Сборник адаптированных текстов по английскому языку Lesson 1 We learn English
About Some Technical Terms in Radio electronics
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About Some Technical Terms in Radio electronicsLet's pay special attention to the meaning of a number of technical terms used in radio electronics. To amplify means to increase in magnitude, or strength. We usually apply this term when we mean the amplification of a signal, current or voltage. Microwaves are radio frequencies with such short wave lengths that they show some properties of light. Their frequency range is from 1,000 me (megacycles) and up. We express radio-frequencies in kilocycles per second (K c/s) at and below 3,000. In radio engineering the range means the maximum useful distance of radar. Radar is the acronym for "Radio Detecting and Ranging". It is a system that measures distance (and usually the direction) to an object Electromagnetic Waves An electric field that is changing in intensity can produce a magnetic field around itself, and a magnetic field that is changing in intensity can produce an electric field around itself. Thus, it seems that once1 either an electric or a magnetic field is created, each will continue to produce the other as they move through space. We can, therefore, define an electromagnetic wave as a disturbance made up of both an electric and a magnetic field, each of which is constantly changing in intensity and generating the other as the disturbance travels through space at a velocity of 180,000 miles per second. The higher the frequency of an electromagnetic wave, the more energy it must possess. This can easily be seen once it is realized that the higher the frequency of an electromagnetic wave, the more times per second it must increase and decrease in intensity. This is another way of saying that it undergoes a greater amount of acceleration than a wave of lower frequency. Ultrasound Ultrasonic may be defined as the branch of science dealing with sound waves — physical vibrations of particles of matter — that are inaudible because their frequency is too high. Ultrasonic is a comparatively new branch of science, but progress being made in developing ultrasonic technique has been so rapid that today ultrasonic generators and instruments find application in many industries. The first important use of ultrasonic was made by P. Langevin, a French scientist, during the 1914-18 for detecting submarines % by using underwater sound. P. Langevin designed and built a high power ultrasonic generator, having used piezoelectric substance i (quartz crystals) to convert electrical energy to sound energy. The significant series of experiments was performed by the scientists of many other countries as well. 5. Ultrasound like a beam of light can be focused yielding a still greater concentration of sound energy. The latter can be transmitted over great distances. This made it possible to produce high power ultrasonic machine thus opening prospects for new uses of ultrasound. Having used new, unique the Soviet scientists and engineers developed new ultrasonic machine-tools and instruments. The latter soon began to find applications in measuring" the thickness of sheet material, the level of liquids in vessels, flaws in metals, etc. Ultrasonic has been especially successful in the detection of flaws in various materials particularly in metals. Its use for this purpose was first suggested by the Soviet scientist Sokolov in 1929. Having been applied in industry ultrasonic instruments demonstrated their superiority over other testing devices such as, for example, X-ray system. Sound waves can penetrate many solids and liquids more readily than X-rays revealing tiny defects in a material. Application of ultrasonic for testing and measuring materials has become one of its major uses within the past few years. Ultrasonic machine-tools have opened great possibilities when applied to the machining of brittle materials. Holes of any shapes and intricate patterns can be cut in brittle materials of all kinds: glass, ceramics, quartz, etc. Ultrasound is also used at our industrial enterprises for welding different materials which cannot be welded by other means. Aluminum can be ultrasonically welded directly to certain ceramics or to another non-metallic materials. 33. The field of ultrasonic applications in chemistry is a very promising one. Ultrasonic instruments can be used to promote and accelerate chemical reactions. Considerable interest centers on the use of ultrasonic techniques for cleaning purposes. Due to the techniques in question we are able to remove impurities from small and intricate metal parts used in watches, rockets and satellites. Considerable research and development work is now being carried out into new applications of ultrasound. Lesson 30 Radioisotopes in Industry Radioisotopes in IndustryThe radiation emitted by radioisotopes is being utilized in a variety of useful ways. One way is measuring or testing industrial products, another is tracing the most complicated chemical reactions, and still another is producing heat for the generation of electric power. Radioisotopes often do a job better than conventional methods do. Sometimes they do jobs conventional devices can't do at all. Since their radiation can easily be followed radioisotopes are being widely used as tracers. We know of the petroleum industry being an early user of radioisotopes to transport different liquids and oil. A radioisotope placed between different liquids or grades of petroleum signals where the flow of one product ends and the other begins. Radiation from the isotope also indicates the rate of flow along the length of the pipeline. By using this tracer method the engineers today are able to examine parts of various engine designs after testing, to learn facts about their wear and the efficiency of lubricants. Radioisotopes are widely employed in thickness gauges for all sorts of coated materials which are manufactured in continuous rolling sheets. In such a gauge a radiation beam from an isotope is passed through or reflected from the material being manufactured. Even the tiniest variations in the thickness will result in varying the strength of this beam and in a reading on the gauge. Gauge readings are fed electronically into a device that automatically adjusts the manufacturing processes so as to ensure the correct thickness of the material. Radiation gauges have the advantage of eliminating mechanical contact with the material being measured. They also give an accurate and uninterrupted reading no matter how fast the sheet flows. We have mentioned of radioisotopes being used to trace chemical reactions. More over radiation itself is used to change the molecular structure of sub stances, the materials with new properties being obtained. Many plastics products now in use have undergone this treatment. Plastics treated by radiation can be made stronger, more heat-resistant and easier to dye. Everyone knows of chemical batteries losing its power after a time, especially under constant use. Radioisotopes give off heat as well as radiation and this heat can readily be converted into a steady and long- lasting supply of electric current by means of a device known as a thermocouple. The current thus generated can be used to continuously are charge conventional batteries. 8. Thus, it is radioisotopes that are capable of supplying electric power for years. It may be expected that other radio isotopic devices will be utilized one day for providing reliable and long-lasting sources of electricity for spaceships during manned flights. Isotopes About 1907, scientists discovered that two samples of an element which looked exactly alike and behaved exactly alike chemically could differ radically in their physical make up. They learned that the reason for this difference was due to a variation in the physical structure of the atoms making up the samples. Scientists called such chemically alike—but physically unlike—substances "isotopes". The word was derived 3 from the Greek "isos" meaning "same" and "topes" meaning "place". Thus, isotope is the name given to a substance- which — although it differs physically from another substance—lakes the same place along with the other substance in the chemical table of elements. We know of most isotopes being stable. That is, they do not give off radiation. But some isotopes are not "stable", i.e. they give off radiation. These isotopes are known as radioactive isotopes, or—for short—radio isotopes. Most radioisotopes are made in nuclear reactors or in machines called accelerators by bombarding stable, non-radioactive atoms with neutrons. After being bombarded the nuclei of the stable atoms acquire additional particles and become unstable. These unstable nuclei try to become stable again by throwing off their excess energy in the form of radiation. Lesson 31 What is Automation? What is Automation? Automation may be said to be a modern term signifying the use of machines to do work that formerly had to be done by people. What used to be called labor saving or mechanization has now been called automation. Any tool is claimed to be a form of automation provided it helps people work more easily, better, or more quickly. Provided the tool can do its work without requiring human guidance it is said to be a higher form of labour saving, for example your self-winding wrist watch. A machine language of some sort is the foundation of every higher form of automation. Punched cards represent a machine language as Hoesched paper tape. If you work on a computer system that turns out ched card checks, you will probably have good control of the machine Miguage after the first week provided you are trying to learn. 4 The machine that automatically makes inspects and packs 1,200 wettes a minute can do nothing else. It is a one-purpose machine as many of others. 5. But the digital computer seems to be versatile and can be used as the brains for automating a wide variety of work where figuring, remembering and making logical choices are required. The computer proves to be only a very high-speed adding and subtracting machine. It is unlikely to be the thinking machine as it is sometimes called. Every thing it does other than4 adding and subtracting is the result of man's ingenuity. The design of newer equipment with greater usefulness and capabilities is said to be bringing about an ever increasing growth in the development of control equipment. The reason is twofold. Firstly automatic controls relieve man of many monotonous activities so that he can devote his abilities to other occupation. Secondly modern complex controls can perform functions which are beyond the physical abilities of man. For example an elaborate automatic control system operates the engine of a modern jet airplane with only a minimum amount of the pilot's attention, so that he is free to fly his airplane. Mention should be made that the design and development of automatic control systems is a principal concern of an engineer. In recent years we know automatic control systems to have been rapidly advancing in importance in all fields of engineering. The applications of control system are known to cover a very wide scope, ranging from the design of precision control devices such as sensitive instrument to the design of the equipment used for controlling the manufacture of steel or other industrial processes. New applications for arranging automatic controls are continually being discovered. Lesson 32 The Development of Radio Engineering and Electronics The Development of Radio Engineering and Electronics 1. The invention of electronic devices whose activity is based on the flow of free electrons in a vacuum has considerably enlarged the application of electrical energy for various industrial purposes. It is electronic devices that made it possible to solve (the problem of obtaining high-frequency currents which are the basis of radio engineering, television, ‘talkies‘ radar and other very important branches of modern engineering. Radio, one of the greatest achievements was born in Russia. A. § Popov, a Russian scientist, was the first to produce an apparatus which has become the world's greatest means of communication and propagation culture. A. S. Popov demonstrated the first radio receiving set in the world as far back as 1895. Broadcasting is considered to be developed in the USSR along with short waves. For the time being radio broadcasting has become a part of our life. The basic devices in radio engineering are known to be radio-transmitting and radio-receiving ones. The theory of both these devices was developed by Soviet scientists. 5. In the early 30's3 Academician A. I. Berg developed the theory of radio-transmitting devices, professor Siforov working out the theory of radio-receiving devices. Academician Vvedensky is known to have contributed a great deal to the successful development of Soviet radio electronics. His investigations in the field of propagation of ultra-short waves proved to be of particularly great significance. The results of these researches are increasingly used in television, radar and other fields of radio engineering. 6. Use is made of radio electronics at every step. Without radio electronics we would not have cybernetics, cosmonautics and nuclear physics. No book on electricity would be complete without mentioning electronics. 7. In the field of television our country was the first as compared with other countries. As early as the 20's in Moscow under the supervision of V. I. Archangelsky television signals were transmitted for the first time. In the early 30's electronic television was being developed. Principles of electronic television suggested by B. L. Rosing were put into practice by S. I. Katayev and other Soviet specialists. In 1939 theMoscoW television centre was put into operation. The newly built 500 meters television tower in Moscow makes it possible to extend direct broadcasts to more than a hundred kilometers. 8. Intervision has come into being; colour programmes are bеing regularly broadcast. Moscow and Leningrad TV programmes are being rebroadcast by a large number of stations in different republics. 9. As far as radar is concerned Soviet specialists made a great contribution. They are N. F. Alekseev and D. E. Malyarov, who work under the supervision of Professor M. A. Bontch-Bruyevitch. They developed a multi-slot magnetron operating at 10 cm wave. One of first radars is known to have been worked out by Kobzaryov. 10.After the second world war a young Soviet scientist N. I. Kabanov covered the phenomenon of "back dissipation" while broadcasting —arried out using ultra-short waves. We know this discovery to be if Kabanov's effect. Wide use is made of this effect in radio communication 11. As for the latest developments in the field of radio engineering mention should be made that there have been major changes in recent such as stereophonic sound and colour television. Provision is also made for the changeover to the use of semiconductor devices such the transistor, the application of new construction techniques such printed circuitry, the use of higher frequencies for broadcasting and frequency modulation. 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