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 fabricatedto meet the needsof modern technology. Using the laboratorytechniquesand knowledge of physics, chemistry, and metallurgy, scientists are finding new ways of using metals, plastics and other materials.

Engineers must know how materialsrespond to exter­nal forces, such astension, 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 theexternal force disap­pears. The materials may also havepermanent deforma­tion or they mayfracture. The results of external forces arecreep andfatigue.

Compression isa pressure causing adecrease in vol­ume. When a material is subjected to abending, shear­ing, or torsion (twisting) force, both tensile and compressive forces aresimultaneously 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 usu­allystretches, returning to its original length if the force does notexceed the material'selastic limit. Under larger tensions, the material does not returncompletely to its original condition, and under greater forces the mate­rialruptures.

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 gradualloosening 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 deformationeliminates the force causing the creep. Creepextended over a long time finally leads to the rupture of the material.

Vocabulary

bar— брусок, прут

completely — полностью, совершенно

compression — сжатие

creep — ползучесть

cross-sectional area — площадь поперечного сечения

cyclic stress — циклическое напряжение

decrease — уменьшение

elastic deformation — упругая деформация

elastic limit — предел упругости

exceed — превышать

external forces — внешние силы

fatigue — усталость металла

fracture — перелом, излом

loosen — ослаблять, расшатывать

permanent deformation — постоянная деформация

remaining — оставшийся

shear — срез

simultaneously — одновременно

to stretch — растягивать

technique — методы

tension — напряженность

to propagate — распространяться

to bend — гнуть, согнуть

to extend — расширять, продолжаться

to meet the needs — отвечать требованиям

to occur — происходить

to respond — отвечать реагировать

to suffer — страдать

torsion — кручение

twisting — закручивание, изгиб

volume — объем, количество

rupture — разрыв

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. отвечать требованиям современной технологии

2. используя лабораторные методы

3. новые способы использования металлов

4. сжатие, растяжение, изгиб, кручение, срез

5. возвращать первоначальный размер и форму

6. внешняя сила

7. постоянная деформация

8. уменьшение объема

9. растягивающие и сжимающие силы

10. превышать предел упругости материала

11. повторяющиеся циклические напряжения

12. разрушение материала

13. развитие и распространение мелких трещин

14. сопротивление материалов ползучести и устало­сти

Exercise 3.2. Translate into English the following sentences:

1. Упругая деформация — это реакция всех мате­риалов на внешние силы, такие, как растяжение, сжа­тие, скручивание, изгиб и срез.

2. Усталость и ползучесть материалов являются результатом внешних сил.

3. Внешние силы вызывают постоянную деформа­цию и разрушение материала.

4. Растягивающие и сжимающие силы работают одновременно, когда мы изгибаем или скручиваем материал.

5. Растяжение материала выше предела его упру­гости дает постоянную деформацию или разрушение.

6. Когда деталь работает долгое время под цикли­ческими напряжениями, в ней появляются небольшие растущие трещины из-за усталости металла.

7. Ползучесть — это медленное изменение размера детали под напряжением.

Text В: «Mechanical Properties of Materials»

Density (specific weight) is theamount of mass in a unitvolume. It is measured in kilograms per cubic me­tre. The density of water is 1000 kg/ m3 but most mate­rials have a higher density andsink in water. Aluminium alloys, with typical densities around 2800 kg/ m3 are con­siderably less dense than steels, which have typical den­sities around 7800 kg/ m3. 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.

Strengthis the force per unit area (stress) that a ma­terial can support without failing. The units are the same as those of Stiffness, MN/m2, but in this case the deformation is irreversible. Theyield 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 theirabilityto be formed into the shape that is needed, such ascar body parts. Materials that are not ductile are brittle. Ductile materials canabsorb 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 agradual 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 — способность

amount — количество

absorb — поглощать

amount — количество

application — применение

brittle —хрупкий, ломкий

car body — кузов автомобиля

constituent — компонент

crack — трещина

creep resistance — устойчивость к ползучести

definition — определение

density — плотность

ductility — ковкость, эластичность

failure — повреждение

gradual — постепенный

permanent — постоянный

rigid — жесткий

to sink — тонуть

square root — квадратный корень

stiffness — жесткость

strain — нагрузка, напряжение, деформация

strength — прочность

stress — давление, напряжение

tensile strength — прочность на разрыв

toughness — прочность, стойкость

yield strength — прочность текучести

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. количество массы в единице объема

2. килограмм на кубический метр

3. мера сопротивления деформации

4. отношение приложенной силы на единицу пло­щади к частичной упругой деформации

5. жесткая конструкция

6. прочность на сжатие

7. способность материала деформироваться не раз­рушаясь

8. поглощать энергию путем деформации

9. обратно пропорционально квадрату размера де­фекта

10. постепенное изменение формы

11. повышенные температуры

12. высокие растягивающие усилия

Exercise 3.4. Translate into English the following:

1. Плотность измеряется в килограммах на куби­ческий метр.

2. Большинство материалов имеют более высокую плотность, чем вода и тонут в воде.

3. Плотность материала очень важна, особенно в авиации.

4. Модуль Юнга — отношение приложенной силы к упругой деформации данного материала.

5. Чем более металл жесткий, тем менее он дефор­мируется под нагрузкой.

6. Когда металл растягивают, он сначала течет, то есть пластически деформируется.

7. Свинец, медь, алюминий и золото — самые ков­кие металлы.

8. Сопротивление ползучести является очень важ­ным свойством материалов, которые используются в авиационных 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

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