуванні допомагає зберегти нову форму деталі.
4. Зміна форми при штампуванні проводиться шляхом стиснення між двома штампами.
5. Краї листа при штампуванні відрізаються для отримання кінцевих розмірів.
6. При проковки деталь повинна бути гарячою для зменшення необхідних зусиль і збільшення пластичності металу.
7. Після кування в закритих штампах деталі не вимагають великої механічної обробки.
8. При карбуванні деформація металу невелика і відбиток формується на поверхні металу.
9. Висадка використовується для виготовлення голівок цвяхів і болтів.
Text C: «METALWORKING AND METAL PROPETIES»
An important feature of hot working is that it provides the improvement of mechanical properties of metals. Hot-working (hot-rolling or hot-forging) eliminates porosity, directionality, and segregation that are usually present in metals. Hot-worked products have better ductility and toughness than the unworked casting. During the forging of a bar, the grains of the metal become greatly elongated in the direction of flow. As a result, the toughness of the metal is greatly improved in this direction and weakened in directions transverse to the flow. Good forging makes the flow lines in the finished part oriented so as to lie in the direction of maximum stress when the part is placed in service.
The ability of a metal to resist thinning and fracture during cold-working operations plays an important role in alloy selection. In operations that involve stretching, the best alloys are those which grow stronger with strain (are strain hardening) - for example, the copper-zinc alloy, brass, used for cartridges and the aluminum-magnesium alloys in beverage cans, which exhibit greater strain hardening.
Fracture of the workpiece during forming can result from inner flaws in the metal. These flaws often consist of nonmetallic inclusions such as oxides or sulfides that are trapped in the metal during refining. Such inclusions can be avoided by proper manufacturing procedures.
The ability of different metals to undergo strain varies. The change of the shape after one forming operation is often limited by the tensile ductility of the metal. Metals such as copper and aluminum are more ductile in such operations than other metals.
Vocabulary
feature - риса, особливість
to provide - забезпечувати
improvement - поліпшення
property - властивість
eliminate - ліквідувати, виключати
porosity - пористість
directional - спрямований
to segregate - розділяти
casting - виливок
elongated - подовжений
to weaken - слабшати, послаблювати
transverse - поперечний
flow - течія, потік
finished - оброблений
thinning - потоншення
fracture - руйнування
strain hardening - деформаційне зміцнення
brass - латунь
beverage - напій
can - консервна банка
to exhibit - виявляти
inner - внутрішній
flaws - недоліки, дефекти кристалічної решітки
inclusion - включення
trapped - зд. укладений
refining - очищати, очищення
to avoid - уникати
to undergo - піддаватися
tensile ductility - пластичність при розтягуванні
General understanding:
1. What process improves the mechanical properties of metals?
2. What new properties have hot-worked products?
3. How does the forging of a bar affect the grains of the metal? What is the result of this?
4. How are the flow lines in the forged metal oriented and how does it affect the strength of the forged part?
5. What are the best strain-hardening alloys? Where can we use them?
6. What are the inner flaws in the metal?
7. Can a metal fracture because of the inner flaw?
8. What limits the change of the shape during forming operations?
Exercise 2.5. Find the following in the text:
1. важлива особливість гарячої обробки
2. поліпшення механічних властивостей металу
3. необроблена виливок
4. напрям максимальної напруги
5. здатність чинити опір потоншення і руйнування
6. проявляти більшу деформаційне зміцнення
7. руйнування деталі при штампуванні
8. внутрішні дефекти в металі
9. неметалеві включення
10. здатність металів піддаватися деформації
11. обмежується пластичністю металу при розтягуванні
Exercise 2.6. Translate into English:
1. Гаряча обробка металу покращує його механічні властивості і усуває пористість і внутрішні дефекти.
2. Подовження зерен у напрямку плинності при куванні значно покращує міцність металу в цьому напрямку і зменшує його міцність у поперечному.
3. Хороша проковування орієнтує лінії плинності в напрямку максимальної напруги.
4. Деформаційне зміцнення металу при холодній обробці дуже важливо для отримання металів з покращеними властивостями.
5. Внутрішні дефекти металу - це неметалеві включення типу оксидів або сульфідів.
6. Зміна форми при штампуванні металевих деталей обмежується пластичністю металу при розтягуванні.
FAMOUS SCIENTISTS
Mikhail Vasilyevich Lomonosov was a famous Russian writer, chemist, and astronomer who made a lot in literature and science.
Lomonosov was born on November 19, 1711, in Denisovka (now Lomonosov), near Archangelsk, and studied at the University of the Imperial Academy of Sciences in St. Petersburg. After studying in Germany at the Universities of Marburg and Freiberg, Lomonosov returned to St. Petersburg in 1745 to teach chemistry and built a teaching and research laboratory there four years later.
Lomonosov is often called the founder of Russian science. He was an innovator in many fields. As a scientist he rejected the phlogiston theory of matter commonly accepted at the time and he anticipated the kinetic theory of gases. He regarded heat as a form of motion, suggested the wave theory of light, and stated the idea of conservation of matter. Lomonosov was the first person to record the freezing of mercury and to observe the atmosphere of Venus during a solar transit.
Interested in the development of Russian education, Lomonosov helped to found Moscow State University in 1755, and in the same year wrote a grammar that reformed the Russian literary language by combining Old Church Slavonic with modern language. In 1760 he published the first history of Russia. He also revived the art of Russian mosaic and built a mosaic and colored-glass factory. Most of his achievements, however, were unknown outside Russia.
UNIT3
MATERIALS SCIENCE AND TECHNOLOGY
I. Text A: «Materials science and technology»,
Text B: «Mechanical Properties of Materials».
II. Famous people of science and technology: Igor Sikorskly, Andrey Tupolev.
Text A: «MECHANICAL PROPERTIES Of MATERIALS»
Materials Science and Technology is the study of materials and how they can be fabricated to meet the needs of modern technology. Using the laboratory techniques and knowledge of physics, chemistry, and metallurgy, scientists are finding new ways of using metals, plastics and other materials.
Engineers must know how materials respond to external forces, such as tension, compression, torsion, bending, and shear. All materials respond to these forces by elastic deformation. That is, the materials return their original size and form when the external force disappears. The materials may also have permanent deformation or they may fracture. The results of external forces are creep and fatigue.
Compression is a pressure causing a decrease in volume. When a material is subjected to a bending, shearing, or torsion (twisting) force, both tensile and compressive forces are simultaneously at work. When a metal bar is bent, one side of it is stretched and subjected to a tensional force, and the other side is compressed.
Tension is a pulling force; for example, the force in a cable holding a weight. Under tension, a material usually stretches, returning to its original length if the force does not exceed the material's elastic limit. Under larger tensions, the material does not return completely to its original condition, and under greater forces the material ruptures.
Fatigue is the growth of cracks under stress. It occurs when a mechanical part is subjected to a repeated or cyclic stress, such as vibration. Even when the maximum stress never exceeds the elastic limit, failure of the material can occur even after a short time. No deformation is seen during fatigue, but small localized cracks develop and propagate through the material until the remaining cross-sectional area cannot support the maximum stress of the cyclic force. Knowledge of tensile stress, elastic limits, and the resistance of materials to creep and fatigue are of basic importance in engineering.
Creep is a slow, permanent deformation that results from a steady force acting on a material. Materials at high temperatures usually suffer from this deformation. The gradual loosening of bolts and the deformation of components of machines and engines are all the examples of creep. In many cases the slow deformation stops because deformation eliminates the force causing the creep. Creep extended over a long time finally leads to the rupture of the material.
Vocabulary
bar - брусок, прут
completely - повністю, абсолютно
compression - стиснення
creep - повзучість
cross-sectional area - площа поперечного перерізу
cyclic stress - циклічне напруга
decrease - зменшення
elastic deformation - пружна деформація
elastic limit - межа пружності
exceed - перевищувати
external forces - зовнішні сили
fatigue - втома металу
fracture - перелом, злам
loosen - послаблювати, розхитувати
permanent deformation - постійна деформація
remaining - залишився
shear - зріз
simultaneously - одночасно
to stretch - розтягувати
technique - методи
tension - напруженість
to propagate - розповсюджуватися
to bend - гнути, зігнути
to extend - розширювати, продовжуватися
to meet the needs - відповідати вимогам
to occur - відбуватися
to respond - відповідати реагувати
to suffer - страждати
torsion - кручення
twisting - закручування, вигин
volume - обсяг, кількість
rupture - розрив
General understanding:
1. What are the external forces causing the elastic deformation of materials? Describe those forces that change the form and size of materials.
2. What are the results of external forces?
3. What kinds of deformation are the combinations of tension and compression?
4. What is the result of tension? What happens if the elastic limit of material is exceeded under tension?
5. What do we call fatigue? When does it occur? What are the results of fatigue?
6. What do we call creep? When does this type of permanent deformation take place? What are the results of creep?
Exercise 3.1. Find the following in the text:
1. відповідати вимогам сучасної технології
2. використовуючи лабораторні методи
3. нові способи використання металів
4. стиск, розтяг, вигин, крутіння, зріз
5. повертати початковий розмір і форму
6. зовнішня сила
7. постійна деформація
8. зменшення обсягу
9. розтягують і стискають сили
10. перевищувати межу пружності матеріалу
11. повторювані циклічні напруги
12. руйнування матеріалу
13. розвиток і поширення дрібних тріщин
14. опір матеріалів повзучості і втоми
Exercise 3.2. Translate into English the following sentences:
1. Пружна деформація - це реакція всіх матеріалів на зовнішні сили, такі, як розтяг, стиск, скручування, вигин і зріз.
2. Втома і повзучість матеріалів є результатом зовнішніх сил.
3. Зовнішні сили викликають постійну деформацію і руйнування матеріалу.
4. Розтягують і стискають сили працюють одночасно, коли ми згинає або скручуємо матеріал.
5. Розтягування матеріалу вище межі його пружності дає постійну деформацію або руйнування.
6. Коли деталь працює довгий час під циклічними напругами, в ній з'являються невеликі зростаючі тріщини через втому металу.
7. Повзучість - це повільне зміна розміру деталі під напругою.
Text В: «Mechanical Properties of Materials»
Density (specific weight) is the amount of mass in a unit volume. It is measured in kilograms per cubic metre. The density of water is 1000 kg / m 3 but most materials have a higher density and sink in water. Aluminium alloys, with typical densities around 2800 kg / m 3 are considerably less dense than steels, which have typical densities around 7800 kg / m 3. Density is important in any application where the material must not be heavy.
Stiffness (rigidity) is a measure of the resistance to deformation such as stretching or bending. The Young modulus is a measure of the resistance to simple stretching or compression. It is the ratio of the applied force per unit area (stress) to the fractional elastic deformation (strain). Stiffness is important when a rigid structure is to be made.
Strength is the force per unit area (stress) that a material can support without failing. The units are the same as those of Stiffness, MN / m 2, but in this case the deformation is irreversible. The yield strength is the stress at which a material first deforms plastically. For a metal the yield strength may be less than the fracture strength, which is the stress at which it breaks. Many materials have a higher strength in compression than in tension.
Ductility is the ability of a material to deform without breaking. One of the great advantages of metals is their ability to be formed into the shape that is needed, such as car body parts. Materials that are not ductile are brittle. Ductile materials can absorb energy by deformation but brittle materials cannot.
Toughness is the resistance of a material to breaking when there is a crack in it. For a material of given toughness, the stress at which it will fail is inversely proportional to the square root of the size of the largest defect present. Toughness is different from strength: the toughest steels, for example, are different from the ones with highest tensile strength. Brittle materials have low toughness: glass can be broken along a chosen line by first scratching it with a diamond. Composites can be designed to have considerably greater toughness than their constituent materials. The example of a very tough composite is fiberglass that is very flexible and strong.
Creep resistance is the resistance to a gradual permanent change of shape, and it becomes especially important at higher temperatures. A successful research has been made in materials for machine parts that operate at high temperatures and under high tensile forces without gradually extending, for example the parts of plane engines.
Vocabulary
ability - здатність
amount - кількість
absorb - поглинати
amount - кількість
application - застосування
brittle - крихкий, ламкий
car body - кузов автомобіля
constituent - компонент
crack - тріщина
creep resistance - стійкість до повзучості
definition - визначення
density - щільність
ductility - гнучкість, еластичність
failure - пошкодження
gradual - поступовий
permanent - постійний
rigid - жорсткий
to sink - тонути
square root - квадратний корінь
stiffness - жорсткість
strain - навантаження, напруга, деформація
strength - міцність
stress - тиск, напруга
tensile strength - міцність на розрив
toughness - міцність, стійкість
yield strength - міцність плинності
Young modulus - модуль Юнга
General understanding:
1. What is the density of a material?
2. What are the units of density? Where low density is needed?
3. What are the densities of water, aluminium and steel?
4. A measure of what properties is stiffness? When stiffness is important?
5. What is Young modulus?
6. What is strength?
7. What is yield strength? Why fracture strength is always greater than yield strength?
8. What is ductility? Give the examples of ductile materials. Give the examples of brittle materials.
8. What is toughness?
9. What properties of steel are necessary for the manufacturing of: a) springs, b) car body parts, c) bolts and nuts, d) cutting tools?
10. Where is aluminium mostly used because of its light weight?
Exercise 3.3. Find the following words and word combinations in the text:
1. кількість маси в одиниці об'єму
2. кілограм на кубічний метр
3. міра опору деформації
4. ставлення прикладеної сили на одиницю площі до часткової пружною деформації
5. жорстка конструкція
6. міцність на стиск
7. здатність матеріалу деформуватися не руйнуючись
8. поглинати енергію шляхом деформації
9. обернено пропорційно квадрату розміру дефекту
10. поступова зміна форми
11. підвищені температури
12. високі розтягуючі зусилля
Exercise 3.4. Translate into English the following:
1. Щільність вимірюється у кілограмах на кубічний метр.
2. Більшість матеріалів мають більш високу щільність, ніж вода і тонуть у воді.
3. Щільність матеріалу дуже важлива, особливо в авіації.
4. Модуль Юнга - відношення прикладеної сили до пружної деформації даного матеріалу.
5. Чим більше метал жорсткий, тим менш він деформується під навантаженням.
6. Коли метал розтягують, він спочатку тече, тобто пластично деформується.
7. Свинець, мідь, алюміній і золото - ковкі метали.
8. Опір повзучості є дуже важливою властивістю матеріалів, які використовуються в авіаційних моторах.
«FAMOUS PEOPLE OF SCIENCE AND ENGINEERING»
Sikorsky Igor Ivanovich was a well-known aircraft engineer and manufacturer.
Sikorsky was born in 1889 in Kiev, in the Ukraine, and got his education at the naval college in St. Petersburg, and later in Kiev and Paris. He was the first to make experiments in helicopter design. In 1913 he designed, built, and flew the first successful aeroplane. Later he built military aircrafts for Russia and France.
In 1919 Sikorsky moved to the United States and later helped to organize an aircraft company that produced a series of multiengine flying boats for commercial service. Sikorsky became an American citizen in 1928. In the late 1930s he returned to developing helicopters and produced the first successful helicopter in the west. Helicopters designed by Sikorsky were used mostly by the US Army Air Forces during World War II. He died in 1972 at the age of 83.
Tupolev Andrey Nikolayevich, famous aircraft designer, was born in 1888. He graduated from the Moscow Higher Technical School, where he designed the first Russian wind tunnel. He helped to found the Central Aerohydrodynamics Institute in 1918 and later worked as the head of its design bureau. During his career he directed the design of more than 100 military and commercial aircraft, including the TU-2 and TU-4 bombers used in the World War II. In 1955 he designed the TU-104, the first passenger jet airliner. His TU-144 supersonic jet liner began its commercial passenger flights in 1977.
UNIT 4
MACHINE-TOOLS
I. Text A: «Machine-tools», Text B: «Lathe»,
Text C: «Milling, boring, drilling machines. Shapers and Planers », Text D:« Dies »
II. Famous people of science and technology: George Stephenson, Robert Slephenson.
Text A: «MACHINE-TOOIS»
Machine-tools are used to shape metals and other materials. The material to be shaped is called the workpiece. Most machine-tools are now electrically driven. Machine-tools with electrical drive are faster and more accurate than hand tools: they were an important element in the development of mass-production processes, as they allowed individual parts to be made in large numbers so as to be interchangeable.
All machine-tools have facilities for holding both the workpiece and the tool, and for accurately controlling the movement of the cutting tool relative to the workpiece. Most machining operations generate large amounts of heat, and use cooling fluids (usually a mixture of water and oils) for cooling and lubrication.
Machine-tools usually work materials mechanically but other machining methods have been developed lately. They include chemical machining, spark erosion to machine very hard materials to any shape by means of a continuous high-voltage spark (discharge) between an electrode and a workpiece. Other machining methods include drilling using ultrasound, and cutting by means of a laser beam. Numerical control of machine-tools and flexible manufacturing systems have made it possible for complete systems of machine-tools to be used flexibly for the manufacture of a range of products .
Vocabulary:
machine-tools - верстати
electrically driven - з електроприводом
shape - форма
workpiece - деталь
accurate - точний
development - розвиток
to allow - дозволяти, дозволяти
interchangeable - взаємозамінний
facility - пристосування
relative-відносний
amount - кількість
fluid - рідина
to lubricate - змащувати
spark erosion - електроіскрових обробка
discharge - розряд
by means of - за допомогою
beam - промінь
drilling - свердління
flexible - гнучкий
range - асортимент, діапазон
Text B: «LATHE»
Lathe is still the most important machine-tool. It produces parts of circular cross-section by turning the workpiece on its axis and cutting its surface with a sharp stationary tool. The tool may be moved sideways to produce a cylindrical part and moved towards the workpiece to control the depth of cut. Nowadays all lathes are power-driven by electric motors. That allows continuous rotation of the workpiece at a variety of speeds. The modern lathe is driven by means of a headstock supporting a hollow spindle on accurate bearings and carrying either a chuck or a faceplate, to which the workpiece is clamped. The movement of the tool, both along the lathe bed and at right angle to it, can be accurately controlled, so enabling a part to be machined to close tolerances. Modern lathes are often under numerical control.
Vocabulary:
lathe - токарний верстат
circular cross-section - круглий поперечний переріз
surface - поверхня
stationary - нерухомий, стаціонарний
sideways - у бік
variety - різноманітність, різновид
depth - глибина
headstock - передня бабка
spindle - шпиндель
chuck - затиск, патрон
faceplate - планшайба
lathe bed - станина верстата
to enable - давати можливість
tolerance - допуск
General understanding:
1. What are machine-tools used for?
2. How are most machine-tools driven nowadays?
3. What facilities have all machine-tools?
4. How are the cutting tool and the workpiece cooled during machining?
5. What other machining methods have been developed lately?
6. What systems are used now for the manufacture of a range of products without the use of manual labor?
7. What parts can be made with lathes?
8. How can the cutting tool be moved on a lathe?
9. How is the workpiece clamped in a lathe?
10. Can we change the speeds of workpiece rotation in a lathe?
11. What is numerical control of machine tools used for?
Exercise 4.1. Find English equivalents in the text:
1. оброблюваний матеріал
2. електропривод
3. більш точний
4. окремі деталі
5. процес масового виробництва
6. пристосування для тримання різця і деталі
7. операції по механічній обробці деталі
8. високовольтний розряд
9. свердління ультразвуком
10. різання за допомогою лазерного променя
11. гнучкі виробничі системи
12. деталі круглого перерізу
13. повертати деталь навколо її осі
14. рухати в бік, рухати у напрямку до деталі
15. глибина різання
16. безперервне обертання деталі
17. рух різця вздовж станини
Exercise 4.2. Translate into English:
1. Токарний верстат дозволяє виробляти деталі круглого перерізу.
2. Деталь затискається в патроні або на планшайбі токарного верстата.
3. Різець може рухатися як уздовж станини, так і під прямим кутом до неї.
4. Сучасні токарні верстати часто мають цифрове управління.
Text З: «MILLING MACHINE»
In a milling machine the cutter (фреза) is a circular device with a series of cutting edges on its circumference. The workpiece is held on a table that controls the feed against the cutter. The table has three possible movements: longitudinal, horizontal, and vertical; in some cases it can also rotate. Milling machines are the most versatile of all machine tools. Flat or contoured surfaces may be machined with excellent finish and accuracy. Angles, slots, gear teeth and cuts can be made by using various shapes of cutters.
Drilling and Boring Machines
To drill a hole usually hole-making machine-tools are used. They can drill a hole according to some specification, they can enlarge it, or they can cut threads for a screw or to create an accurate size or a smooth finish of a hole.
Drilling machines (свердлильні верстати) are different in size and function, from portable drills to radial drilling machines, multispindle units, automatic production machines, and deep-hole-drilling machines.
Boring (розточування) is a process that enlarges holes previously drilled, usually with a rotating single-point cutter held on a boring bar and fed against a stationary workpiece.
Shapers and Planers
The shaper (поперечно-стругальний верстат) is used mainly to produce different flat surfaces. The tool slides against the stationary workpiece and cuts on one stroke, returns to its starting position, and then cuts on the next stroke after a slight lateral displacement. In general, the shaper can make any surface having straight-line elements. It uses only one cutting-tool and is relatively slow, because the return stroke is idle. That is why the shaper is seldom found on a mass production line. It is, however, valuable for tool production and for workshops where flexibility is important and relative slowness is unimportant.
The planer (поздовжньо-стругальний верстат) is the largest of the reciprocating machine tools. It differs from the shaper, which moves a tool past a fixed workpiece because the planer moves the workpiece to expose a new section to the tool. Like the shaper, the planer is intended to produce vertical, horizontal, or diagonal cuts. It is also possible to mount several tools at one time in any or all tool holders of a planer to execute multiple simultaneous cuts.
Grinders
Grinders (шліфувальні верстати) remove metal by a rotating abrasive wheel. The wheel is composed of many small grains of abrasive, bonded together, with each grain acting as a miniature cutting tool. The process gives very smooth and accurate finishes. Only a small amount of material is removed at each pass of the wheel, so grinding machines require fine wheel regulation. The pressure of the wheel against the workpiece is usually very light, so that grinding can be carried out on fragile materials that cannot be machined by other conventional devices.
Vocabulary:
milling machine - фрезерний верстат
series - серія, ряд
cutting edge - ріжучий край, вістря
circumference - коло
to feed - подавати
longitudinal - поздовжній
horizontal - горизонтальний
vertical - вертикальний
versatile - універсальний
flat - плаский
contoured - контурний
angle - кут
slot - проріз, паз
gear teeth - зуби шестірні
drill - дриль, свердло, свердлити
hole - отвір
to enlarge - збільшувати
thread - різьблення
portable - портативний
unit - одиниця, ціле, вузол
previously - раніше
to slide - ковзати
stroke - хід
lateral - бічний
displacement - зміщення
straight - прямий
idle - на холостому ходу
workshop - цех, майстерня
to mount - кріпити
holder - тримач
to execute - виконувати
simultaneous - одночасний
multiple - численний
grinder - шліфувальний верстат
wheel - коло, колесо
bonded - скріплений
to remove - видаляти
pass - прохід
fine - точний
conventional - звичайний
device - пристрій, прилад
fragile - тендітний
General understanding:
1. What is the shape of a cutter in a milling machine?
2. What moves in a milling machine, a table or a cutter?
3. What possible movements has the table of a milling machine?
4. What kind of surfaces and shapes may be machined by a milling machine?
5. What can we use a drilling machine for?
6. What kinds of drilling machines exist?
7. What is rotated while boring, a cutter or a work-piece?
8. Describe the work of a shaper (planer).
9. What must be done to execute multiple simultaneous cuts on a planer?
10. What is the working tool in a grinder?
11. Can we obtain a very smooth surface after grinding and why? 12. Can we grind fragile materials and why?
Exercise 4.3. Translate into English:
1. Токарний верстат все ще залишається найважливішим верстатом.
2. Всі сучасні токарні верстати обладнані електроприводами.
3. Рух інструменту контролюється з високою точністю.
4. Електропривод дозволяє обробляти заготовку на різних швидкостях.
Text D: «DIES»
Dies are tools used for the shaping solid materials, especially those employed in the pressworking of cold metals.
In presswork, dies are used in pairs. The smaller die, or punch, fits inside the larger die, called the matrix or, simply, the die. The metal to be formed, usually a sheet, is placed over the matrix on the press. The punch is mounted on the press and moves down by hydraulic or mechanical force.
A number of different forms of dies are employed for different operations. The simplest are piercing dies (пробивної штамп), used for punching holes. Bending and folding dies are designed to make single or compound bends. A combination die is designed to perform more than one of the above operations in one stroke of the press. A progressive die permits successive forming operations with the same die.
In coining, metal is forced to flow into two matching dies, each of which bears a engraved design.
Wiredrawing Dies
In the manufacture of wire, a drawplate (волочильна дошка) is usually employed. This tool is a metal plate containing a number of holes, successively less in diameter and known as wire dies. A piece of metal is pulled through the largest die to make a coarse wire. This wire is then drawn through the smaller hole, and then the next, until the wire is reduced to the desired measurement. Wiredrawing dies are made from extremely hard materials, such as tungsten carbide or diamonds.
Thread-Cutting Dies
For cutting threads on bolts or on the outside of pipes, a thread-cutting die (різьбонарізна плашка) is used. It is usually made of hardened steel in the form of a round plate with a hole in the centre. The hole has a thread. To cut an outside thread, the die is lubricated with oil and simply screwed onto an unthreaded bolt or piece of pipe, the same way a nut is screwed onto a bolt. The corresponding tool for cutting an inside thread, such as that inside a nut, is called a tap (мітчик).
Vocabulary:
chip - стружка
sharp - гострий
friction - тертя
content - зміст
range - діапазон
inexpensive - недорогий
to permit - дозволяти, дозволяти
common - звичайний
tungsten - вольфрам
ingredient - інгредієнт
diamond - алмаз
tips - наконечники
ceramic - керамічний
truing - редагування, наводка, заточка
die - матриця, штамп
matrix - матриця
to employ - застосовувати
to pierce - протикати, проколювати
to punch - пробивати отвір
matching - поєднується, парний
coarse - грубий
wire - дріт
to draw - тягти, волочити
thread - різьблення
hardened - загартований
to lubricate - змащувати
to screw - прикручувати
nut - гайка
outside - зовнішній, зовнішній
inside - всередині, внутрішній
Exercise 4.4. Find English equivalents in the text:
1. видаляти металеву стружку
2. гострий ріжучий край
3. вміст вуглецю
4. ріжуча здатність
5. сталь для швидкісного різання
6. правка шліфувальних кіл
7. гідравлічне або механічний тиск
8. різні форми штампів
Exercise 4.5. Translate the following sentences into Russian:
1. Всі різці і фрези повинні мати гостру ріжучу кромку.
2. Під час різання ріжучий інструмент і деталь мають високу температуру і повинні охолоджуватися.
3. Вуглецеві стали часто використовуються для виготовлення різців тому, що вони недорогі.
4. Швидкорізальні сталі містять вольфрам, хром і ванадій.
5. Алмази використовуються для різання абразивних матеріалів і чистової обробки поверхні твердих матеріалів.
6. Для різних операцій використовують різні штампи.
7. Волочильні дошки для дроту робляться з дуже твердих матеріалів.
8. Різьбонарізні плашки і мітчики використовуються для нарізки різьби зовні і всередині.
FAMOUS PEOPLE OF SCIENCE AND ENGINEERING
George Stephenson
George Stephenson was a British inventor and engineer. He is famous for building the first practical railway locomotive.
Stephenson was born in 1781 in Wylam, near Newcastle upon Tyne, Northumberland. During his youth he worked as a fireman and later as an engineer in the coal mines of Newcastle. He invented one of the first miner's safety lamps independently of the British inventor Humphry Davy. Stephenson's early locomotives were used to carry loads in coal mines, and in 1823 he established a factory at Newcastle for their manufacture. In 1829 he designed a locomotive known as the Rocket, which could carry both loads and passengers at a greater speed than any locomotive constructed at that time. The success of the Rocket was the beginning of the construction of locomotives and the laying of railway lines.
Robert Stephenson, the son of George Stephenson was a British civil engineer. He is mostly well-known known for the construction of several notable bridges.
He was born in 1803 in Willington Quay, near Newcastle upon Tyne, and educated in Newcastle and at the University of Edinburgh. In 1829 he assisted his father in constructing a locomotive known as the Rocket, and four years later he was appointed construction engineer of the Birmingham and London Railway, completed in 1838. Stephenson built several famous bridges, including the Victoria Bridge in Northumberland, the Britannia Bridge in Wales, two bridges across the Nile in Damietta in Egypt and the Victoria Bridge in Montreal, Canada. Stephenson was a Member of Parliament from 1847 until his death in 1859.
UNIT 5
PLASTICS
I. Text A: «Plastics», Text B: «Types of plastics», Text C: «Composite Materials»
II. Famous People of Science: Alfred Bernhard Nobel.
Text A: «PLASTICS»
Plastics are non-metallic, synthetic, carbon-based materials. They can be moulded, shaped, or extruded into flexible sheets, films, or fibres. Plastics are synthetic polymers. Polymers consist of long-chain molecules made of large numbers of identical small molecules (monomers). The chemical nature of a plastic is defined by the monomer (repeating unit) that makes up the chain of the polymer. Polyethene is a polyolefin; its monomer unit is ethene (formerly called ethylene). Other categories are acrylics (such as polymethylmethacrylate), styrenes (such as polystyrene), vinys (such as polyvinyl chloride (PVC)), polyesters, polyurethanes, polyamides (such as nylons), polyethers, acetals, phenolics, cellulosics, and amino resins . The molecules can be either natural - like cellulose, wax, and natural rubber - or synthetic - in polyethene and nylon. In co-polymers, more than one monomer is used.
The giant molecules of which polymers consist may be linear, branched, or cross-linked, depending on the plastic. Linear and branched molecules are thermoplastic (soften when heated), whereas cross-linked molecules are thermosetting (harden when heated).
Most plastics are synthesized from organic chemicals or from natural gas or coal. Plastics are light-weight compared to metals and are good electrical insulators. The best insulators now are epoxy resins and teflon. Teflon or polytetrafluoroethene (PTFE) was first made in 1938 and was produced commercially in 1950.
Plastics can be classified into several broad types.
1. Thermoplastics soften on heating, then harden again when cooled. Thermoplastic molecules are also coiled and because of this they are flexible and easily stretched.
Typical example of thermoplastics is polystyrene. Polystyrene resins are characterized by high resistance to chemical and mechanical stresses at low temperatures and by very low absorption of water. These properties make the polystyrenes especially suitable for radio-frequency insulation and for parts used at low temperatures in refrigerators and in airplanes. PET (polyethene terephthalate) is a transparent thermoplastic used for soft-drinks bottles. Thermoplastics are also viscoelastic, that is, they flow (creep) under stress. Examples are polythene, polystyrene and PVC.
2. Thermosetting plastics (thermosets) do not soften when heated, and with strong heating they decompose. In most thermosets final cross-linking, which fixes the molecules, takes place after the plastic has already been formed.
Thermosetting plastics have a higher density than thermoplastics. They are less flexible, more difficult to stretch, and are less subjected to creep. Examples of thermosetting plastics include urea-formaldehyde or polyurethane and epoxy resins, most polyesters, and phenolic polymers such as phenol-formaldehyde resin.
3. Elastomers are similar to thermoplastics but have sufficient cross-linking between molecules to prevent stretching and creep.
Vocabulary:
carbon - вуглець
flexible - гнучкий
fibre - волокно, нитка
chain - ланцюг
identical - однаковий, ідентичний
molecule - молекула
branch - розгалужений
to synthesize - синтезувати
chemicals - хімічні речовини
to soften - пом'якшувати
cellulose - клітковина, целюлоза
wax - віск
thermosetting plastics - термореактивні пластмаси
to harden - робити твердим
coil - спіраль
stretched - розтягнутий
transparent - прозорий
rubber - гума, каучук
to decompose - розкладатися
soft-drink - безалкогольний напій
to subject - піддавати
polyurethane - поліуретан
resin - смола
similar - подібний, подібний
sufficient - достатній
to prevent - запобігати
General understanding
1. What is the definition of plastics?
2. What is the basic chemical element in plastics formula?
3. What do polymers consist of?
4. What are long-chain molecules made of?
5. What are the main types of polymers?
6. Give examples of plastics belonging to these types.
7. What plastics are the best electrical insulators?
8. Describe the difference between thermoplastics and thermosets.
9. What are the main types of structures of polymers?
10. What are the most important properties of plastics?
11. Give the examples of various uses of plastics because of their characteristic properties.
Exercise 5.1. Find English equivalents in the text:
1. синтетичні полімери
2. молекули з довгими ланцюгами
3. характерні властивості полімеру
4. синтезуються з органічних хімічних речовин
5. хороший електричний ізолятор
6. розм'якшуватися при нагріванні
7. тверднути при охолодженні
8. гнучкий і легко розтяжний
9. текти під навантаженням
10. більш висока щільність
11. менш схильні до повзучості
12. достатня взаємозв'язок між молекулами
Exercise 5.2. Translate into English:
1. Довгі ланцюги молекул полімерів складаються з однакових невеликих молекул мономерів.
2. Сополімери складаються з двох і більше мономерів.
3. Пластмаси можна одержувати у вигляді листів, тонких плівок, волокон або гранул.
4. Молекули полімерів можуть бути лінійними, розгалуженим чи з поперечними зв'язками.
5. Мала вага пластмас і добрі електроізоляційні властивості дозволяють використовувати їх в радіоелектроніці і електроприладах, а також замість металів.
6. Молекули термопластів мають звиту форму і, тому, вони гнучкі і легко розтяжним.
7. Еластоміри мають велике число поперечних зв'язків між молекулами.
Text В: «TYPES OF PLASTICS»
1. Epoxy resin.
Epoxy resin is a thermoset plastic containing epoxy groups. Epoxy resin hardens when it is mixed with solidifier and plasticizer. Plasticizers make a polymer more flexible.
Epoxy resins have outstanding adhesion, toughness, and resistance to attack from chemicals. They form strong bonds and have excellent electrical insulation properties. Large, complex, void-free castings can be made from them. They are also used as adhesives, and in composites for boat building and sports equipment.
2. PVC (polyvinyl chloride)
PVC (polyvinyl chloride) is a thermoplastic polymer made from vinyl chloride is a colourless solid with outstanding resistance to water, alcohols, and concentrated acids and alkalis. It is obtainable as granules, solutions, lattices, and pastes. When compounded with plasticizers, it yields a flexible material more durable than rubber. It is widely used for cable and wire insulation, in chemical plants, and in the manufacture of protective garments. Blow moulding of unplasticized PVC produces clear, tough bottles which do not affect the flavour of their contents. PVC is also used for production of tubes or pipes.
3. Polystyrene.
Polystyrene is a thermoplastic produced by the polymerization of styrene. The electrical insulating properties of polystyrene are outstandingly good and it is relatively unaffected by water. Typical applications include light fixtures, toys, bottles, lenses, capacitor dielectrics, medical syringes, and light-duty industrial components. Extruded sheets of polystyrene are widely used for packaging, envelope windows, and photographic film. Its resistance to impact can be improved by the addition of rubber modifiers. Polystyrene can be readily foamed; the resulting foamed polystyrene is used extensively for packaging.
4. Polythene (polyethene, polyethylene)
Polythene (polyethene, polyethylene) is a plastic made from ethane. It is one of the most widely used important thermoplastic polymers. It was first developed by the polymerization of ethane at a pressure of 2,000 bar at 200 ° C. This produced low-density polythene (LDPE). A relatively high-density form (HDPE) was synthesized in the 1950s using a complex catalyst. Polythene is a white waxy solid with very low density, reasonable strength and toughness, but low stiffness. It is easily moulded and has a wide range of uses in containers, packaging, pipes, coatings, and insulation.
Vocabulary:
adhesion - прилипання
adhesive - клей
bond - зв'язки, узи
insulation - ізоляція
casting - лиття
void - порожнеча
solid - тверде тіло, твердий
acid - кислота
alkali - луг
to obtain - діставати, отримувати
granule - гранула
solution - розчин
lattices - латекси
paste - паста
yield - вихід
durable - міцний
rubber - гума, каучук
garment - предмети одягу
lens-лінза
capacitor - ел. конденсатор
syringe - шприц
light-duty - невідповідальний
envelope - зд. обрамлення
impact - удар
improved - покращений
modifiers - модифікатори
addition - додавання
readily - легко, з готовністю
foam - піна
catalyst - каталізатор
wax - віск
reasonable - прийнятний, непоганий
coating - шар, покриття
General understanding:
1. What are the types of plastics?
2. What are the features of the epoxy resin?
3. What is epoxy resin used for?
4. What is PVC usually used for?
5. What are the typical applications of polystyrene?
6. When was polyethylen synthesized?
7. Under what conditions is polyethylen synthesized?
8. What sorts of polyethylen can be synthesized?
Exercise 5.3. Translate into Russian:
1. Polythene is a plastic made from ethane.
2. Epoxy resins have outstanding adhesion, toughness and resistance to attack from chemicals.
3. PVC is a colourless solid with outstanding resistance to water, alcohols, and concentrated acids and alkalis.
4. Polystyrene is a thermoplastic produced by the polymerization of styrene.
5. Polythene is a white waxy solid with very low density, reasonable strength and toughness but low stiffness.
Exercise 5.4. Translate into English:
1. Епоксидна смола твердне коли змішується з затверджувачем і пластифікатором.
2. Епоксидні смоли використовуються в якості клею, а з добавками - у будівництві човнів та спортивного спорядження.
3. ПВХ - безбарвне тверда речовина з видатною стійкістю до дії води, спиртів, концентрованих кислот і лугів.
4. ПВХ широко використовується при виробництві ізоляції для проводів.
5. Видувки непластифікованого ПВХ використовується при виробництві прозорих пляшок для напоїв.
6. Полістирол легко спінюється й використовується для упаковки.
7. Поліетилен - воскоподібне речовина білого кольору з дуже низькою щільністю і малою жорсткістю.
Text З: «COMPOSITE MATERIALS»
The combinations of two or more different materials are called composite materials. They usually have unique mechanical and physical properties because they combine the best properties of different materials. For example, a fibre-glass reinforced plastic combines the high strength of thin glass fibres with the ductility and chemical resistance of plastic. Nowadays composites are being used for structures such as bridges, boat-building etc.
Composite materials usually consist of synthetic fibres within a matrix, a material that surrounds and is tightly bound to the fibres. The most widely used type of composite material is polymer matrix composites (PMCs). PMCs consist of fibres made of a ceramic material such as carbon or glass embedded in a plastic matrix. Usually the fibres make up about 60 per cent by volume. Composites with metal matrices or ceramic matrices are called metal matrix composites (MMCs) and ceramic matrix composites (CMCs), respectively.
Continuous-fibre composites are generally required for structural applications. The specific strength (strength-to-density ratio) and specific stiffness (elastic modulus-to-density ratio) of continuous carbon fibre PMCs, for example, can be better than metal alloys have. Composites can also have other attractive properties, such as high thermal or electrical conductivity and a low coefficient of thermal expansion.
Although composite materials have certain advantages over conventional materials, composites also have some disadvantages. For example, PMCs and other composite materials tend to be highly anisotropic - that is, their strength, stiffness, and other engineering properties are different depending on the orientation of the composite material. For example, if a PMC is fabricated so that all the fibres are lined up parallel to one another, then the PMC will be very stiff in the direction parallel to the fibres, but not stiff in the perpendicular direction. The designer who uses composite materials in structures subjected to multidirectional forces, must take these anisotropic properties into account. Also, forming strong connections between separate composite material components is difficult.
The advanced composites have high manufacturing costs. Fabricating composite materials is a complex process. However, new manufacturing techniques are developed. It will become possible to produce composite materials at higher volumes and at a lower cost than is now possible, accelerating the wider exploitation of these materials.
Vocabulary:
fibreglass - скловолокно
fibre - волокно, нитка
reinforced - зміцнений
expansion - розширення
matrix - матриця
ceramic - керамічний
specific strength - питома міцність
specific stiffness - питома жорсткість
anisotropic - анізотропний
General understanding:
1. What is called «composite materials»?
2. What are the best properties of fibre-glass?
3. What do composite material usually consist of?
4. What is used as matrix in composites?
5. What is used as filler or fibers in composites?
6. How are the composite materials with ceramic and metal matrices called?
7. What are the advantages of composites?
8. What are the disadvantages of composites?
9. Why anisotropic properties of composites should be taken into account?
Exercise 5.5. Find equivalents in the text:
1. композитні матеріали
2. унікальні механічні якості
3. полімерні композити матричні
4. становити 60% обсягу
5. вуглепластик
6. привабливі якості
7. структура, що піддається впливу різноспрямованих сил
Exercise 5.6. Translate into Russian:
1. PMC is fabricated so that all the fibres are lined up parallel to one another.
2. Forming strong connections between separate composite material components is difficult.
3. Fabricating composite materials is a complex process.
4. Composite materials have certain advantages over conventional materials
5. Nowadays, composites are being used for structures such as bridges, boat-building etc.
6. Continuous-fibre composites are generally required for structural applications.
FAMOUS INVENTORS
Alfred Bernhard Nobel was a famous Swedish chemist and inventor. He was born in Stockholm in 1833. After receiving an education in St. Petersburg, Russia, and then in the United States, where he studied mechanical engineering, he returned to St. Petersburg to work with his father in Russia. They were developing mines, torpedoes, and other explosives.
In a family-owned factory in Heleneborg, Sweden, he developed a safe way to handle nitroglycerine, after a factory explosion in 1864 killed his younger brother and four other people. In 1867 Nobel achieved his goal: he produced what he called dynamite динаміт. Чи не later produced one of the first smokeless powders (порох). At the time of his death he controlled factories for the manufacture of explosives (вибухова речовина) in many parts of the world. In his will he wanted that the major portion of his money left became a fund for yearly prizes in his name. The prizes were to be given for merits (заслуги) in physics, chemistry, medicine and physiology, literature, and world peace. A prize in economics has been awarded since 1969.
UNIT 6
WELDING
I. Text A: «Welding», Text В: «Other types of welding»
II. Famous People of Science and Technology: James Prescott Joule.
Text A: «WELDING»
Welding is a process when metal parts are joined together by the application of heat, pressure, or a combination of both. The processes of welding can be divided into two main groups:
• pressure welding, when the weld is achieved by pressure and
• heat welding, when the weld is achieved by heat. Heat welding is the most common welding process used today.
Nowadays welding is used instead of bolting and riveting in the construction of many types of structures, including bridges, buildings, and ships. It is also a basic process in the manufacture of machinery and in the motor and aircraft industries. It is necessary almost in all productions where metals are used.
The welding process depends greatly on the properties of the metals, the purpose of their application and the available equipment. Welding processes are classified according to the sources of heat and pressure used.
The welding processes widely employed today include gas welding, arc welding, and resistance welding. Other joining processes are laser welding, and electron-beam welding.
Gas Welding
Gas welding is a non-pressure process using heat from a gas flame. The flame is applied directly to the metal edges to be joined and simultaneously to a filler metal in the form of wire or rod, called the welding rod, which is melted to the joint. Gas welding has the advantage of using equipment that is portable and does not require an electric power source. The surfaces to be welded and the welding rod are coated with flux, a fusible material that shields the material from air, which would result in a defective weld.
Arc Welding
Arc-welding is the most important welding process for joining steels. It requires a continuous supply of either direct or alternating electrical current. This current is used to create an electric arc, which generates enough heat to melt metal and create a weld.
Arc welding has several advantages over other welding methods. Arc welding is faster because the concentration of heat is high. Also, fluxes are not necessary in certain methods of arc welding. The most widely used arc-welding processes are shielded metal arc, gas-tungsten arc, gas-metal arc, and submerged arc.
Shielded Metal Arc
In shielded metal-arc welding, a metallic electrode, which conducts electricity, is coated with flux and connected to a source of electric current. The metal to be welded is connected to the other end of the same source of current. An electric arc is formed by touching the tip of the electrode to the metal and then drawing it away. The intense heat of the arc melts both parts to be welded and the point of the metal electrode, which supplies filler metal for the weld. This process is used mainly for welding steels.
Vocabulary:
to join - з'єднувати
pressure welding - зварювання тиском
heat welding - зварювання нагріванням
instead - замість, натомість
bolting - скріплення болтами
riveting - клепка
basic - основний
to manufacture - виготовляти
to depend - залежатиме від
purpose - мета
available - наявний
equipment - обладнання
source - джерело
gas welding - газозварювання
arc welding - електродугова зварювання
resistance welding - контактне зварювання
laser welding - лазерне зварювання
electron-beam welding - електронно-променева зварювання
flame - полум'я
edge - край
simultaneously - одночасно
filler - наповнювач
wire - дріт
rod - прут, стрижень
to melt - плавити (ся)
joint - з'єднання, стик
advantage - перевага
to require - вимагати потребувати
surface - поверхня
coated - покритий
flux - флюс
fusible - плавкий
to shield - затуляти, захищати
touching - торкання
tip - кінчик
General understanding:
1. How can a process of welding be defined?
2. What are the two main groups of processes of welding?
3. How can we join metal parts together?
4. What is welding used for nowadays?
5. Where is welding necessary?
6. What do the welding processes of today include?
7. What are the principles of gas welding?
8. What kinds of welding can be used for joining steels?
9. What does arc welding require? 10. What is the difference between the arc welding and shielded-metal welding?
Exercise 6.1. Find the following words and word combinations in the text:
1. зварювання тиском
2. теплова зварювання
3. болтове (клепані) з'єднання
4. процес зварювання
5. залежати від властивостей металів
6. наявне обладнання
7. зварювальний електрод
8. плавкий матеріал
9. дефектний зварний шов
10. безперервна подача електричного струму
11. електрична дуга
12. джерело електричного струму
Text В: «OTHER TYPES OF WELDING»
Non-consumable Electrode Arc welding
As a non-consumable electrodes tungsten or carbon electrodes can be used. In gas-tungsten arc welding a tungsten electrode is used in place of the metal electrode used in shielded metal-arc welding. A chemically inert gas, such as argon, helium, or carbon dioxide is used to shield the metal from oxidation. The heat from the arc formed between the electrode and the metal melts the edges of the metal. Metal for the weld may be added by placing a bare wire in the arc or the point of the weld. This process can be used with nearly all metals and produces a high-quality weld. However, the rate of welding is considerably slower than in other processes.
Gas-Metal Arc
In gas-metal welding, a bare electrode is shielded from the air by surrounding it with argon or carbon dioxide gas and sometimes by coating the electrode with flux. The electrode is fed into the electric arc, and melts off in droplets that enter the liquid metal of the weld seam. Most metals can be joined by this process.
Submerged Arc
Submerged-arc welding is similar to gas-metal arc welding, but in this process no gas is used to shield the weld. Instead of that, the arc and tip of the wire are submerged beneath a layer of granular, fusible material that covers the weld seam. This process is also called electroslag welding. It is very efficient but can be used only with steels.
Resistance Welding
In resistance welding, heat is obtained from the resistance of metal to the flow of an electric current. Electrodes are clamped on each side of the parts to be welded, the parts are subjected to great pressure, and a heavy current is applied for a short period of time. The point where the two metals touch creates resistance to the flow of current. This resistance causes heat, which melts the metals and creates the weld. Resistance welding is widely employed in many fields of sheet metal or wire manufacturing and is often used for welds made by automatic or semi-automatic machines especially in automobile industry.
Vocabulary
gas-tungsten - зварювання оплавленням вольфрамовим електродом в середовищі інертного газу
inert - інертний
edge - край
bare - голий
rate - зд. швидкість
gas-metal arc - аргонодуговая зварювання
considerably - значно, значно
surrounding - навколишній
carbon dioxide - вуглекислий газ
droplet - крапелька
liquid - рідина, рідкий
beneath - під, нижче, внизу
layer - шар
weld seam - зварний шов
resistance - опір
clamp - затиск, затискати
sheet - лист
fusible - плавкий
granular - плавкий
semi-automatic - напівавтоматична
to create - створювати
to submerge - занурювати
General understanding:
1. What is the difference between the arc-welding and non-consumable electrode arc welding?
2. What are the disadvantages of the non-consumable electrode arc welding?
3. How is electrode protected from the air in gas-metal arc welding?
4. What is submerged arc welding?
5. What is the principle of resistance welding?
6. Where is semi-automatic welding employed?
Exercise 6.2. Translate into English:
1. вольфрамовий електрод
2. інертний газ
3. окислення
4. високоякісний зварювальний шов
5. швидкість зварювання
6. аргон, гелій, вуглекислий газ
7. рідкий метал
8. шар плавкого матеріалу у вигляді гранул
9. листовий метал
10. полувтоматіческіе зварювальні верстати
Exercise 6.3. Translate into Russian:
1. In resistance welding, heat is obtained from the resistance of metal to the flow of an electric current.
2. The heat from the arc melts the edges of the metal.
3. A bare electrode is shielded from the air by surrounding it with argon or carbon dioxide gas.
4. Submerged-arc welding is similar to gas-metal arc welding.
5. Electrodes are clamped on each side of the parts to be welded.
6. Resistance causes heat which melts the metals and creates the weld.
FAMOUS PEOPLE OF SCIENCE AND TECHNOLOGY
James Prescott Joule, famous British physicist, was born in 1818 in Salford, England.
Joule was one of the most outstanding physicists of his time. He is best known for his research in electricity and thermodynamics. In the course of his investigations of the heat emitted in an electrical circuit, he formulated the law, now known as Joule's law of electric heating. This law states that the amount of heat produced each second in a conductor by electric current is proportional to the resistance of the conductor and to the square of the current. Joule experimentally verified the law of conservation of energy in his study of the conversion of mechanical energy into heat energy.
Joule determined the numerical relation between heat and mechanical energy, or the mechanical equivalent of heat, using many independent methods. The unit of energy, called the joule, is named after him. It is equal to 1 watt-second. Together with the physicist William Thomson (Baron Kelvin), Joule found that the temperature of a gas falls when it expands without doing any work. This phenomenon, which became known as the Joule-Thomson effect, lies in the operation of modern refrigeration and air-conditioning systems.
UNIT 7
AUTOMATION AND ROBOTICS
I. Text A: «Automation», Text B: «Types of automation»,
Text C: «Robots In manufacturing»
II. Famous people of science and technology: James Watt.
Text A: «AUTOMATION»
Automation is the system of manufacture performing certain tasks, previously done by people, by machines only. The sequences of operations are controlled automatically. The most familiar example of a highly automated system is an assembly plant for automobiles or other complex products.
The term automation is also used to describe non-manufacturing systems in which automatic devices can operate independently of human control. Such devices as automatic pilots, automatic telephone equipment and automated control systems are used to perform various operations much faster and better than could be done by people.
Automated manufacturing had several steps in its development. Mechanization was the first step necessary in the development of automation. The simplification of work made it possible to design and build machines that resembled the motions of the worker. These specialized machines were motorized and they had better production efficiency.
Industrial robots, originally designed only to perform simple tasks in environments dangerous to human workers, are now widely used to transfer, manipulate, and position both light and heavy workpieces performing all the functions of a transfer machine.
In the 1920s the automobile industry for the first time used an integrated system of production. This method of production was adopted by most car manufacturers and became known as Detroit automation.
The feedback principle is used in all automatic-control mechanisms when machines have ability to correct themselves. The feedback principle has been used for centuries. An outstanding early example is the flyball governor, invented in 1788 by James Watt to control the speed of the steam engine. The common household thermostat is another example of a feedback device.
Using feedback devices, machines can start, stop, speed up, slow down, count, inspect, test, compare, and measure. These operations are commonly applied to a wide variety of production operations.
Computers have greatly facilitated the use of feedback in manufacturing processes. Computers gave rise to the development of numerically controlled machines. The motions of these machines are controlled by punched paper or magnetic tapes. In numerically controlled machining centres machine tools can perform several different machining operations.
More recently, the introduction of microprocessors and computers have made possible the development of computer-aided design and computer-aided manufacture (CAD and CAM) technologies. When using these systems a designer draws a part and indicates its dimensions with the help of a mouse, light pen, or other input device. After the drawing has been completed the computer automatically gives the instructions that direct a machining centre to machine the part.
Another development using automation are the flexible manufacturing systems (FMS). A computer in FMS can be used to monitor and control the operation of the whole factory.
Automation has also had an influence on the areas of the economy other than manufacturing. Small computers are used in systems called word processors, which are rapidly becoming a standard part of the modern office. They are used to edit texts, to type letters and so on.
Automation in Industry
Many industries are highly automated or use automation technology in some part of their operation. In communications and especially in the telephone industry dialing and transmission are all done automatically. Railways are also controlled by automatic signaling devices, which have sensors that detect carriages passing a particular point. In this way the movement and location of trains can be monitored.
Not all industries require the same degree of automation. Sales, agriculture, and some service industries are difficult to automate, though agriculture industry may become more mechanized, especially in the processing and packaging of foods.
The automation technology in manufacturing and assembly is widely used in car and other consumer product industries.
Nevertheless, each industry has its own concept of automation that answers its particular production needs.
Vocabulary:
automation - автоматизація
previously - раніше
sequence - послідовність
assembly plant - складальний завод
non-manufacturing - невиробничий
device - пристрій, прилад
resemble - походити
efficiency - ефективність
flyball governor - відцентровий регулятор
steam engine - паровоз
household thermostat - побутової термостат
facilitate - сприяти
punched - перфорований
aid - допомога
dimension - вимірювання, розміри
General understanding:
1. How is the term automation defined in the text?
2. What is the most «familiar example» of automation given in the text?
3. What was the first step in the development of automaton?
4. What were the first robots originally designed for?
5. What was the first industry to adopt the new integrated system of production?
6. What is feedback principle?
7. What do the abbreviations CAM and CAD stand for?
8. What is FMS?
9. What industries use automation technologies?
Exercise 7.1. Find the following words and word combinations in the text:
1. автоматичні пристрої
2. автоматизоване виробництво
3. виконувати прості завдання
4. як легкі, так і важкі деталі
5. інтегрована система виробництва
6. принцип зворотного зв'язку
7. механізм може розганятися і гальмувати
8. комп'ютер автоматично посилає команди
9. високоавтоматизована система
10. невиробнича система
Text В: «TYPES OF AUTOMATION»
Applications of Automation and Robotics in Industry
Manufacturing is one of the most important application area for automation technology. There are several types of automation in manufacturing. The examples of automated systems used in manufacturing are described below.
1. Fixed automation, sometimes called «hard automation» refers to automated machines in which the equipment configuration allows fixed sequence of processing operations. These machines are programmed by their design to make only certain processing operations. They are not easily changed over from one product style to another. This form of automation needs high initial investments and high production rates. That is why it is suitable for products that are made in large volumes. Examples of fixed automation are machining transfer lines found in the automobile industry, automatic assembly machines and certain chemical processes.
2. Programmable automation is a form of automation for producing products in large quantities, ranging from several dozen to several thousand units at a time. For each new product the production equipment must be reprogrammed and changed over. This reprogramming and changeover take a period of non-productive time. Production rates in programmable automation are generally lower than in fixed automation, because the equipment is designed to facilitate product changeover rather than for product specialization. A numerical-control machine-tool is a good example of programmable automation. The program is coded in computer memory for each different product style and the machine-tool is controlled by the computer programme.
3. Flexible automation is a kind of programmable automation. Programmable automation requires time to re-program and change over the production equipment for each series of new product. This is lost production time, which is expensive. In flexible automation the number of products is limited so that the changeover of the equipment can be done very quickly and automatically. The reprogramming of the equipment in flexible automation is done at a computer terminal without using the production equipment itself. Flexible automation allows a mixture of different products to be produced one right after another.
Vocabulary
equipment - обладнання
sequence - послідовність
initial - початковий, початковий
investment - інвестиція, вклад
to facilitate - сприяти
rate - швидкість, темп
assembly machines - складальні машини
quantity - кількість
non-productive - непродуктивний
changeover - перехід, переналагодження
General understanding:
1. What is the most important application of automation?
2. What are the types of automation used in manufacturing?
3. What is fixed automation?
4. What are the limitations of hard automation?
5. What is the best example of programmable automation?
6. What are the limitations of programmable automation?
7. What are the advantages of flexible automation?
8. Is it possible to produce different products one after another using automation technology?
Exercise 7.2. Find equivalents in English in the text:
1. сфера застосування
2. фіксована послідовність операцій
3. автоматичні складальні машини
4. певні хімічні процеси
5. верстат з числовим програмним управлінням
6. втрачене виробниче час
7. різноманітна продукція
Exercise 7.3. Explain in English what does the following mean?
1. automation technology
2. fixed automation
3. assembly machines
4. non-productive time
5. programmable automation
6. computer terminal
7. numerical-control machine-tool
Text C: «ROBOTS IN MANUFACTURING»
Today most robots are used in manufacturing operations. The applications of robots can be divided into three categories:
1. material handling
2. processing operations
3. assembly and inspection.
Material-handling is the transfer of material and loading and unloading of machines. Material-transfer applications require the robot to move materials or work parts from one to another. Many of these tasks are relatively simple: robots pick up parts from one conveyor and place them on another. Other transfer operations are more complex, such as placing parts in an arrangement that can be calculated by the robot. Machine loading and unloading operations utilize a robot to load and unload parts. This requires the robot to be equipped with a grip-per that can grasp parts. Usually the gripper must be designed specifically for the particular part geometry.
In robotic processing operations, the robot manipulates a tool to perform a process on the work part. Examples of such applications include spot welding, continuous arc welding and spray painting. Spot welding of automobile bodies is one of the most common applications of industrial robots. The robot positions a spot welder against the automobile panels and frames to join them. Arc welding is a continuous process in which robot moves the welding rod along the welding seam. Spray painting is the manipulation of a spray-painting gun over the surface of the object to be coated. Other operations in this category include grinding and polishing in which a rotating spindle serves as the robot's tool.
The third application area of industrial robots is assembly and inspection. The use of robots in assembly is expected to increase because of the high cost of manual labour. But the design of the product is an important aspect of robotic assembly. Assembly methods that are satisfactory for humans are not always suitable for robots. Screws and nuts are widely used for fastening in manual assembly, but the same operations are extremely difficult for an one-armed robot.
Inspection is another area of factory operations in which the utilization of robots is growing. In a typical inspection job, the robot positions a sensor with respect to the work part and determines whether the part answers the quality specifications. In nearly all industrial robotic applications, the robot provides a substitute for human labour. There are certain characteristics of industrial jobs performed by humans that can be done by robots:
1. the operation is repetitive, involving the same basic work motions every cycle,
2. the operation is hazardous or uncomfortable for the human worker (for example: spray painting, spot welding, arc welding, and certain machine loading and unloading tasks),
3. the workpiece or tool is too heavy and difficult to handle,
4. the operation allows the robot to be used on two or three shifts.
Vocabulary:
handling - звернення
transfer - передача, перенесення
location - місцезнаходження
pick up - брати, підбирати
arrangement - розташування
to utilize - утилізувати, знаходити застосування
gripper - захоплення
to grasp - схоплювати
spot welding - точкове зварювання
continuous - безперервний
arc welding - електродугова зварювання
spray painting - забарвлення розпиленням
frame - рама
spray-painting gun - розпилювач фарби
grinding - шліфування
polishing - полірування
spindle - шпиндель
manual - ручний
labour - праця
hazardous - небезпечний
shift - зміна
General understanding:
1. How are robots used in manufacturing?
2. What is «material handling»?
3. What does a robot need to be equipped with to do loading and unloading operations?
4. What does robot manipulate in robotic processing operation?
5. What is the most common application of robots in automobile manufacturing?
6. What operations could be done by robot in car manufacturing industry?
7. What are the main reasons to use robots in production?
8. How can robots inspect the quality of production?
9. What operations could be done by robots in hazardous or uncomfortable for the human workers conditions?
Exercise 7.4. Translate into English:
1. Існує кілька різних сфер використання автоматизації в виробництві.
2. Для використання жорсткої автоматизації необхідні великі інвестиції.
3. Жорстка автоматизація широко використовується в хімічній промисловості.
4. Верстати з числовим програмним управлінням - хороший приклад програмованої автоматизації.
5. Гнучка автоматизація робить можливим перепрограмування обладнання.
6. Час простою обладнання обертається великими збитками.
7. Використання гнучкої автоматизації робить можливим виробництво різноманітної продукції.
FAMOUS PEOPLE OF SCIENCE AND ENGINEERING
James Watt
James Watt was a Scottish inventor and mechanical engineer, known for his improvements of the steam engine.
Watt was born on January 19, 1736, in Greenock, Scotland. He worked as a mathematical-instrument maker from the age of 19 and soon became interested in improving the steam engine which was used at that time to pump out water from mines.
Watt determined the properties of steam, especially the relation of its density to its temperature and pressure, and designed a separate condensing chamber for the steam engine that prevented large losses of steam in the cylinder. Watt's first patent, in 1769, covered this device and other improvements on steam engine.
At that time. Watt was the partner of the inventor John Roebuck, who had financed his researches. In 1775, however. Roebuck's interest was taken over by the manufacturer Matthew Boulton, owner of the Soho Engineering Works at Birmingham, and he and Watt began the manufacture of steam engines. Watt continued his research and patented several other important inventions, including the rotary engine for driving various types of machinery; the double-action engine, in which steam is admitted alternately into both ends of the cylinder; and the steam indicator, which records the steam pressure in the engine. He retired from the firm in 1800 and thereafter devoted himself entirely to research work.
The misconception that Watt was the actual inventor of the steam engine arose from the fundamental nature of his contributions to its development. The centrifugal or flyball governor, which he invented in 1788, and which automatically regulated the speed of an engine, is of particular interest today. It embodies the feedback principle of a servomechanism, linking output to input, which is the basic concept of automation. The watt, the unit of power, was named in his honour. Watt was also a well-known civil engineer. He invented, in 1767, an attachment that adapted telescopes for use in the measurement of distances. Watt died in Heathfield, near Birmingham, in August 1819.
UNIT8
COMPUTERS
I. Text A: «What is a computer?», Text B: «Hardware», Text C: «Types of software»
II. Famous people of science and engineering: Charles Babbage.
Text A: «WHAT IS A COMPUTER?»
The term computer is used to describe a device made up of a combination of electronic and electromechanical (part electronic and part mechanical) components. Computer has no intelligence by itself and is referred to as hardware. A computer system is a combination of five elements:
• Hardware
• Software
• People
• Procedures
• Data / information
When one computer system is set up to communicate with another computer system, connectivity becomes the sixth system element. In other words, the manner in which the various individual systems are connected - for example, by phone lines, microwave transmission, or satellite - is an element of the total computer system.
Software is the term used to describe the instructions that tell the hardware how to perform a task. Without software instructions, the hardware doesn't know what to do. People, however, are the most important component of the computer system: they create the computer software instructions and respond to the procedures that those instructions present.
The basic job of the computer is the processing of information. Computers accept information in the form of instruction called a program and characters called data to perform mathematical and logical operations, and then give the results. The data is raw material while information is organized, processed, refined and useful for decision making. Computer is used to convert data into information. Computer is also used to store information in the digital form.
Vocabulary:
characters - символи
data - дані
decision - рішення
device - пристрій
hardware - обладнання
instruction - команда
intelligence - розум
manner - манера, спосіб
microwave - мікрохвильова
procedures - процедури, операції
purpose - мета
raw - необроблений, сирої
to come to life - оживати
to connect - з'єднувати
to convert - перетворювати, перетворювати
to create - створювати
to evaluate - оцінювати
to refer to as - називати що-небудь
to refine - очищати
to respond - відповідати
transmission - передача
various - різні
General understanding:
1) What does the term «computer» describe?
2) Is computer intelligent?
3) What are five components of computer system?
4) What is connectivity?
5) What is software? What's the difference between hardware and software?
6) Why people are the most important component of a computer system?
7) In what way terms «data» and «information» differ?
8) How does computer convert data into information?
Exercise 8.1. Which of the listed below terms have Russian equivalents:
computer, diskette, metal, processor, scanner, information, data, microphones, printer, modem, Internet.
Exercise 8.2. Which of the listed above statements are true / false. Specify your answer using the text.
1) Computer is made of electronic components so it is referred to as electronic device.
2) Computer has no intelligence until software is loaded.
3) There are five elements of computer system: hardware, software, people, diskettes and data.
4) The manner in which computers are connected is the connectivity.
5) Without software instructions hardware doesn't know what to do.
6) The software is the most important component because it is made by people.
7) The user inputs data into computer to get information as an output.
8) Computer is used to help people in decision making process.
Exercise 8.3. Match the following:
1) ... doesn't come to life until it is connected to other parts of a system.
2) ... is the term used to describe the instructions that tell the hardware how to perform a task.
3) ... create the computer software instructions and respond to the procedures that those instructions present
4) Information in the form of instruction is called a. ..
5) The manner in which the various individual systems are connected is ...
6) ... is organized, processed and useful for decision making
7) The basic job of the computer is the ...
a) program
b) information
c) processing of information
d) software
e) connectivity
f) computer
g) people
Exercise 8.4. Translate the text. Retell the text, using the vocabulary.
Exercise 8.5. Questions for group discussion:
1) Why so many people are still «computer illiterate»?
2) What are the most important applications of computer? (Are computer games just a «waste of time» or it is a nice hobby and a lot of fun?)
3) Who has a computer in your group? Ask them what they use it for?
Text B: «HARDWARE»
What is hardware? Webster's dictionary gives us the following definition of the hardware - the mechanical, magnetic, electronic, and electrical devices composing a computer system.
Computer hardware can be divided into four categories:
1) input hardware
2) processing hardware
3) storage hardware
4) output hardware.
Input hardware
The purpose of the input hardware is to collect data and convert it into a form suitable for computer processing. The most common input device is a keyboard. It looks very much like a typewriter. The mouse is a hand held device connected to the computer by small cable. As the mouse is rolled across the mouse pad, the cursor moves across the screen. When the cursor reaches the desired location, the user usually pushes a button on the mouse once or twice to signal a menu selection or a command to the computer.
The light pen uses a light sensitive photoelectric cell to signal screen position to the computer. Another type of input hardware is optic-electronic scanner that is used to input graphics as well as typeset characters. Microphone and video camera can be also used to input data into the computer. Electronic cameras are becoming very popular among the consumers for their relatively low price and convenience.
Processing hardware
The purpose of processing hardware is retrieve, interpret and direct the execution of software instructions provided to the computer. The most common components of processing hardware are the Central Processing Unit and main memory.
The Central Processing Unit (CPU) is the brain of the computer. It reads and interprets software instructions and coordinates the processing activities that must take place. The design of the CPU affects the processing power and the speed of the computer, as well as the amount of main memory it can use effectively. With a well-designed CPU in your computer, you can perform highly sophisticated tasks in a very short time.
Memory is the system of component of the computer in which information is stored. There are two types of computer memory: RAM and ROM.
RAM (random access memory) is the volatile computer memory, used for creating loading, and running programs and for manipulating and temporarily storing data;
ROM (read only memory) is nonvolatile, non-modifiable computer memory, used to hold programmed instructions to the system.
The more memory you have in your computer, the more operations you can perform.
Storage hardware
The purpose of storage hardware is to store computer instructions and data in a form that is relatively permanent and retrieve when needed for processing. Storage hardware serves the same basic functions as do office filing systems except that it stores data as electromagnetic signals. The most common ways of storing data are Hard disk, floppy disk and CD-ROM.
Hard disk is a rigid disk coated with magnetic material, for storing programs and relatively large amounts of data.
Floppy disk (diskette) - thin, usually flexible plastic disk coated with magnetic material, for storing computer data and programs. There are two formats for floppy disks: 5.25 "and 3.5". 5.25 "is not used in modern computer systems because of it relatively large size flexibility and small capacity. 3.5" disks are formatted 1.4 megabytes and are widely used.
CD-ROM (compact disc read only memory) is a compact disc on which a large amount of digitized read-only data can be stored. CD-ROMs are very popular now because of the growing speed which CD-ROM drives can provide nowadays. Output hardware
The purpose of output hardware is to provide the user with the means to view information produced by the computer system. Information is output in either hardcopy or softcopy form. Hardcopy output can be held in your hand, such as paper with text (word or numbers) or graphics printed on it. Softcopy output is displayed on a monitor.
Monitor is a component with a display screen for viewing computer data, television programs, etc.
Printer is a computer output device that produces a paper copy of data or graphics.
Modem is an example of communication hardware - an electronic device that makes possible the transmission of data to or from computer via telephone or other communication lines.
Hardware comes in many configurations, depending on what the computer system is designed to do. Hardware can fill several floors of a large office building or can fit on your lap.
Vocabulary:
amount - кількість
capacity - місткість
circuitry - ел. ланцюга
CPU, microprocessor - мікропроцесор
hard disk - жорсткий диск, «вінчестер»
input hardware - пристрої введення даних
keyboard - клавіатура
lap - коліна
modem - модем
mouse - пристрій для переміщення об'єктів на екрані, «миша»
output hardware - вихідні пристрої відображення інформації
printer - принтер
processing hardware - пристрої обробки даних
RAM - ОЗП (оперативний запам'ятовуючий пристрій)
ROM - ПЗП (постійний запам'ятовуючий пристрій)
CD-ROM - накопичувач на компакт-дисках (CD)
scanner - сканер
sensitive - чутливий
sophisticated - складний
storage hardware - пристрої зберігання даних
temporarily - тимчасово
temporary - тимчасовий
the purpose - мета
tier - ярус
to affect - впливати
to connect - з'єднувати
to convert - перетворювати
to direct - керувати
to execute - виконувати
to interpret - переводити
to provide - забезпечувати
to reach - досягати
to retrieve - витягати
to roll - катати, перекочувати
volatile - летючий, нестійкий, тимчасовий
General understanding:
1. What is the Webster's dictionary definition of the hardware?
2. What groups of hardware could be defined?
3. What is input hardware? What are the examples of input hardware?
4. What is mouse designed for? What is a light pen?
5. What is processing hardware? What are the basic types of memory used in a PC?
6. Can a PC-user change the ROM? Who records the information in ROM?
7. What is storage hardware? What is CD-ROM used for? Can a user record his or her data on a CD? What kind of storage hardware can contain more information: CD-ROM, RAM or ROM?
8. What is modem used for? Can PC-user communicate with other people without a modem?
Exercise 8.6. Which of the listed below statements are true / false. Specify your answer using the text.
1) Computer is an electronic device therefore hardware is a system of electronic devices.
2) The purpose of the input hardware is to collect data and convert it into a form suitable for computer processing.
3) Scanner is used to input graphics only.
4) The purpose of processing hardware is to retrieve, interpret and direct the execution of software instructions provided to the computer.
5) CPU reads and interprets software and prints the results on paper.
6) User is unable to change the contents of ROM.
7) 5.25 "floppy disks are used more often because they are flexible and have more capacity than 3.5" disks.
5) Printer is a processing hardware because its purpose is to show the information produced by the system.
6) Modem is an electronic device that makes possible the transmission of data from one computer to another via telephone or other communication lines.
7) The purpose of storage hardware is to store computer instructions and data in a form that is relatively permanent and retrieve them when needed for processing.
Exercise8.7. Give definitions to the following using the vocabulary
1) CPU
2) ROM
3) Floppy-disk
4) CD-ROM
5) Printer
6) Modem
7) Motherboard
8) Hard disk
9) Keyboard
10) Sound-card
Exercise 8.8. Which of the following is Hardware:
1) program
2) mouse
3) CPU
4) printer
5) modem
6) command
7) port
8) cursor or the pointer
9) keyboard
10) character
Exercise 8.9. Match the following:
1) процесор
2) клавіатура
3) миша
4) дискета
5) «вінчестер»
6) модем
7) екран
8) ПЗУ
9) ОЗУ
a) nonvolatile, non-modifiable computer memory, used to hold programmed instructions to the system.
b) the part of a television or computer on which a picture is formed or information is displayed.
c) rigid disk coated with magnetic material, for storing computer programs and relatively large amounts of data.
d) an electronic device that makes possible he transmission of data to or from computer via telephone or other communication lines.
e) a set of keys, usually arranged in tiers, for operating a typewriter, typesetting machine, computer terminal, or the like.
f) volatile computer memory, used for creating, loading, and running programs and for manipulating and temporarily storing data; main memory.
g) central processing unit: the key component of a computer system, containing the circuitry necessary to interpret and execute program instructions.
h) a palm-sized device equipped with one or more buttons, used to point at and select items on a computer display screen and for controlling the cursor by means of analogous movement on a nearby surface.
i) a thin, usually flexible plastic disk coated with magnetic material, for storing computer data and program.
Questions for group discussion:
1) Without what parts computer is unable to work?
2) What is the most expensive part of the hardware?
3) What other hardware devices do you know? What are they for? Do you know how to use them?
Text C: "TYPES OF SOFTWARE»
A computer to complete a job requires more than just the actual equipment or hardware we see and touch. It requires Software - programs for directing the operation of a computer or electronic data.
Software is the final computer system component. These computer programs instruct the hardware how to conduct processing. The computer is merely a general-purpose machine which requires specific software to perform a given task. Computers can input, calculate, compare, and output data as information. Software determines the order in which these operations are performed.
Programs usually fall in one of two categories: system software and applications software.
System software controls standard internal computer activities. An operating system, for example, is a collection of system programs that aid in the operation of a computer regardless of the application software being used. When a computer is first turned on, one of the systems programs is booted or loaded into the computers memory. This software contains information about memory capacity, the model of the processor, the disk drives to be used, and more. Once the system software is loaded, the applications software can be brought in.
System programs are designed for the specific pieces of hardware. These programs are called drivers and coordinate peripheral hardware and computer activities. User needs to install a specific driver in order to activate a peripheral device. For example, if you intend to buy a printer or a scanner you need to worry in advance about the driver program which, though, commonly goes along with your device. By installing the driver you «teach» your mainboard to «understand» the newly attached part.
Applications software satisfies your specific need. The developers of application software rely mostly on marketing research strategies trying to do their best to attract more users (buyers) to their software. As the productivity of the hardware has increased greatly in recent years, the programmers nowadays tend to include as much as possible in one program to make software interface look more attractive to the user. These class of programs is the most numerous and perspective from the
marketing point of view.
Data communication within and between computers systems is handled by system software. Communications software transfers data from one computer system to another. These programs usually provide users with data security and error checking along with physically transferring data between the two computer's memories. During the past five years the developing electronic network communication has stimulated more and more companies to produce various communication software, such as Web-Browsers for Internet.
Vocabulary:
aid - допомога
to attach - приєднувати
control - управління
developer - розробник
equipment - обладнання
general-purpose - загального призначення
internal - внутрішній
mainboard - материнська плата
memory capacity - місткість пам'яті
peripheral - периферійний
regard - відношення
regardless - незважаючи на, безвідносно,
security - безпека
specific - конкретний, визначений
to boot - завантажувати
to check - перевіряти
to complete - здійснювати, завершувати
to conduct - проводити
to develop - розвивати, проявляти
to direct - управляти, керувати
to handle - керувати, звертатися з
to install - встановлювати, вбудовувати, інсталювати
to provide with - забезпечувати чим-небудь
to require - вимагати
to secure - забезпечувати безпеку
to transfer - перекладати, переносити
Web-browser - «браузер» (програма, що дозволяє користувачеві шукати і зчитувати інформацію з глобальної електронної мережі Internet)
General understanding
1. What is software?
2. In what two basic groups software (programs) could be divided?
3. What is system software for?
4. What is an operating system - a system software or application software?
5. What is a «driver»?
6. What is application software?
7. What is application software used for?
8. What is the tendency in application software market in the recent years?
9. What is the application of the communication software?
Exercise 8.10. Which of the following is Software:
1. Program
2. Mouse
3. CPU
4. Word processor
5. Modem
6. Web-browser
7. Operating system
8. Scanner
9. Printer
10. Display
Exercise 8.11. Which of the listed below statements are true / false. Specify your answer using the text:
1) Computer programs only instruct hardware how to handle data storage.
2) System software controls internal computer activities.
3) System software is very dependable on the type of application software being used.
4) The information about memory capacity, the model of the processor and disk drives are unavailable for system software.
5) The driver is a special device usually used by car drivers for Floppy-disk driving.
6) It is very reasonable to ask for a driver when you buy a new piece of hardware.
7) Software developers tend to make their products very small and with poor interface to save computer resources.
8) Communication software is in great demand now because of the new advances in communication technologies.
9) Application software is merely a general-purpose instrument.
10) Web-browsers is the class of software for electronic communication through the network.
Exercise 8.12. Find English equivalents in the text:
1) Програмне забезпечення визначає порядок виконання операцій.
2) Прикладні програми виконують поставлену вами конкретну задачу (задовольняють вашу потреба).
3) Цей клас програм - найчисленніший і перспективний з точки зору маркетингу.
4) Системні програми призначені для конкретних пристроїв комп'ютерної системи.
5) Встановлюючи драйвер, ви <вчіть »систему« розуміти »знову приєднане пристрій.
6) Коли комп'ютер вперше включається, одна з системних програм повинна бути завантажена в його пам'ять.
7) Розвиток систем електронної комунікації за останні п'ять років стимулювало виробництво відповідних програмних продуктів зростаючим числом компаній-розробників.
Exercise 8.13. Give definitions to the following using the vocabulary:
1) Software
2) Driver
3) Application software
4) Operating system
5) Communication software
6) Computer
7) Peripheral device
8) Operating system
Questions for group discussion:
1) What do you think is more expensive - hardware or software?
2) Has anyone in your group ever purchased software? Why do you think piracy (audio, video, computer software) still exists?
FAMOUS PEOPLE OF SCIENCE AND ENGINEERING
Babbage, Charles (1792-1871), British mathematician and inventor, who designed and built mechanical computing machines on principles that anticipated the modern electronic computer. Babbage was born in Teignmouth, Devon, and educated at the University of Cambridge. He became a Fellow of the Royal Society in 1816 and was active in the founding of the Analytical, the Royal Astronomical, and the Statistical Societies.
In the 1820s Babbage began developing his Difference Engine, a mechanical device that could perform simple mathematical calculations. Although Babbage started to build his machine, he was unable to complete it because of a lack of funding. In the 1830s Babbage began developing his Analytical Engine, which was designed to carry out more complicated calculations, but this device was never built, too. Babbage's book, «Economy of Machines and Manufactures» (1832), initiated the field of study known today as operational research.
UNIT 9
MODERN COMPUTER TECHNOLOGIES
I. Text A: «Operating systems», Text B: «Windows 95»,
Text C: «Internet and WWW»
II. Famous people of science and engineering: Bill Gates.
Text A: «OPERATING SYSTEMS»
When computers were first introduced in the 1940's and 50's, every program written had to provide instructions that told the computer how to use devices such as the printer, how to store information on a disk, as well as how to perform several other tasks not necessarily related to the program. The additional program instructions for working with hardware devices were very complex, and time-consuming. Programmers soon realized it would be smarter to develop one program that could control the computer's hardware, which others programs could have used when they needed it. With that, the first operating system was born.
Today, operating systems control and manage the use of hardware devices such as the printer or mouse. They also provide disk management by letting you store information in files. The operating system also lets you run programs such as the basic word processor. Lastly, the operating system provides several of its own commands that help you to use the computer.
DOS is the most commonly used PC operating system. DOS is an abbreviation for disk operating system. DOS was developed by a company named Microsoft. MS-DOS is an abbreviation for «Microsoft DOS». When IBM first released the IBM PC in 1981, IBM licensed DOS from Microsoft for use on the PC and called it PC-DOS. From the users perspective, PC-DOS and MS-DOS are the same, each providing the same capabilities and commands.
The version of DOS release in 1981 was 1.0. Over the past decade, DOS has undergone several changes. Each time the DOS developers release a new version, they increase the version number.
Windows NT (new technology) is an operating system developed by Microsoft. NT is an enhanced version of the popular Microsoft Windows 3.0, 3.1 programs. NT requires a 386 processor or greater and 8 Mb of RAM. For the best NT performance, you have to use a 486 processor with about 16 Mb or higher. Unlike the Windows, which runs on top of DOS, Windows NT is an operating system itself. However, NT is DOS compatible. The advantage of using NT over Windows is that NT makes better use of the PC's memory management capabilities.
OS / 2 is a PC operating system created by IBM. Like NT, OS / 2 is DOS compatible and provides a graphical user interface that lets you run programs with a click of a mouse. Also like NT, OS / 2 performs best when you are using a powerful system. Many IBM-based PCs are shipped with OS / 2 preinstalled.
UNIX is a multi-user operating system that allows multiple users to access the system. Traditionally, UNIX was run on a larger mini computers to which users accessed the systems using terminals and not PC's. UNIX allowed each user to simultaneously run the programs they desired. Unlike NT and OS / 2, UNIX is not DOS compatible. Most users would not purchase UNIX for their own use.
Windows 95 & 98 (Windows 2000) are the most popular user-oriented operating systems with a friendly interface and multitasking capabilities. The usage of Windows 95 and its enhanced version Windows 98 is so simple that even little kids learn how to use it very quickly. Windows 95 and 98 are DOS compatible, so all programs written for DOS may work under the new operating system.
Windows 95 requires 486 processor with 16 megabytes of RAM or Pentium 75-90 with 40 megabytes of free hard disk space.
Vocabulary:
complex - складний
to consume - споживати
consumer - споживач
to realize - зрозуміти, усвідомити
smart - розумний
decade - декада, десятиліття
version - версія
to enhance - збільшувати, розширювати
top - верх, вершина
on top of DOS - «зверху», на основі ДОС
are shipped - поставляються
compatible - сумісний
with a click of a mouse - одним клацанням кнопки миші
access - доступ
to allow - дозволяти
multiple users - численні користувачі
simultaneously - одночасно
to desire - бажати
to ship - постачати, доставляти
General understanding:
1) What problems faced programmers in the 1940's and 1950's?
2) Why were the first programs «complex» and «time-consuming»?
3) What are the basic functions of operating system?
4) What does the abbreviation DOS mean?
5) What company developed the first version of DOS operating system? For what purpose was it done? Was the new operational system successful?
6) What is the difference between the PC-DOS and MS-DOS
7) What does the abbreviation NT stand for? Is NT DOS-compatible? What are the basic requirements for NT?
8) Who is the developer of OS / 2?
9) What makes UNIX so different from the other operational systems?
10) What are the special features of Windows 95, Windows 98, Windows 2000?
Exercise 9.1. Match the following:
1) Like NT, ... is DOS compatible and provides a graphical user interface that lets you run programmes with a click of a mouse.
2) ... is the most commonly used PC operating system
3) ... is a multi-user operating system that allows multiple users to access the system
4) ... is an operating system developed by Microsoft, an enhanced version of the popular Microsoft Windows programs.
5) The usage of ... is so simple that even little kids learn how to use it very quickly.
a) UNIX
b) DOS
c) NT
d) OS / 2
e) Windows 95
Exercise 9.2. Which of the listed below statements are true / false. Specify your answer using the text.
1) When computers were first introduced in 40's and 50's programmers had to write programs to instruct CD-ROMs, laser printers and scanners.
2) The operational system controls and manages the use of the hardware and the memory.
3) There are no commands available in operating systems, they are only in word processors.
4) Microsoft developed MS-DOS to compete with IBM's PC-DOS.
5) NT requires computers with 486 CPU and 16 M random access memory.
6) OS / 2 is DOS compatible because it was developed by Microsoft.
7) Traditionally, UNIX was run by many users simultaneously.
8) Windows 95 and Windows 98 are DOS compatible and have very «friendly» and convenient interface.
Exercise 9.3. Translate into English:
1) Сучасна операційні системи контролюють використання системного обладнання, наприклад, принтера та миші.
2) З точки зору користувача, операційні системи PC-DOS і MS-DOS ідентичні, з рівними можливостями і набором системних команд.
3) OS / 2 є DOS-сумісної операційної системою, що дозволяє запускати програми за допомогою графічного інтерфейсу користувача.
4) Додаткові програми для роботи з пристроями системного обладнання були дуже складні і поглинали багато часу.
5) Операційна система також дозволяє запускати програми, такі як найпростіший текстовий редактор.
6) DOS - найбільш поширена операційна система для персонального комп'ютера.
Questions for group discussion:
1) Why do you think Bill Gates, President of Microsoft Company is one of the richest people on the Earth?
2) Judging from your experience tell if UNIX is used nowadays? What about OS / 2?
3) Ask the students in your group who have experience working with Windows 95 and Windows 98 about the advantages and disadvantages of these operational systems.
Text B: «WINDOWS 95»
Windows 95 is a new operational system with an easy interface based on the expanding windows principle which uses icons to graphically represent files and their types.
Windows 95 makes the way you and your computer interact easy. Most everyday tasks are now easier to accomplish than ever before. For example, the second mouse button has become a powerful weapon. The old Windows 3.0 Program Manager and File Manager have been replaced. The desktop tools that replace them are very like those found on a Macintosh. For example, there is a Recycle Bin that makes it easier to recover accidentally deleted files.
Your computer probably will crash less running Windows 95 than it did with Windows 3.1 and 3.0 or even DOS. Most memory related problems have been removed. Built-in networking features make it easy to reliably share files with co-workers across the room or across the world. And MS-DOS as we know it is so well hidden that you'll rarely give it a thought. Yes, you can still run DOS programs and older Windows applications but most users will probably want to spend most of their time using Windows 95 applications instead.
Microsoft says that it is moving forward to the time when we'll all think more about our data and less about the specific name-brand programs used to create them.
Window 95 plug-and-play capability makes it easy to upgrade your computer hardware. And portable computer users will like what Microsoft has done to make their lives calmer.
A new Windows shortcuts capability makes it easy to reach frequently used files and other necessities. A new Find feature helps you to locate and examine the contents of files in a flash.
Most of this is accomplished without sacrificing performance. In fact, many things (like printing) usually happen faster now, due to 32-bit support and other Windows 95 advancements.
Vocabulary:
to interact - взаємодіяти
to accomplish - виконувати, досягати
weapon - зброя
to replace - заміщувати
Recycle Bin - кошик
to crash - ламатися, давати збої
to remove - видаляти
co-workers - колеги, товариші по службі
rarely - рідко
to plug - підключати
frequently - часто
support - підтримка
necessity - необхідність
flash - спалах, зд. in a flash - моментально
to give smth. a thought - подумати про що-небудь
brand-name - торгова марка
calm - спокійний
shortcut - найкоротший шлях
to sacrifice - жертвувати
advancement - прогрес, просування
General understanding:
1) What is Windows 95?
2) What new principles are used in Windows 95?
3) What is a Recycle Bin feature?
4) What problems has Windows 95 solved?
5) Is it possible to run old DOS programs under Windows 95?
6) What is a «plug-n-play» capability?
7) What is a «shortcut» capability?
8) What is a «Find» feature?
9) Why many things work faster now with Windows 95?
Exercise 9.4. Which of the listed above statements are true / false. Specify your answer using the text.
An «icon» is graphical image that represents file and its type.
Second button is not used in Windows 95 because most people use 1-button mouse.
3) There are no similarities between Macintosh and Windows 95 desktop tools.
4) Windows 95 has some tools which help to communicate with other people through computer network.
5) It's no longer possible to use MS-DOS commands and run MS-DOS files.
6) Microsoft corporation is oriented to produce as many programs as needed to meet people needs and make them buy specific brand-name products.
7) New plug-n-play capability is for those who like to play computer games 24 hours a day and seven days a week.
8) A new shortcut feature is used to cut long programs very short to save disk space.
9) New Find feature helps you to locate the contents of files.
10) It must be mentioned that all new Windows features are possible only because of the low level of performance and quality.
Exercise 9.5. Find the equivalents in the text:
1) Ваш комп'ютер ймовірно буде давати менше збоїв з Віндоуз 95, ніж з більш ранніми версіями і навіть ДОС.
2) Корпорація Майкрософт заявляє, що вона робить все для того, щоб наблизити час, коли ми всі будемо думати більше про наших даних, ніж про конкретні «фірмових» програмах, які використовуються для створення цих даних.
3) Нова функція пошуку дозволяє виявити місце розташування і досліджувати вміст файлу в одну мить.
4) Більшість цих функцій досягнута на шкоду продуктивності.
5) ДОС, яким ми його знаємо, так добре захований, що ви рідко думаєте про його використання.
6) У Віндоуз 95 існує інструмент Кошик, який дозволяє легко відновлювати випадково видалені файли.
7) Інструменти Робочого Столу дуже схожий з інструментами Макінтоша.
8) Друга кнопка миші стала могутньою зброєю.
Exercise 9.6. What is:
1) window
2) icon
3) recycle bin
4) plug-and-play capability
5) shortcut feature
Exercise 9.7. Practice:
1) Start Windows 95. Empty the Recycle Bin. See the free diskspace on drives A and C. See the catalgue of disk C.
2) Resize, maximize and minimize the window. Close the window. Move it, holding the left button.
3) Create a folder COMPUTER. Copy any 2 filesinto it. Rename the folder. Delete two files into the Recycle Bin then recover them. Delete the whole folder.
4) Create a textual file in WordPad program. Save it as TEXT. Rename it as MYFILE. Create a shortcut for it. Put the shortcut on the DeskTOP.
5) Create a picture in Paintbrush program. Save it as MYPICTURE. Create folder PICTURES. Copy file MYPICTURE to the PICTURES folder.
6) QUIT Windows 95.
Questions for group discussion:
1) What are the poor features of Windows 95?
2) Computer society thinks, that Intel company, the most powerful CPU producer, has an agreement with Microsoft corporation that the latter will develop more and more sophisticated, large and demanding software to force users to buy new processors and upgrade their computers. Do you think this might be true? How does this suggestion correlate with the new Windows 2000 and Microsoft Office 2000? Do you think that Bill Gates 'monopoly on Windows operating systems is very dangerous for the competition and price-making process?
3) Ask anyone in the group who has a computer if Windows 98 is better than Windows 2000? Why and why not?
Text C: «INTRODUCTION TO THE WWW AND THE INTERNET»
Millions of people around the world use the Internet to search for and retrieve information on all sorts of topics in a wide variety of areas including the arts, business, government, humanities, news, politics and recreation. People communicate through electronic mail (e-mail), discussion groups, chat channels and other means of informational exchange. They share information and make commercial and business transactions. All this activity is possible because tens of thousands of networks are connected to the Internet and exchange information in the same basic ways.
The World Wide Web (WWW) is a part of the Internet. But it's not a collection of networks. Rather, it is information that is connected or linked together like a web. You access this information through one interface or tool called a Web browser. The number of resources and services that are part of the World Wide Web is growing extremely fast. In 1996 there were more than 20 million users of the WWW, and more than half the information that is transferred across the Internet is accessed through the WWW. By using a computer terminal (hardware) connected to a network that is a part of the Internet, and by using a program (software) to browse or retrieve information that is a part of the World Wide Web, the people connected to the Internet and World Wide Web through the local providers have access to a variety of information. Each browser provides a graphical interface. You move from place to place, from site to site on the Web by using a mouse to click on a portion of text, icon or region of a map. These items are called hyperlinks or links. Each link you select represents a document, an image, a video clip or an audio file somewhere on the Internet. The user doesn't need to know where it is, the browser follows the link.
All sorts of things are available on the WWW. One can use Internet for recreational purposes. Many TV and radio stations broadcast live on the WWW. Essentially, if something can be put into digital format and stored in a computer, then it's available on the WWW. You can even visit museums, gardens, cities throughout the world, learn foreign languages and meet new friends. And, of course, you can play computer games through WWW, competing with partners from other countries and continents.
Just a little bit of exploring the World Wide Web will show you what a lot of use and fun it is.
Vocabulary:
World Wide Web - «Всесвітня Павутина»
to retrieve - витягати
variety - різноманітність, спектр
recreation - розвага
network - мережа
to share - ділити
humanities - гуманітарні науки
business transactions - комерційні операції
access - доступ
to browse - розглядати, роздивлятися
browser - браузер (програма пошуку інформації)
to provide - забезпечувати (чим-небудь)
provider - провайдер (компанія, що надає доступ до WWW через місцеві телефонні мережі)
broadcast live - передавати в прямому ефірі site - сторінка, сайт
to link - з'єднувати
hyperlink - гіперпосилання
to compete - змагатися
General understanding:
1) What is Internet used for?
2) Why so many activities such as e-mail and business transactions are possible through the Internet?
3) What is World Wide Web?
4) What is Web browser?
5) What does a user need to have an access to the WWW?
6) What are hyperlinks?
7) What resources are available on the WWW?
8) What are the basic recreational applications of WWW?
Exercise 9.8. Which of the listed below statements are true / false. Specify your answer using the text.
1) There are still not so many users of the Internet.
2) There is information on all sorts of topics on the Internet, including education and weather forecasts.
3) People can communicate through e-mail and chat programs only.
4) Internet is tens of thousands of networks which exchange the information in the same basic way.
5) You can access information available on the World Wide Web through the Web browser.
6) You need a computer (hardware) and a special program (software) to be a WWW user.
7) You move from site to site by clicking on a portion of text only.
8) Every time the user wants to move somewhere on the 'eh he / she needs to step by step enter links and addresses.
9) Films and pictures are not available on the Internet.
10) Radio and TV-broadcasting is a future of Internet. They're not available yet.
Exercise 9.9. Define the following using the vocabulary:
1) Internet
2) World Wide Web
3) Web browser
4) Internet provider
5) Hyperlinks
Exercise 9.10. Find the equivalents:
1) Обсяг ресурсів і послуг, які є частиною WWW, зростає надзвичайно швидко.
2) Кожна посилання, обрана вами представляє документ, графічне зображення, відеокліп або аудіо файл де-то в Інтернет.
3) Інтернет може бути також використаний для цілей розваги.
4) Ви отримуєте доступ до ресурсів Інтернет через інтерфейс або інструмент, який називається веб-браузер.
5) Вся ця діяльність можлива завдяки десяткам тисяч комп'ютерних мереж, підключених до Інтернет та обмінюються інформацією в одному режимі.
6) Користувачі спілкуються через електронну пошту, дискусійні групи, чет-канали (багатоканальний розмову в реальному часі) та інші засоби інформаційного обміну.
Exercise 9.11. Match the following:
1) You access the information through one interface or tool called a. ..
2) People connected to the WWW through the local ... have access to a variety of information.
3) The user doesn't need to know where the site is, the ... follows the ...
4) In 1996 there were more than 20 million users of the ...
5) Each ... provides a graphical interface.
6) Local ... charge money for their services to access ... resources.
Words to match with:
1) web browser, providers, link, WWW,
Questions for group discussion:
1) Some people think that Internet is very harmful, especially for young people, because it carries a lot of information about sex, drugs, violence and terrorism. Do you think that some kind of censorship is necessary on the WWW?
2) World famous authors and publishers say that the Internet violates their copyright because Web-programmers put all kinds of books, pictures, music, films and programs free on the Internet and this reduces their sales and profits.
3) Has anyone in your group experience working on the Internet? Ask them 1) about the difficulties they had; 2) useful information retrieved; 3) fun they got? Why so few people have experience working on the Internet?
FAMOUS PEOPLE OF SCIENCE AND ENGINEERING
Bill Gates
William Henry Gates was born in Seattle, Washington, in 1955.
He is an American business executive, chairman and chief executive officer of the Microsoft Corporation. Gates was the founder of Microsoft in 1975 together with Paul Alien, his partner in computer language development. While attending Harvard in 1975, Gates together with Alien developed a version of the BASIC computer programming language for the first personal computer.
In the early 1980s. Gates led Microsoft's evolution from the developer of computer programming languages to a large computer software company. This transition began with the introduction of MS-DOS, the operating system for the new IBM Personal Computer in 1981. Gates also led Microsoft towards the introduction of application software such as the Microsoft Word processor.
Much of Gates 'success is based on his ability to translate technical visions into market strategy. Although Gates has accumulated great wealth from his holdings of Microsoft stock, he has been known as a tough competitor who seems to value winning in a competitive environment over money. Gates still continues to work personally in product development at Microsoft.
1. ALLOYS
Bronze and brass, the first alloys in the history of metallurgy, were probably obtained by man accidentally when melting mixed metal ores. Much later alloys of iron were obtained.
Steel was made in small quantities in early times until the mid-19th century when it was manufactured on a large scale in the iron and steel industry.
The commercial production of pure aluminium in about 1890 began a new range of alloys and among them duralumin, an alloy of about 94 per cent aluminium, with small quantities of copper, manganese, magnesium, and silicon. Most of aluminium alloys are both light and strong.
Nickel is often mixed with other metals for special purposes: permalloy is a nickel-iron alloy that is magnetically soft. The polarity of its magnetic field can be easily changed and it is used for transformer cores. Monel metals contain about two parts nickel to one part copper, plus other elements. They are stronger than nickel and extremely corrosion-resistant. These properties make them useful in chemical production.
Electrum is a natural or artificial alloy of gold and silver containing 15-45 per cent of silver. It was used in the ancient world for coinage.
Bismuth is frequently used as a part of alloys with low melting-points. Today alloys can be designed for particular applications with certain properties.
2. MANUFACTURING OF PLASTICS
The manufacture of plastic and plastic products involves procuring the raw materials, synthesizing the basic polymer, compounding the polymer into a material useful for fabrication, and moulding or shaping the plastic into its final form.
Raw Materials
Originally, most plastics were made from resins derived from vegetable matter, such as cellulose (from cotton), oils (from seeds), starch derivatives, or coal. Casein (from milk) was among the nonvegetable materials used. Although the production of nylon was originally based on coal, air, and water, and nylon 11 is still based on oil from castor beans, most plastics today are derived from petrochemicals. These oil-based raw materials are relatively widely available and inexpensive. However, because the world supply of oil is limited, other sources of raw materials, such as coal gasification, are being explored.
Synthesizing the Polymer
The first stage in manufacturing plastic is polymerization. As noted, the two basic polymerization methods are condensation and addition reactions. These methods may be carried out in various ways. In bulk polymerization, the pure monomer alone is polymerized, generally either in the gaseous or liquid phase, although a few solid-state polymerizations are also used. In solution polymerization, an emulsion is formed and then coagulated. In interfacial polymerization, the monomers are dissolved in two immiscible liquids, and the polymerization occurs at the interface of the two liquids.
Additives
Chemical additives are often used in plastics to produce some desired characteristic. For instance, antioxidants protect a polymer from chemical degradation by oxygen or ozone; similarly, ultraviolet stabilizers protect against weathering. Plasticizers make a polymer more flexible, lubricants reduce problems with friction, and pigments add colour. Among other additives are flame retardants and antistatics.
Many plastics are manufactured as composites. This involves a system where reinforcing material (usually fibres made of glass or carbon) is added to a plastic resin matrix. Composites have strength and stability comparable to that of metals but generally with less weight. Plastic foams, which are composites of plastic and gas, offer bulk with low weight.
Shaping and Finishing
The techniques used for shaping and finishing plastics depend on three factors: time, temperature, and flow (also known as deformation). Many of the processes are cyclic in nature, although some fall into the categories of continuous or semicontinuous operation.
One of the most widely used operations is that of extrusion. An extruder is a device that pumps a plastic through a desired die or shape. Extrusion products, such as pipes, have a regularly shaped cross section. The extruder itself also serves as the means to carry out other operations, such as blow moulding and injection moulding. In extrusion blow moulding, the extruder fills the mould with a tube, which is then cut off and clamped to form a hollow shape called a parison. The hot, molten parison is then blown like a balloon and forced against the walls of the mould to form the desired shape. In injection moulding, one or more extruders are used with reciprocating screws that move forwards to inject the melt and then retract to take on new molten material to continue the process. In injection blow moulding, which is used in making bottles for carbonated drinks, the parison is first injection moulded and then reheated and blown.
In compression moulding, pressure forces the plastic into a given shape. Another process, transfer moulding, is a hybrid of injection and compression moulding: the molten plastic is forced by a ram into a mould. Other finishing processes include calendering, in which plastic sheets are formed, and sheet forming, in which the plastic sheets are formed into a desired shape. Some plastics, particularly those with very high temperature resistance, require special fabrication procedures. For example, polytetrafluoroethene (Teflon) has such a high melt viscosity that it is first pressed into shape and then sintered-exposed to extremely high temperatures that bond it into a cohesive mass without melting it. Some polyamides are produced by a similar process.
Uses
Plastics have an ever-widening range of uses in both the industrial and consumer sectors.
Packaging
The packaging industry is a leading user of plastics. Much LDPE (low-density polyethene) is marketed in rolls of clear-plastic wrap. High-density polyethene (HPDE) is used for some thicker plastic films, such as those used for plastic waste bags and containers. Other packaging plastics include polypropene, polystyrene, polyvinyl chloride (PVC), and polyvinylidene chloride. Polyvinylidene chloride is used primarily for its barrier properties, which can keep gases such as oxygen from passing into or out of a package. Similarly, polypropene is an effective barrier against water vapour. Polypropene is also often used in housewares and as a fibre for carpeting and rope.
Construction
The building industry is a major consumer of plastics, including many of the packaging plastics mentioned above. HDPE is used for pipes, as is PVC. PVC is also used in sheets for building materials and similar items. Many plastics are used to insulate cables and wires, and polystyrene in the form of foam serves as insulation for walls, roofs, and other areas. Other plastic products are roofing, door and window frames, mouldings, and hardware.
Other Uses
Many other industries, especially motor manufacturing, also depend on plastics. Tough engineering plastics are found in vehicle components like fuel lines, fuel pumps, and electronic devices. Plastics are also used for interior panelling, seats, and trim. Many car bodies are made of fibreglass-reinforced plastic.
Among the other uses of plastic are housings for business machines, electronic devices, small appliances, and tools. Consumer goods range from sports equipment to luggage and toys
3. PRINCIPLES AND PROCESS OF POLYMERISATION IN PLASTICS PRODUCTION
Condensation polymerisation and addition polymerisation are the two main processes in plastics production. The manufacture of plastics depends upon the building of chains and networks during polymerisation.
A condensation polymer is formed by a synthesis that involves the gradual reaction of reactive molecules with one another, with the elimination of small molecules such as water. The reaction gradually slows down as polymers are built up.
An addition polymer forms chains by the linking of small identical units without elimination of small molecules.
The most important concept in condensation polymers is that of «functionality», ie, the number of reactive groups in each molecule participating in the chain buildup. Each molecule must have at least two reactive groups, of which hydroxyl (-OH), acidic endings (-COOH), and amine endings (-NH) are the simplest.
Hydroxyl is characteristic of alcohol endings, combining with an acid ending to give an ester, the polymer being known as a polyester. Examples are polyethylene terephthalate obtained by reaction of ethylene glycol containing hydroxyl groups at each end and terephthalic acid containing two acidic groups and polycarbonate resins.
Alcohols are a particular class of oxygen-containing chemical compounds with a structure analogous to ethyl alcohol (C-HOH). Amines are various compounds derived from ammonia by replacement of hydrogen by one or more hydrocarbon radicals (molecular groups that act as a unit). Esters are compounds formed by the reaction between an acid and an alcohol or phenol with the elimination of water.
Bulk addition polymerization of pure monomers is mainly confined to styrene and methyl methacrylate The process is highly exothermic, or heat producing. The dissipation of heat (necessary to maintain chain length) is achieved in the case of styrene by intensive stirring of the viscous, partially polymerized mixture, which is then passed down a tower through zones of increasing temperature. Alternatively, polymerization may be completed in containers that are small enough to avoid an excessive temperature rise as a result of the heat released during polymerization.
Methyl methacrylate is also partially polymerized before being poured into molds consisting of between sheets of plate glass, to produce clear acrylic sheet.
Ethylene is polymerized in tubular reactors about 30 metres long and less than 25 millimetres in diameter at pressures of 600-3,000 to give 10-20 percent conversion to low-density polyethylene. Residual gas is recycled.
Polymerization of monomers in solution allows easy temperature control, but the molecular weight of polymers formed is reduced because of chain transfer reactions
Solvent removal from such a solution may also be very difficult. The process can be applied advantageously to vinyl acetate and acrylic esters.
Suspension polymerization producing beads of plastic is extensively applied to styrene, methyl methacrylate, vinyl chloride, and vinyl acetate. The monomer, in which the initiator or catalyst must be soluble, is maintained in droplet form suspended in water by agitation in the presence of a stabilizer such as gelatin, each droplet of monomer undergoing bulk polymerization.
In emulsion polymerization the monomer is dispersed in water by means of a surface-active agent (a substance slightly soluble in water that reduces the surface tension of a liquid), its bulk aggregating into tiny particles held in suspension. The monomer enters the hydrocarbon part of the surface-active micelles and is polymerized there by a water-soluble catalyst.
This process is particularly useful for the preparation of very high molecular weight polymers.
Exposure of certain substances to X-ray or ultraviolet radiation initiates chain reactions that can be used for manufacture of such thermoplastics as polyethylene and polyvinyl chloride.
4. RESINS
Resins that cannot be softened by heating include the phenolics, furan resins, aminoplastics, alkyds, allyls, epoxy resins, polyurethanes, some polyesters, and silicones.
Phenolics or phenol-aldehydes
The important commercial phenolic resin Bakelite is based on phenol and formaldehyde. The two processes in general use are the one-step process producing resol resins (the first stage in the formation of a phenolic resin) that are either liquid or brittle, soluble, fusible solids, from more than one molecule of formaldehyde per phenol molecule; and the two-step process, using an excess of phenol to produce novolacs, resins that have no reactive methylol groups and must be mixed with an aldehyde to undergo further reaction.
Resol resins thermoset on heating and are used for adhesives. Novolacs require a further source of formaldehyde in the form of hexamethylenetetramine to produce molding powders. Both resins are run out from the reaction vessel, after removal of water by distillation, and ground up, then compounded on heated rolls with fillers that vary from wood flour to mica; for strength and heat resistance fibrous asbestos is used as a filler (hexamethylenetetramine is also added at this stage in the case of the two-step resin). Final grinding produces the molding powders, which on further heat treatment will yield the typical thermoset resin.
Phenolic moldings are resistant to heat, chemicals, and moisture and are preferred for wet-dry applications as in washing machines. Their stability to heat and low heat conductivity suit them for use in appliance parts, and their electrical insulation qualities qualify them for electric fittings such as switches, plugs, and distributor caps; resistance to hydraulic fluids has led to their use in automotive parts. All these applications have been made more economical by the development of injection molding and extrusion methods. Complex phenols are used in manufacture of brake linings.
Furan resins
Furfural is a five-membered ring compound (ie, the basic molecule has a ring shape and contains five atoms) of four carbon atoms and one oxygen atom, carrying the aldehyde group, - CHO; it reacts like formaldehyde with phenols in the presence of an acid catalyst to give a rigid polymer with high chemical resistance, used for coatings in industry. It can be prepared in semiliquid form with a low viscosity and remarkable penetrating power when applied to porous forms such as foundry sand cores or graphite blocks, being in this respect superior to other liquid resins.
Aminoplastics
Urea resins are made by the condensation in aqueous solution of formaldehyde and urea in the presence of ammonia as an alkaline catalyst, giving a colourless solution to which cellulose filler is added to yield a molding powder upon drying, which when heated in a mold gives a water-white (transparent) molding unless previously coloured by pigment.
The filler confers considerable strength, so that thin sections such as in cups and tumblers can be molded. Very large quantities of urea-formaldehyde resin are used in kitchen and bathroom hardware details, and electric appliance housings and fittings.
Melamine behaves in the same way as urea, but the product is more moisture resistant, harder and stronger, leading to wide use for plates and food containers. Melamine moldings are glossy and harder than any other plastic and retain a dust-free surface. Solutions of the thermoplastic forms of urea-formaldehyde resins are widely used as bonding agents for plywood and wood-fibre products.
Alkyds
Alkyds are polyesters, generally of phthalic acid (with two acid groups) and glycerol, a triol - ie, an alcohol with three hydroxyl groups. The solid resins are molded at high speed under low pressure, cured quickly, and are used where insulating properties, strength, and dimensional stability over a wide range of voltage, frequency, temperature, and humidity are required, as in vacuum-tube bases and automotive ignition parts and with glass-fibre reinforcement for switch gear and housings for portable tools.
Polyesters of unsaturated alcohols
The resins known as DAP and DAIP, are crossliked allyl esters of phthalic and isophthalic acid, respectively. They are notable for maintaining rigidity and excellent electrical properties at temperatures up to 230 З, prорerties also manifested by allylic resin-impregnated glass cloth, used in aircraft and missile parts. Other advantages are good storage life and absence of gas evolution during polymerization. The resin allyl diglycol carbonate, optically clear and colourless, is used for making cast objects; fully cured castings are more heat and abrasion resistant than other cast resins.
Epoxy resins
Epoxy resins have outstanding mechanical and electrical properties, dimensional stability, resistance to heat and chemicals, and adhesion to other materials. They are used for casting, encapsulation, protective coatings, and adhesives, and for reinforced moldings and laminates of the highest quality. Popular adhesives (epoxy glues) contain the resin components and the curing agent, usually an amine or an anhydride, in separate packages. The two are mixed just before use.
Polyurethanes
Formed by the reaction between diisocyanates and polyols (multihydroxy compounds), polyurethanes are among the most versatile of plastics, ranging from rigid to elastic forms. Their major use is for foams, with properties varying from good flexibility to high rigidity. Thermoplastic polyurethanes that can be extruded as sheet and film of extreme toughness can also be made.
Polyesters of unsaturated acids
Certain esters can be polymerized to resin and are used on a very large scale in glass-fibre-reinforced plastics.
Unsaturated acid (usually maleic acid in the form of its anhydride) is first polymerized to a relatively short polymer chain by condensation with a dihydric alcohol such as propylene glycol, the chain length being determined by the relative quantities of the two ingredients The resulting condensation polymer is then diluted with a monomer such as styrene and an initiator for addition polymerization added. This mixture is quite stable at room temperature over a long period. Frequently, a silicone compound is added to promote adhesion to glass fibres, and wax to protect the surface from oxygen inhibition of polymerization. Glass-fibre materials are impregnated with the syrup and polymerization is brought about by raising the temperature. Alternatively, the polymerization can be carried out at room temperature by addition of a polymerization accelerator to the syrup immediately before impregnation. After an induction period, which can be controlled, polymerization takes place, with rapid increase in temperature, to give a glass-fibre-reinforced cross-linked polymer, which is effectively a thermoset type of plastic and very resistant to heat. The properties of the resin are frequently varied by replacing part of the unsaturated maleic anhydride by anhydrides of saturated acids.
Silicones
Silicon, unlike carbon, does not form double bonds or long silicon chains. It does, however, form long chains with oxygen such as in siloxanes with hydrocarbon groups attached to the silicon; these result in a wide range of oils, greases, and rubbers.
Produced through a series of reactions involving replacement of certain atoms in the chain, silicon resins, or silicones, can be used for high-and low-pressure lamination, with glass-fibre reinforcement and with mineral or short glass-fibre fillers, or for molding powders. The outstanding characteristic of these products is high dielectric strength (that is, they are good insulators at high voltages) with low dissipation over a wide temperature and humidity range. Silicones are not distorted by heat up to 400 С. They are also physiologically inert and therefore valuable for prostheses (artificial body parts).
5. INDUSTRIAL PLASTICS:
RIGID AND FLEXIBLE FOAMS
Rigid polyurethane foams in sandwich forms have wide applications as building components. They are also the best insulants known today and so have wide application in refrigeration and in buildings, where they are applied in fitted slab form or are foamed into cavities at the building site. They can also be applied by spraying about six millimetres thickness with each pass of the spray gun. The ability to spray a foaming mixture through a single nozzle is a great advantage in application.
A very important use of rigid foam is for furniture parts to reproduce wood structures; these can be injection molded. Polyurethane foam can be screwed and nailed with a retention about equal to white pine lumber.
A major advance in the manufacture of sandwich structures is a new method of injection molding, in which a large machine is used to produce moldings up to 1.2 metres square. Moldings of great strength and any desired surface are obtained.
Flexible foams
Flexible foams, usually polyurethane, are made in slab form up to 2.4 metres in width and as much as 1.5 metres high; these are then cut to required shapes or sizes or are molded. The molded foams may be hot molded.
This involves filling heated aluminum castings and gives a product having high resistance to compression, as for automobile seats; or they may be cold molded, a process used particularly for semi-flexible foams with high load-bearing properties. Used almost exclusively by the automobile industry for crash pads, armrests, and dashboard covers, the process involves machine mixing the ingredients and pouring them into aluminum molds lined with vinyl or acrylo-nitrile-butadiene-styrene skins, which become the cover material for the part.
Polystyrene foams are made in a wide range of densities, from expandable beads, either by extrusion through slot-shaped openings to 40 times the original volume to form boards directly or by foaming in steam chests to form large billets. Using small beads in stainless steel molds, cups can be molded with thin sections.
Thin sheet for packaging can also be made by the tube extrusion technique. Though packaging is a major use for forms made in closed molds, the largest use is for building panels; they can be plastered directly.
Acrylonitrile-butadiene-styrene can be expanded from pellets and is particularly suitable for wood-grain effects and for the production of heavy sections.
Expanded vinyls can be made from plastisols for flooring or textile linings by calendering with a blowing agent and laminating to a fabric base, and by injection molding for insulation and such articles as shoe soles. An improved material is now obtained from cross-linked polyvinyl chloride and competes with polyester in glass reinforced plastic.
6. BASIC PRINCIPLES OF WELDING
A weld can be defined as a coalescence of metals produced by heating to a suitable temperature with or without the application of pressure, and with or without the use of a filler material.
In fusion welding a heat source generates sufficient heat to create and maintain a molten pool of metal of the required size. The heat may be supplied by electricity or by a gas flame. Electric resistance welding can be considered fusion welding because some molten metal is formed.
Solid-phase processes produce welds without melting the base material and without the addition of a filler metal. Pressure is always employed, and generally some heat is provided. Frictional heat is developed in ultrasonic and friction joining, and furnace heating is usually employed in diffusion bonding.
The electric arc used in welding is a high-current, low-voltage discharge generally in the range 10-2,000 amperes at 10-50 volts. An arc column is complex but, broadly speaking, consists of a cathode that emits electrons, a gas plasma for current conduction, and an anode region that becomes comparatively hotter than the cathode due to electron bombardment. Therefore, the electrode, if consumable, is made positive and, if non-consumable, is made negative. A direct current (dc) arc is usually used, but alternating current (ac) arcs can be employed.
Total energy input in all welding processes exceeds that which is required to produce a joint, because not all the heat generated can be effectively utilized. Efficiencies vary from 60 to 90 percent, depending on the process; some special processes deviate widely from this figure. Heat is lost by conduction through the base metal and by radiation to the surroundings.
Most metals, when heated, react with the atmosphere or other nearby metals. These reactions can be extremely detrimental to the properties of a welded joint. Most metals, for example, rapidly oxidise when molten. A layer of oxide can prevent proper bonding of the metal. Molten-metal droplets coated with oxide become entrapped in the weld and make the joint brittle. Some valuable materials added for specific properties react so quickly on exposure to the air that the metal deposited does not have the same composition as it had initially. These problems have led to the use of fluxes and inert atmospheres.
In fusion welding the flux has a protective role in facilitating a controlled reaction of the metal and then preventing oxidation by forming a blanket over the molten material. Fluxes can be active and help in the process or inactive and simply protect the surfaces during joining.
Inert atmospheres play a protective role similar to that of fluxes. In gas-shielded metal-arc and gas-shielded tungsten-arc welding an inert gas-usually argon-flows from an tube surrounding the torch in a continuous stream, displacing the air from around the arc. The gas does not chemically react with the metal but simply protects it from contact with the oxygen in the air.
The metallurgy of metal joining is important to the functional capabilities of the joint. The arc weld illustrates all the basic features of a joint. Three zones result from the passage of a welding arc: (1) the weld metal, or fusion zone, (2) the heat-affected zone, and (3) the unaffected zone. The weld metal is that portion of the joint that has been melted during welding. The heat-affected zone is a region adjacent to the weld metal that has not been welded but has undergone a change in microstructure or mechanical properties due to the heat of welding. The unaffected material is that which was not heated sufficiently to alter its properties.
Weld-metal composition and the conditions under which it freezes (solidifies) significantly affect the ability of the joint to meet service requirements. In arc welding, the weld metal comprises filler material plus the base metal that has melted. After the arc passes, rapid cooling of the weld metal occurs. A one-pass weld has a cast structure with columnar grains extending from the edge of the molten pool to the centre of the weld. In a multipass weld, this cast structure maybe modified, depending on the particular metal that is being welded.
The base metal adjacent to the weld, or the heat-affected zone, is subjected to a range of temperature cycles, and its change in structure is directly related to the peak temperature at any given point, the time of exposure, and the cooling rates . The types of base metal are too numerous to discuss here, but they can be grouped in three classes: (1) materials unaffected by welding heat, (2) materials hardened by structural change, (3) materials hardened by precipitation processes.
Welding produces stresses in materials. These forces are induced by contraction of the weld metal and by expansion and then contraction of the heat-affected zone. The unheated metal imposes a restraint on the above, and as contraction predominates, the weld metal cannot contract freely, and a stress is built up in the joint. This is generally known as residual stress, and for some critical applications must be removed by heat treatment of the whole fabrication. Residual stress is unavoidable in all welded structures, and if it is not controlled bowing or distortion of the weldment will take place.
Arc welding
Shielded metal-arc welding accounts for the largest total volume of welding today. In this process an electric arc is struck between the metallic electrode and the workpiece. Tiny globules of molten metal are transferred from the metal electrode to the weld joint. Arc welding can be done with either alternating or direct current. A holder or clamping device with an insulated handle is used to conduct the welding current to the electrode. A return circuit to the power source is made by means of a clamp to the workpiece.
Gas-shielded arc welding, in which the arc is shielded from the air by an inert gas such as argon or helium, has become increasingly important because it can deposit more material at a higher efficiency and can be readily automated. The tungsten electrode version finds its major applications in highly alloyed sheet materials. Either direct or alternating current is used, and filler metal is added either hot or cold into the arc. Consumable electrode gas-metal arc welding with a carbon dioxide shielding gas is widely used for steel welding. Metal transfer is rapid, and the gas protection ensures a tough weld.
Submerged arc welding is similar to the above except that the gas shield is replaced with a granulated mineral material as a flux.
Weldability of metals
Carbon and low-alloy steels are the most widely used materials in welded construction. Carbon content largely determines the weldability of carbon steels. Low-alloy steels are generally regarded as those having a total alloying content of less than 6 percent. There are many grades of steel available, and their relative weldability varies.
Aluminum and its alloys are also generally weldable. A very thin oxide film on aluminum tends to prevent good metal flow, however, and suitable fluxes are used for gas welding. Fusion welding is more effective with alternating current when using the gas-tungsten arc process to enable the oxide to be removed by the arc action.
Copper and its alloys are weldable, but the high thermal conductivity of copper makes welding difficult. Metals such as zirconium, niobium, molybdenum, tantalum, and tungsten are usually welded by the gas-tungsten arc process. Nickel is the most compatible material for joining, is weldable to itself, and is extensively used in dissimilar metal welding of steels, stainless steels and copper alloys.
7. GEAR
Gear is a toothed wheel or cylinder used to transmit rotary or reciprocating motion from one part of a machine to another. Two or more gears, transmitting motion from one shaft to another, constitute a gear train. At one time various mechanisms were collectively called gearing. Now, however, gearing is used only to describe systems of wheels or cylinders with meshing (постійне зачеплення) teeth. Gearing is chiefly used to transmit rotating motion, but can, with suitably designed gears and flat-toothed sectors, be employed to transform reciprocating motion into rotating motion, and vice versa.
Simple Gears
The simplest gear is the spur (зубчаста) gear, a wheel with teeth cut across its edge parallel to the axis. Spur gears transmit rotating motion between two shafts or other parts with parallel axes. In simple spur gearing, the driven shaft revolves in the opposite direction to the driving shaft. If rotation in the same direction is desired, an idler gear (паразитна) is placed between the driving gear and the driven gear. The idler revolves in the opposite direction to the driving gear and therefore turns the driven gear in the same direction as the driving gear. In any form of gearing the speed of the driven shaft depends on the number of teeth in each gear. A gear with 10 teeth driving a gear with 20 teeth will revolve twice as fast as the gear it is driving, and a 20-tooth gear driving a 10-tooth gear will revolve at half the speed. By using a train of several gears, the ratio of driving to driven speed may be varied within wide limits.
Internal, or annular, gears are variations of the spur gear in which the teeth are cut on the inside of a ring or flanged wheel rather than on the outside. Internal gears usually drive or are driven by a pinion, a small gear with few teeth. A rack, a flat, toothed bar that moves in a straight line, operates like a gear wheel with an infinite radius and can be used to transform the rotation of a pinion to reciprocating motion, or vice versa.
Bevel gears (конічні передачі) are employed to transmit rotation between shafts that do not have parallel axes. These gears have cone-shaped bodies and straight teeth. When the angle between the rotating shafts is 90 °, the bevel gears used are called mitre gears.
Helical Gears
These gears have teeth that are not parallel to the axis of the shaft but are spiraled around the shaft in the form of a helix. Such gears are suitable for heavy loads because the gear teeth come together at an acute angle rather than at 90 ° as in spur gearing. Simple helical gearing has the disadvantage of producing a thrust that tends to move the gears along their respective shafts. This thrust can be avoided by using double helical, or herringbone, gears, which have V-shaped teeth composed of half a right-handed helical tooth and half a left-handed helical tooth. Hypoid gears are helical bevel gears employed when the axes of the two shafts are perpendicular but do not intersect. One of the most common uses of hypoid gearing is to connect the drive shaft and the rear axle in motor cars. Helical gearing used to transmit rotation between shafts that are not parallel is often incorrectly called spiral gearing.
Another variation of helical gearing is provided by the worm gear, also called the screw gear. A worm gear is a long, thin cylinder that has one or more continuous helical teeth that mesh with a helical gear. Worm gears differ from helical gears in that the teeth of the worm slide across the teeth of the driven gear instead of exerting a direct rolling pressure. Worm gears are used chiefly to transmit rotation, with a large reduction in speed, from one shaft to another at a 90 ° angle.
8. BEARINGS
Bearing is a mechanical device for decreasing friction in a machine in which a moving part bears-that is, slides or rolls on another part. Usually in a bearing the support must allow the moving part one type of motion, for example, rotation, while preventing it from moving in any other way, for example, sidewise. The commonest bearings are found at the rigid supports of rotating shafts where friction is the greatest.
Bearings were invented early in history; when the wheel was invented, it was mounted on an axle, and where wheel and axle touched was a bearing. Such early bearings had surfaces of wood or leather lubricated with animal fat.
Modern bearings have been arbitrarily designated as friction bearings and antifriction bearings. The first comprises sleeve or journal bearings; the second, ball and roller bearings. Neither type of bearing is completely frictionless, and both are highly efficient in reducing friction. A large, modern aircraft engine, for example, has more than 100 bearings, including both types; yet the total power consumed in overcoming bearing friction is less than one per cent of the total power output of the engine.
Friction bearings (ковзання) of the sleeve or journal type are simpler than antifriction bearings in construction but more complex in theory and operation. The shaft supported by the bearing is called the journal, and the outer portion, the sleeve. If journal and sleeve are both made of steel, the bearing surfaces, even if well lubricated, may grab or pick up, that is, rip, small pieces of metal from each other. The sleeves of most bearings therefore are lined with brass, bronze, or Babbitt metal. Sleeve bearings are generally pressure-lubricated through a hole in the journal or from the housing that contains the bearing. The sleeve is often grooved to distribute the oil evenly over the bearing surface.
Typical clearance (difference between the diameters of journal and sleeve) is nominally 0.0025 cm for every 2.54 cm of journal diameter. When the journal is rotating, it may be about 0.0000001 cm from the sleeve at the side with the greatest load. The journal is thus supported on an extremely thin film of oil, and the two parts have no actual contact. As the rotational speed increases, other variables remaining constant, the oil film becomes thicker, so that the friction increases in less than direct proportion to the speed. Conversely, at lower speeds the oil film is thinner if other factors are unchanged. At extremely low speeds, however, the film may rupture and the two pieces come into contact. Therefore, friction is high when the machine is started in motion, and the bearing may fail if high stresses are put on it during starting. Ball bearings, on the other hand, have low starting friction.
Jewel bearings are used to mount very little shafts such as those found in fine watches. They are friction-type bearings in which the ends of the shafts are mounted in extremely hard substances. The bearing is lubricated with a microscopic drop of fine oil.
In a ball bearing, a number of balls rotate freely between an inner ring, which is rigidly fixed to a rotating shaft, and an outer ring, which is rigidly fixed to a support. Both balls and rings are made of hardened alloy steel, usually finished to extremely fine tolerances. The balls are generally held in position by a cage or separator that keeps them evenly spaced and prevents them from rubbing against each other. The bearing is lubricated with grease or oil.
A roller bearing is similar to a ball bearing, except that small steel cylinders, or rollers, are substituted for the balls. A needle bearing is a roller bearing in which the rollers are extremely long and thin. An ordinary roller bearing may have 20 rollers - each twice as long as it is wide - whereas a needle bearing may have 100 needles, each 10 times as long as it is wide. Needle bearings are particularly useful when space is limited.
9. CONSTRUCTION OF AN AUTOMOBILE
The primary components of a car are the power plant, the power transmission, the running gear, and the control system. These constitute the chassis, on which the body is mounted.
The power plant includes the engine and its fuel, the carburettor, ignition, lubrication, and cooling systems, and the starter motor.
The Engine
The greatest number of cars use piston engines. The four-cycle piston engine requires four strokes of the piston per cycle. The first downstroke draws in the petrol mixture. The first upstroke compresses it. The second downstroke-the power stroke-following the combustion of the fuel, supplies the power, and the second upstroke evacuates the burned gases. Intake and exhaust valves in the cylinder control the intake of fuel and the release of burned gases. At the end of the power stroke the pressure of the burned gases in the cylinder is 2.8 to 3.5 kg / sq cm. These gases escape with the sudden opening of the exhaust valve. They rush to a silencer (muffler), an enlarged section of piping containing expanding ducts and perforated plates through which the gases expand and are released into the atmosphere.
Greater smoothness of operation of the four-cycle engine were provided by the development of the four-cylinder engine, which supplies power from one or another of the cylinders on each stroke of the cycle. A further increase in power and smoothness is obtained in engines of 6,8,12, and 16 cylinders, which are arranged in either a straight line or two banks assembled in the form of a V.
Carburation
Air is mixed with the vapour of the petrol in the carburettor. To prevent the air and the carburettor from becoming too cold for successful evaporation of the fuel, the air for the carburettor is usually taken from a point close to a heated part of the engine. Modern carburettors are fitted with a so-called float-feed chamber and a mixing or spraying chamber. The first is a small chamber in which a small supply of petrol is maintained at a constant level. The petrol is pumped from the main tank to this chamber, the float rising as the petrol flows in until the desired level is reached, when the inlet closes. The carburettor is equipped with such devices as accelerating pumps and economizer valves, which automatically control the mixture ratio for efficient operation under varying conditions. Level-road driving at constant speed requires a lower ratio of petrol to air than that needed for climbing hills, for acceleration, or for starting the engine in cold weather. When a mixture extremely rich in petrol is necessary, a valve known as the choke cuts down the air intake, permitting large quantities of unvaporized fuel to enter the cylinder.
Ignition
The mixture of air and petrol vapour delivered to the cylinder from the carburettor is compressed by the first upstroke of the piston. This heats the gas, and the higher temperature and pressure facilitate ignition and quick combustion. The next operation is that of igniting the charge by a spark plug. One electrode is insulated by porcelain or mica; the other is grounded through the metal of the plug, and both form part of the secondary circuit of an induction system.
The principal type of ignition now commonly used is the battery-and-coil system. The current from the battery flows through the coil and magnetizes the iron core. When this circuit is interrupted at the distributor points by the interrupter cam, a current is produced in the primary coil with the assistance of the condenser. This induces a high-voltage current in the secondary winding. This secondary high voltage is needed to cause the spark to jump the gap in the spark plug. The spark is directed to the proper cylinder by the distributor, which connects the secondary coil to the spark plugs in the several cylinders in their proper firing sequence. The interrupter cam and distributor are driven from the same shaft, the number of breaking points on the interrupter cam being the same as the number of cylinders.
The electrical equipment controls the starting of the engine, its ignition system, and the lighting of the car. It consists of the battery, a generator for charging it when the engine is running, a starter and the necessary wiring. Electricity also operates various automatic devices and accessories, including windscreen wipers, directional signals, heating and air conditioning, cigarette lighters, powered windows and audio equipment.
Lubrication
In the force-feed system, a pump forces the oil to the main crankshaft bearings and then through drilled holes in the crankpins. In the full-force system, oil is also forced to the connecting rod and then out to the walls of the cylinder at the piston pin.
Cooling
At the moment of explosion, the temperature within the cylinder is much higher than the melting point of cast iron. Since the explosions take place as often as 2,000 times per minute in each cylinder, the cylinder would soon become so hot that the piston, through expansion, would «freeze» in the cylinder. The cylinders are therefore provided with jackets, through which water is rapidly circulated by a small pump driven by a gear on the crankshaft or camshaft. During cold weather, the water is generally mixed with a suitable antifreeze, such as alcohol, wood alcohol, or ethylene glycol.
To keep the water from boiling away, a radiator forms part of the engine-cooling system. Radiators vary in shape and style. They all have the same function, however, of allowing the water to pass through tubing with a large area, the outer surface of which can be cooled by the atmosphere. In air cooling of engine cylinders, various means are used to give the heat an outlet and carry it off by a forced draught of air.
The Starter
The petrol engine must usually be set in motion before an explosion can take place and power can be developed; moreover, it cannot develop much power at low speeds. These difficulties have been overcome by the use of gears and clutches, which permit the engine to work at a speed higher than that of the wheels, and to work when the vehicle is at rest. An electric starter receiving its current from the storage battery, turns the crankshaft, thus starting the petrol engine. The starter motor is of a special type that operates under a heavy overload, producing high power for very short periods. In modern cars, the starter motor is automatically actuated when the ignition switch is turned on.
The Power Transmission
The engine power is delivered first to the flywheel and then to the clutch. From the clutch, which is the means of coupling the engine with the power-transmission units, the power flows through the transmission and is delivered into the rear-axle drive gears, or differential, by means of the drive shaft and universal joints. The differential delivers the power to each of the rear wheels through the rear-axle drive shafts.
The Clutch
Some type of clutch is found in every car. The clutch may be operated by means of a foot pedal, or it may be automatic or semi-automatic. The friction clutch and the fluid coupling are the two basic varieties. The friction clutch, which depends on solid contact between engine and transmission, consists of: the rear face of the flywheel; the driving plate, mounted to rotate with the flywheel; and the driven plate, between the other two. When the clutch is engaged, the driving plate presses the driven plate against the rear face of the flywheel. Engine power is then delivered through the contacting surfaces to the transmission.
Fluid coupling may be used either with or without the friction clutch. When it is the sole means of engaging the engine to the transmission, power is delivered exclusively through an oil medium without any contact of solid parts. In this type, known as a fluid drive, an engine-driven, fan-bladed disc, known as the fluid flywheel, agitates the oil with sufficient force to rotate a second disc that is connected to the transmission. As the rotation of the second disc directly depends on the amount of engine power delivered, the prime result of fluid coupling is an automatic clutch action, which greatly simplifies the requirements for gear shifting.
Manual and Automatic Transmissions
The transmission is a mechanism that changes speed and power ratios between the engine and the driving wheels. Three general types of transmission are in current use: conventional or sliding-gear, Hydra-Matic, and torque-converter systems.
The conventional transmission provides for three or four forward speeds and one reverse speed. It consists of two shafts, each with gears of varying diameters. One shaft drives the other at a preselected speed by meshing the appropriate set of gears. For reverse speed / an extra gear, known as the idler gear, is required to turn the driven shaft in the opposite direction from normal rotation. In high gear, the two shafts usually turn at the same speed. In low, second, and reverse gears, the driven shaft turns more slowly than the driving shaft. When a pair of gears permits the driven shaft to turn more rapidly than the driving shaft, the transmission is said to have overdrive. Overdrive is designed to increase the speed of a car.
The Hydra-Matic type of transmission combines the automatic clutch provided by fluid coupling with a semiautomatic transmission. A mechanical governor, controlled by the pressure exerted on the accelerator pedal, regulates gear selection through a system of hydraulically controlled shift valves. Hydra-Matic transmission provides for several forward gears.
The torque-converter type of transmission provides an unlimited number of gear ratios with no shifting of gears. The torque converter is a hydraulic mechanism using engine power to drive a pump, which impels streams of oil against the blades of a turbine. The turbine is connected to the drive shaft and causes it to rotate.
Both Hydra-Matic and torque-converter systems are controlled by a selector lever on the steering column, which provides also for reverse and sometimes for emergency-low gears.
The Running Gear
The running gear of the car includes the wheel-suspension system, the stabilizers, and the wheels and tyres. The frame of the car may be considered the integrating member of the running gear. It is attached to the rear axle and to the front wheels by springs. These springs, along with the axles, the control and support arms, and the shock absorbers, constitute the wheel-suspension system. In modern cars the front wheels are independently suspended from the frame in a manner that permits either wheel to change its plane without appreciably affecting the other. This type of front-wheel suspension is known popularly as independent suspension. The stabilizers consist of spring-steel bars, connected between the shock-absorber arms by levers, to decrease body roll and improve steerability.
The Control System
Steering is controlled by a hand wheel, mounted on an inclined column and attached to a steering tube inside the column. The other end of the tube is connected to the steering gear, which is designed to provide maximum ease of operation. Power steering, adapted for passenger cars in the early 1950s, is generally a hydraulic mechanism used as a booster to reduce the effort of steering.
A car has two sets of brakes: the hand or emergency brake and the foot brake. The emergency brake generally operates on the rear wheels only. The foot brake in modern cars is always of the four-wheel type, operating on all wheels. Hydraulic brakes on cars and hydraulic vacuum, air, or power brakes on lorries apply the braking force to the wheels with much less force on the brake pedal than is required with ordinary mechanical brakes. The wheel brakes are generally of the internally expanding type, in which a convex strip of material is forced against a concave steel brake drum.
10. TWO-STROKE AND DIESEL ENGINES
Most diesels are also four-stroke engines. The first or suction stroke draws air, but no fuel, into the combustion chamber through an intake valve. On the second or compression stroke the air is compressed to a small fraction of its former volume and is heated to approximately 440 ° C by this compression. At the end of the compression stroke vaporised fuel is injected into the combustion chamber and burns instantly because of the high temperature of the air in the chamber. Some diesels have auxiliary electrical ignition systems to ignite the fuel when the engine starts and until it warms up. This combustion drives the piston back on the third or power stroke of the cycle. The fourth stroke is an exhaust stroke.
The efficiency of the diesel engine is greater than that of any petrol engine and in actual engines today is slightly over 40 per cent. Diesels are in general slow-speed engines with crankshaft speeds of 100 to 750 revolutions per minute (rpm) as compared to 2,500 to 5,000 rpm for typical petrol engines. Some types of diesel, however, have speeds up to 2,000 rpm. Because diesels use compression ratios of 14 or more, they are generally more heavily built than petrol engines, but this disadvantage is counterbalanced by their greater efficiency and the fact that they can be operated on less expensive fuel.
Two-Stroke Engines
By suitable design it is possible to operate a diesel as a two-stroke or two-cycle engine with a power stroke every other stroke of the piston instead of once every four strokes. The efficiency of such engines is less than that of four-stroke engines, and therefore the power of a two-stroke engine is always less then half that of a four-stroke engine of comparable size.
The general principle of the two-stroke engine is to shorten the periods in which fuel is introduced to the combustion chamber and in which the spent gases are exhausted to a small fraction of the duration of a stroke instead of allowing each of these operations to occupy a full stroke.
In the simplest type of two-stroke engine, the valves are the openings in the cylinder wall that are uncovered by the piston at the end of its outward travel. In the two-stroke cycle the fuel mixture or air is introduced through the intake port when the piston is fully withdrawn from the cylinder. The compression stroke follows and the charge is ignited when the piston reaches the end of this stroke. The piston then moves outward on the power stroke, uncovering the exhaust port and permitting the gases to escape from the combustion chamber.
11. DIRECT-CURRENT (DC) GENERATORS
If an armature revolves between two stationary field poles, the current in the armature moves in one direction during half of each revolution and in the other direction during the other half. To produce a steady flow of unidirectional, or direct, current from such a device, it is necessary to provide a means of reversing the current flow outside the generator once during each revolution. In older machines this reversal is accomplished by means of a commutator (колектор) - a split metal ring mounted on the shaft of the armature. The two halves of the ring are insulated from each other and serve as the terminals of the armature coil. Fixed brushes of metal or carbon are held against the commutator as it revolves, connecting the coil electrically to external wires. As the armature turns, each brush is in contact alternately with the halves of the commutator, changing position at the moment when the current in the armature coil reverses its direction. Thus there is a flow of unidirectional current in the outside circuit to which the generator is connected. DC generators are usually operated at fairly low voltages to avoid the sparking between brushes and commutator that occurs at high voltage. The highest potential commonly developed by such generators is 1500 V. In some newer machines this reversal is accomplished using power electronic devices, for example, diode rectifiers.
Modern DC generators use drum armatures that usually consist of a large number of windings set in longitudinal slits in the armature core and connected to appropriate segments of a multiple commutator. In an armature having only one loop of wire, the current produced will rise and fall depending on the part of the magnetic field through which the loop is moving. A commutator of many segments used with a drum armature always connects the external circuit to one loop of wire moving through the high-intensity area of the field, and as a result the current delivered by the armature windings is virtually constant. Fields of modern generators are usually equipped with four or more electromagnetic poles to increase the size and strength of the magnetic field. Sometimes smaller interpoles are added to compensate for distortions in the magnetic flux of the field caused by the magnetic effect of the armature.
DC generators are commonly classified according to the method used to provide field current for energizing the field magnets. A series-wound generator has its field in series with the armature, and a shunt-wound generator has the field connected in parallel with the armature. Compound-wound generators have part of their fields in series and part in parallel. Both shunt-wound and compound-wound generators have the advantage of delivering comparatively constant voltage under varying electrical loads. The series-wound generator is used principally to supply a constant current at variable voltage. A magneto is a small DC generator with a permanent-magnet field
12. AC MOTORS
Two basic types of motors are designed to operate on alternating current: synchronous motors and induction motors. The synchronous motor is essentially a three-phase alternator operated in reverse. The field magnets are mounted on the rotor and are excited by direct current, and the armature winding is divided into three parts and fed with three-phase alternating current. The variation of the three waves of current in the armature causes a varying magnetic reaction with the poles of the field magnets, and makes the field rotate at a constant speed that is determined by the frequency of the current in the AC power line.
The constant speed of a synchronous motor is advantageous in certain devices. However, in applications where the mechanical load on the motor becomes very great, synchronous motors cannot be used, because if the motor slows down under load it will «fall out of step» with the frequency of the current and come to a stop. Synchronous motors can be made to operate from a single-phase power source by the inclusion of suitable circuit elements that cause a rotating magnetic field.
The simplest of all electric motors is the squirrel-cage type of induction motor used with a three-phase supply. The armature of the squirrel-cage motor consists of three fixed coils similar to the armature of the synchronous motor. The rotating member consists of a core in which are imbedded a series of heavy conductors arranged in a circle around the shaft and parallel to it. With the core removed, the rotor conductors resemble in form the cylindrical cages once used to exercise pet squirrels. The three-phase current flowing in the stationary armature windings generates a rotating magnetic field, and this field induces a current in the conductors of the cage. The magnetic reaction between the rotating field and the current-carrying conductors of the rotor makes the rotor turn. If the rotor is revolving at exactly the same speed as the magnetic field no currents will be induced in it, and hence the rotor should not turn at a synchronous speed. In operation the speeds of rotation of the rotor and the field differ by about 2 to 5 per cent. This speed difference is known as slip.
Motors with squirrel-cage rotors can be used on single-phase alternating current by means of various arrangements of inductance and capacitance that alter the characteristics of the single-phase voltage and make it resemble a two-phase voltage. Such motors are called split-phase motors or condenser motors (or capacitor motors), depending on the arrangement used. Single-phase squirrel-cage motors do not have a large starting torque, and for applications where such torque is required, repulsion-induction motors are used. A repulsion-induction motor may be of the split-phase or condenser type, but has a manual or automatic switch that allows current to flow between brushes on the commutator when the motor is starting, and short-circuits all commutator segments after the motor reaches a critical speed. Repulsion-induction motors are so named because their starting torque depends on the repulsion between the rotor and the stator, and their torque while running depends on induction. Series-wound motors with commutators, which will operate on direct or alternating current, are called universal motors. They are usually made only in small sizes and are commonly used in household appliances.
13. ENGINEERING AS A PROFESSION
Electrical and Electronics Engineering
Electrical and electronics engineering is the largest and most diverse field of engineering. It is concerned with the development and design, application, and manufacture of systems and devices that use electric power and signals. Among the most important subjects in the field are electric power and machinery, electronic circuits, control systems, computer design, superconductors, solid-state electronics, medical imaging systems, robotics, lasers, radar, consumer electronics, and fibre optics.
Despite its diversity, electrical engineering can be divided into four main branches: electric power and machinery, electronics, communications and control, and computers.
Electric Power and Machinery
The field of electric power is concerned with the design and operation of systems for generating, transmitting, and distributing electric power Engineers in this field have brought about several important developments since the late 1970s. One of these is the ability to transmit power at extremely high voltages in both the direct current (DC) and alternating current (AC) modes, reducing power losses proportionately. Another is the real time control of power generation, transmission, and distribution, using computers to analyze the data fed back from the power system to a central station and thereby optimizing the efficiency of the system while it is in operation.
A significant advance in the engineering of electric machinery has been the introduction of electronic controls that enable AC motors to run at variable speeds by adjusting the frequency of the current fed into them. DC motors have also been made to run more efficiently this way.
Electronics
Electronic engineering deals with the research, design, integration, and application of circuits and devices used in the transmission and processing of information. Information is now generated, transmitted, received, and stored electronically on a scale unprecedented in history, and there is every indication that the explosive rate of growth in this field will continue unabated.
Electronic engineers design circuits to perform specific tasks, such as amplifying electronic signals, adding binary numbers, and demodulating radio signals to recover the information they carry. Circuits are also used to generate waveforms useful for synchronization and timing, as in television, and for correcting errors in digital information, as in telecommunications.
Prior to the 1960s, circuits consisted of separate electronic devices - resistors, capacitors, inductors, and vacuum tubes - assembled on a chassis and connected by wires to form a bulky package. The electronics revolution of the 1970s and 1980s set the trend towards integrating electronic devices on a single tiny chip of silicon or some other semiconductive material. The complex task of manufacturing these chips uses the most advanced technology, including computers, electron-beam lithography, micro-manipulators, ion-beam implantation, and ultraclean environments. Much of the research in electronics is directed towards creating even smaller chips, faster switching of components, and three-dimensional integrated circuits.
Communications and Control
Engineers work on control systems ranging from the everyday, passenger-actuated, such as those that run a lift, to the exotic, such as systems for keeping spacecraft on course. Control systems are used extensively in aircraft and ships, in military fire-control systems, in power transmission and distribution, in automated manufacturing, and in robotics.
Computers
Computer engineering is now the most rapidly growing field. The electronics of computers involve engineers in design and manufacture of memory systems, of central processing units, and of peripheral devices. The field of computer science is closely related to computer engineering; however, the task of making computers more «intelligent» (artificial intelligence), through creation of sophisticated programs or development of higher level machine languages or other means, is generally regarded as the aim of computer science.
One current trend in computer engineering is microminiaturization. Engineers try to place greater and greater numbers of circuit elements onto smaller and smaller chips. Another trend is towards increasing the speed of computer operations through the use of parallel processors and superconducting materials.
Mechanical Engineering
Engineers in this field design, test, build, and operate machinery of all types; they also work on a variety of manufactured goods and certain kinds of structures. The field is divided into (1) machinery, mechanisms, materials, hydraulics, and pneumatics; and (2) heat as applied to engines, work and energy, heating, ventilating, and air conditioning. The mechanical engineer, therefore, must be trained in mechanics, hydraulics, and thermodynamics and must know such subjects as metallurgy and machine design. Some mechanical engineers specialise in particular types of machines such as pumps or steam turbines. A mechanical engineer designs not only the machines that make products but the products themselves, and must design for both economy and efficiency. A typical example of modern mechanical engineering is the design of a car or an agricultural machine.
Safety Engineering
This field of engineering has as its object the prevention of accidents. In recent years safety engineering has become a specialty adopted by individuals trained in other branches of engineering. Safety engineers develop methods and procedures to safeguard workers in hazardous occupations. They also assist in designing machinery, factories, ships and roads, suggesting alterations and improvements to reduce the possibility of accident.
In the design of machinery, for example, the safety engineer try to cover all moving parts or keep them from accidental contact with the operator, to put cutoff switches within reach of the operator and to eliminate dangerous sharp parts. In designing roads the safety engineer seeks to avoid such hazards as sharp turns and blind intersections that lead to traffic accidents
14. AUTOMATION IN INDUSTRY. FIXED AND PROGRAMMABLE AUTOMATION
Automated production lines
An automated production line consists of a series of workstations connected by a transfer system to move parts between the stations. This is an example of fixed automation, since these lines are set up for long production runs, making large number of product units and running for several years between changeovers. Each station is designed to perform a specific processing operation, so that the part or product is constructed stepwise as it progresses along the line. A raw work part enters at one end of the line, proceeds through each workstation and appears at the other end as a completed product. In the normal operation of the line, there is a work part being processed at each station, so that many parts are being processed simultaneously and a finished part is produced with each cycle of the line. The various operations, part transfers, and other activities taking place on an automated transfer line must all be sequenced and coordinated properly for the line to operate efficiently.
Modern automated lines are controlled by programmable logic controllers, which are special computers that can perform timing and sequencing functions required to operate such equipment. Automated production lines are utilized in many industries, mostly automobile, where they are used for processes such as machining and pressworking.
Machining is a manufacturing process in which metal is removed by a cutting or shaping tool, so that the remaining work part is the desired shape. Machinery and motor components are usually made by this process. In many cases, multiple operations are required to completely shape the part. If the part is mass-produced, an automated transfer line is often the most economical method of production. Many separate operations are divided among the workstations.
Pressworking operations involve the cutting and forming of parts from sheet metal. Examples of such parts include automobile body panels, outer shells of laundry machines and metal furniture More than one processing step is often required to complete a complicated part. Several presses are connected together in sequence by handling mechanisms that transfer the partially completed parts from one press to the next, thus creating an automated pressworking line.
Numerical control
Numerical control is a form of programmable automation in which a machine is controlled by numbers (and other symbols) that have been coded on punched paper tape or an alternative storage medium. The initial application of numerical control was in the machine tool industry, to control the position of a cutting tool relative to the work part being machined. The NC part program represents the set of machining instructions for the particular part. The coded numbers in the program specify xyz coordinates in a Cartesian axis system, defining the various positions of the cutting tool in relation to the work part. By sequencing these positions in the program, the machine tool is directed to accomplish the machining of the part. A position feedback control system is used in most NC machines to verify that the coded instructions have been correctly performed. Today a small computer is used as the controller in an NC machine tool. Since this form of numerical control is implemented by computer, it is called computer numerical control, or CNC. Another variation in the implementation of numerical control involves sending part programs over telecommunications lines from a central computer to individual machine tools in the factory. This form of numerical control is called direct numerical control, or DNC.
Many applications of numerical control have been developed since its initial use to control machine.tools. Other machines using numerical control include component-insertion machines used in electronics assembly, drafting machines that prepare engineering drawings, coordinate measuring machines that perform accurate inspections of parts. In these applications coded numerical data are employed to control the position of a tool or workhead relative to some object. Such machines are used to position electronic components (eg, semiconductor chip modules) onto a printed circuit board (PCB). It is basically an xy positioning table that moves the printed circuit board relative to the part-insertion head, which then places the individual component into position on the board. A typical printed circuit board has dozens of individual components that must be placed on its surface; in many cases, the lead wires of the components must be inserted into small holes in the board, requiring great precision by the insertion machine. The program that controls the machine indicates which components are to be placed on the board and their locations. This information is contained in the product-design database and is typically communicated directly from the computer to the insertion machine.
Automated assembly
Assembly operations have traditionally been performed manually, either at single assembly workstations or on assembly lines with multiple stations. Owing to the high labour content and high cost of manual labour, greater attention has been given in recent years to the use of automation for assembly work. Assembly operations can be automated using production line principles if the quantities are large, the product is small, and the design is simple (eg, mechanical pencils, pens, and cigarette lighters). For products that do not satisfy these conditions, manual assembly is generally required.
Automated assembly machines have been developed that operate in a manner similar to machining transfer lines, with the difference being that assembly operations, instead of machining, are performed at the workstations. A typical assembly machine consists of several stations, each equipped with a supply of components and a mechanism for delivering the components into position for assembly. A workhead at each station performs the actual attachment of the component. Typical workheads include automatic screwdrivers, welding heads and other joining devices. A new component is added to the partially completed product at each workstation, thus building up the product gradually as it proceeds through the line. Assembly machines of this type are considered to be examples of fixed automation, because they are generally configured for a particular product made in high volume. Programmable assembly machines are represented by the component-insertion machines employed in the electronics industry.
15. HISTORY OF ROBOTICS
The concept of robots dates back to ancient times, when some myths told of mechanical beings brought to life. Such automata also appeared in the clockwork figures of medieval churches, and in the 18th century some clockmakers gained fame for the clever mechanical figures that they constructed. Today the term automaton is usually applied to these handcrafted, mechanical (rather than electromechanical) devices that imitate the motions of living creatures. Some of the «robots» used in advertising and entertainment are actually automata, even with the addition of remote radio control.
The term robot itself is derived from the Czech word robota, meaning «compulsory labour». It was first used by the Czech novelist and playwright Karel Chapek, to describe a mechanical device that looks like a human but, lacking human sensibility, can perform only automatic, mechanical operations. Robots as they are known today do not only imitate human or other living forms. True robots did not become possible, however, until the invention of the computer in the 1940s and the miniaturization of computer parts. One of the first true robots was an experimental model designed by researchers at the Stanford Research Institute in the late 1960s. It was capable of arranging blocks into stacks through the use of a television camera as a visual sensor, processing this information in a small computer.
Computers today are equipped with microprocessors that can handle the data being fed to them by various sensors of the surrounding environment. Making use of the principle of feedback, robots can change their operations to some degree in response to changes in that environment. The commercial use of robots is spreading, with the increasing automation of factories, and they have become essential to many laboratory procedures. Japan is the most advanced nation exploring robot technology. Nowadays robots continue to expand their applications. The home-made robots (покоївка) available today may be one sign of the future
16. MEASUREMENTS
Metric System is a decimal system of physical units, named after its unit of length, the metre, the metric system is adopted as the common system of weights and measures by the majority of countries, and by all countries as the system used in scientific work .
Weights and Measures
Length, capacity, and weight can be measured using standard units. The principal early standards of length were the palm or hand breadth, the foot, and the cubit, which is the length from the elbow to the tip of the middle finger. Such standards were not accurate and definite. Unchanging standards of measurement have been adopted only in modern time.
In the English-speaking world, the everyday units of linear measurement were traditionally the inch, foot, yard and mile. In Great Britain, until recently, these units of length were defined in terms of the imperial standard yard, which was the distance between two lines on a bronze bar made in 1845.
In Britain units of weight (ounces, pounds, and tons) are now also derived from the metric standard - kilogram. This is a solid cylinder of platinum-iridium alloy maintained at constant temperature at Sevres, near Paris. Copies, as exact as possible, of this standard are maintained by national standards laboratories in many countries.
International System of Units is a system of measurement units based on the MKS (metre-kilogram-second) system. This international system is commonly referred to as SI.
At the Eleventh General Conference on Weights and Measures, held in Paris in 1960 standards were defined for six base units and two supplementary units:
Length
The metre had its origin in the metric system. By international agreement, the standard metre had been defined as the distance between two fine lines on a bar of platinum-iridium alloy. The 1960 conference redefined the metre as 1,650,763.73 wavelengths of the reddish-orange light emitted by the isotope krypton-86. The metre was again redefined in 1983 as the length of the path travelled by light in a vacuum during a time interval of 1 / 299, 792,458 of a second.
Mass
When the metric system was created, the kilogram was defined as the mass of 1 cubic decimetre of pure water at the temperature of its maximum density or at 4.0 ° C.
Time
For centuries, time has been universally measured in terms of the rotation of the earth. The second, the basic unit of time, was defined as 1 / 86, 400 of a mean solar day or one complete rotation of the earth on its axis in relation to the sun. Scientists discovered, however, that the rotation of the earth was not constant enough to serve as the basis of the time standard. As a result, the second was redefined in 1967 in terms of the resonant frequency of the caesium atom, that is, the frequency at which this atom absorbs energy: 9,192,631,770 Hz (hertz, or cycles per second).
Temperature
The temperature scale is based on a fixed temperature, that of the triple point of water at which it's solid, liquid and gaseous. The freezing point of water was designated as 273.15 К, equaling exactly 0 ° on the Celsius temperature scale. The Celsius scale, which is identical to the centigrade scale, is named after the 18th-century Swedish astronomer Anders Celsius, who first proposed the use of a scale in which the interval between the freezing and boiling points of water is divided into 100 degrees. By international agreement, the term Celsius has officially replaced centigrade.
One feature of SI is that some units are too large for ordinary use and others too small. To compensate, the prefixes developed for the metric system have been borrowed and expanded. These prefixes are used with all three types of units: base, supplementary, and derived. Examples are millimetre (mm), kilometre / hour (km / h), megawatt (MW), and picofarad (pF). Because double prefixes are not used, and because the base unit name kilogram already contains a prefix, prefixes are used not with kilogram but with gram. The prefixes hecto, deka, deci, and centi are used only rarely, and then usually with metre to express areas and volumes. In accordance with established usage, the centimetre is retained for body measurements and clothing.
In cases where their usage is already well established, certain other units are allowed for a limited time, subject to future review. These include the nautical mile, knot, angstrom, standard atmosphere, hectare, and bar.
17. COMPUTERS
Computer is an electronic device that can receive a program (a set of instructions) and then carry out this program by calculating numerical information.
The modern world of high technology is possible mainly due to the development of the computer. Computers have opened up a new era in manufacturing by means of automation, and they have enhanced modern communication systems.
Personal computers
Personal computers are also called microcomputers or home computer. The most compact are called laptops. They are portable and work on built-in batteries.
Personal computers are designed for use at homes, schools, and offices. At home they can be used for home management (balancing the family finances, for example) and for playing computer games, watching films or listening to music. Schoolchildren can use computers for doing their homework and many schools now have computers for independent learning and computer-literacy studies. In the office personal computers may be used for word processing, bookkeeping, storage and handling of necessary information.
Personal computers were made possible by two technical innovations in the field of microelectronics: the integrated circuit, or Iс, which was developed in 1959 and the microprocessor that first appeared in 1971. The IС permitted the miniaturization of computer-memory circuits, and the microprocessor reduced the size of a computer's CPU to the size of a single silicon chip.
Because a CPU calculates, performs logical operations, contains operating instructions, and manages data flows, a complete microcomputer as a separate system was designed and developed in 1974.
In 1981, IBM Company offered its own microcomputer model, the IBM PC that became a necessary tool for almost every business. The PC's use of a 16-bit microprocessor initiated the development of faster and more powerful personal computers, and its use of an operating system that was available to all other computer makers led to a standardisation of the industry.
In the mid-1980s, a number of other developments were especially important for the growth of personal computers. One of these was the introduction of a powerful 32-bit CPU capable of running advanced operating systems at high speeds.
Another innovation was the use of conventional operating systems, such as UNIX, OS / 2 and Windows. The Apple Macintosh computers were the first to allow the user to select icons - graphic symbols of computer functions - from a display screen instead of typing commands. New voice-controlled systems are now available, and users are able to use the words and syntax of spoken language to operate their personal computers.
18. HISTORY AND FUTURE OF THE INTERNET
The Internet technology was created by Vinton Cerf in early 1973 as part of a project headed by Robert Kahn and conducted by the Advanced Research Projects Agency, part of the United States Department of Defence. Later Cerf made many efforts to build and standardise the Internet. In 1984 the technology and the network were turned over to the private sector and to government scientific agencies for further development. The growth has continued exponentially. Service-provider companies that make «gateways» to the Internet available to home and business users enter the market in ever-increasing numbers. By early 1995, access was available in 180 countries and more than 30 million users used the Internet. The Internet and its technology continue to have a profound effect in promoting the exchange of information, making possible rapid transactions among businesses, and supporting global collaboration among individuals and organisations. More than 100 million computers are connected via the global Internet in 2000, and even more are attached to enterprise internets. The development of the World Wide Web leads to the rapid introduction of new business tools and activities that may lead to annual business transactions on the Internet worth hundreds of billions of dollars.
19. AGRICULTURAL MACHINERY
Agricultural machines are used to till soil and to plant, cultivate, and harvest crops. Since ancient times, when cultures first began cultivating plants, people have used tools to help them grow and harvest crops. They used pointed tools to dig and keep soil loosened, and sharp, knife-like objects to harvest ripened crops. Modifications of these early implements led to the development of small hand tools that are still used in gardening, such as the spade, hoe, rake and trowel, and larger implements, such as ploughs and larger rakes that are drawn by humans, animals, or simple machines.
Modern machinery is used extensively in Western Europe, Australia, the United States, the Russian Federation and Canada.
Modern large agricultural implements, adapted to large-scale farming methods, are usually powered by diesel-or petrol-fuelled internal-combustion engines. The most important implement of modern agriculture is the tractor. It provides locomotion for many other implements and can furnish power, via its power shaft, for the operation of machines drawn behind the tractor. The power shafts of tractors can also be set up to drive belts that operate equipment such as feed grinders, pumps, and electric-power generators. Small implements, such as portable irrigators, may be powered by individual motors.
Implements for Growing Crops
Many types of implements have been developed for the activities involved in growing crops. These activities include breaking ground, planting, weeding, fertilizing, and combating pests.
Ground is broken by ploughs to prepare the seed-bed. A plough consists of a blade-like ploughshare that cuts under, then lifts, turns, and pulverizes the soil. Modern tractor ploughs are usually equipped with two or more ploughshares so that a wide area of ground can be broken at a single sweep. Harrows are used to smooth the ploughed land and sometimes to cover seeds and fertilizer with earth. The disc harrow, which has curved, sharp-edged steel discs, is used mainly to cut up crop residues before ploughing and to bury weeds during seedbed preparation. Rollers with V-shaped wheels break up clods of soil to improve the aeration of the soil and its capacity for taking in water.
Some cereal crops are still planted by broadcasting seeds-that is, by scattering the seeds over a wide area. Machines for broadcasting usually consist of a long seed-box mounted on wheels and equipped with an agitator to distribute the seeds. Broadcast seeds are not always covered by a uniform or sufficient depth of soil, so seeding is more often done with drills, which produce continuous furrows of uniform depth. Specialized implements called planters are necessary for sowing crops that are planted in rows, such as maize. Maize planters and other similar machines have a special feed wheel that picks up small quantities of grain or separate kernels and places them in the ground.
Fertilizer can be distributed during the winter or shortly before seeding time. Commercial fertilizers are commonly distributed, along with seeds, by drills and planters. Manure is distributed most efficiently by a manure spreader, which is a wagon equipped with a bottom conveyor to carry the fertilizer back to a beater attachment, which disintegrates it and then scatters it on the ground.
After crops have begun to grow, a cultivator is used to destroy weeds and loosen and aerate the soil. A flame weeder, which produces a hot-air blast, can be used to destroy weeds growing around crops, such as cotton, that have stems of tough bark. The weeds are vulnerable to the hot air, but the tough stems protect the crops from damage. Chemical herbicides applied in the form of a spray or as granules are used extensively for weed control.
Insecticides for pest control are applied to soil and crops in the form of granules, dust, or liquid sprays. A variety of mechanical spraying and dusting equipment is used to spread chemicals on crops and fields; the machinery may be self-powered, or drawn and powered by a tractor. In areas where large crops of vegetables and grain are grown, aircraft are sometimes used to dust or spray pesticides.
Chemical pesticides are used in nearly all farming operations undertaken in developed countries. However, increasing concern over the harmful effects that pesticides may have on the environment has led to the use of alternative forms of pest control. For example, farmers use crop rotation to prevent pests that feed on a certain crop. Also, certain pests are controlled by introducing an organism that damages or kills the pests, but leaves the crops unharmed. Finally, some crops are being genetically engineered to be more resistant to pests.
Implements for Harvesting Crops
Most cereal crops are harvested by using a combine-a machine that removes the fruiting heads, beats off the grain kernels, and cleans the grain as the combine moves through the fields. The cleaned grain is accumulated in an attached grain tank.
Wheat and other cereal crops are harvested by a combine which, as it moves along the rows, picks the ears from the stalks and husks them. The ears are then transferred either to a sheller, which removes the kernels from the ear, or to a vehicle trailing behind the machine.
Hay harvesting usually requires several steps. First, the hay is cut close to the ground with a mower. After drying in the sun, most hay is baled. In baling, the pickup baler lifts the hay to a conveyor that carries it to a baling chamber, which compresses the hay into bales weighing up to 57 kg or more and ties each bale with heavy twine or wire. A machine called a field chopper cuts down green hay or field-cured hay for use as animal feed. After being cut down, the hay is stored in a silo and allowed to ferment; this type of animal feed is nutritious and resistant to spoilage.
Specialized machinery is also used to harvest large root crops such as potatoes and sugar beet and to harvest fruits and vegetables. Some mechanical fruit-pickers that are used to harvest tree fruits, such as plums, cherries, and apricots shake the fruit tree, causing the fruit to fall on to a raised catching frame that surrounds the tree. Nut crops can also be harvested in this manner.
Use of agricultural machinery substantially reduces the amount of human labour needed for growing crops. The average amount of labour required per hectare to produce and harvest corn, hay, and cereal crops has fallen to less than a quarter of what was required only a few decades ago.
Прийменники, що позначають рух
to рух у напрямку до предмету (особі), що протікає процесу:
Come to me. - Підійдіть до мене.
from рух від предмета (особи), видалення від протікаючого процесу:
Take this book from the table .- Забери книгу зі столу. '
I come from Russia. - Я з Росії.
into рух всередину обмеженого простору:
Put the book into the bag. - Поклади книгу в портфель.
out of рух з обмеженого простору:
Take the book out of the table. - Дістань книжку з столу.
on (to) / onto рух на поверхню:
Snow fell onto the ground. - Сніг падав на землю.
through через, крізь: Не went in through the door. - Він увійшов через двері.
Прийменники, що позначають місце
at місцезнаходження у предмета (особи), а також там, де протікає певний процес