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  • . THE RUSSIAN METALLURGIST D. K. CHERNOV

  • 2. OXYGEN IN THE BESSEMER CONVERTER

  • 4. OXYGEN FOR DIRECT REDUCTION OF IRON ORE

  • 5. CRUCIBLE FURNACE

  • 6. PORTABLE HARDNESS TESTER

  • 7. HIGH-SPEED PRECISION BALL BEARING TESTING MACHINES

  • AГЛИЙСКИЙ. Пособие по английскому языку для машиностроительных вузов допущено Министерством высшего и среднего


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    THE HYDRAULIC INTERNAL GRINDER


    Machines of this type are of extremely massive construc­tion but are so designed that they can be operated as easily as machines of smaller sizes. They are hydraulically operat­ed, and controlled by a single lever conveniently located at the front of the machine. This single lever controls all func­tions of the machine, including all movements of the wheel slide, cross feed, and starting and stopping the work-spindle. The wheel slide can be swung to the rear through the medium of the hydraulic lifter, thus giving, easy and rapid access to the work. The wheel-spindle is driven by V-belts from a motor on an adjustable bracket on the wheel slide. Idlers are provided to give a maximum of belt contact and to main­tain proper belt tension. The cross feed for the wheel slide is also operated by a hydraulic unit and can be set automa­tically.

    (b) Make up some questions, on the basis of this text and answer them

    IX. Describe the surface grinder shown in Fig. 55.

    CHAPTER V


    TEXTS FOR HOME READING
    1. THE RUSSIAN METALLURGIST D. K. CHERNOV
    The father of the branch of science concerned with the changes in structure of steels was the Russian metallurgist Dmitry Konstantinovich Chernov (1839-1921). Investigating the properties of steel after heating to various temperatures, Chernov first established that at definite temperatures steel undergoes certain changes altering its structure and proper­ties. These "critical temperatures" characterized by internal changes in the steel are now known all over the world as the "Chernov points". One of these points called by Chernov point a, is notable for the fact that steel heated below this point (about 700°C) cannot be hardened no matter how rap­idly it is cooled. Another point, b, is characterized by the fact that as soon as the temperature of the steel reaches it (800 to 850°C), the steel rapidly passes from the coarse crys­talline into the fine crystalline state, in which it possesses the best mechanical properties. If the temperature is raised still further, the metal crystals begin to increase again in size, and the higher the temperature, the more rapidly they grow.

    The discovery of the critical points of steel was of very great importance for metallurgical theory and practice. Ex­plaining the phenomena of tempering and hardening of steel and the structural changes taking place in steel when heated, it enabled accurate determination of the hardening temperatures and selection of favourable conditions of forging and other types of steel treatment, promoting improvement of its mechanical properties.
    2. OXYGEN IN THE BESSEMER CONVERTER
    Fundamentally, the addition of oxygen to the Bessemer air blast should have two major effects: (1) to increase the rate of oxidation because of the higher partial pressure of oxygen in the system; (2) to increase the amount of heat available to melt cold materials. The use of oxygen for enriching the blast of the basic Bessemer converter or for chang­ing the nature of the converter blast altogether, became a very important development in steel works. Reduction of nitrogen content in Bessemer steel by oxygen enrichment alone reaches a limit at about .006 per cent nitrogen. Furth­er it is necessary to remove all nitrogen from the blast but, at the same time, maintain a blast composition which will oxidize metalloids in the steel without generating so much heat that the converter tuyeres are burned out. This can be done by a mixed blast of oxygen and superheated steam. By this method steel containing less than .003 per cent nitrogen is produced.

    One potential source of difficulty in the oxygen-steam mixed blast process is the danger that condensate from the steam may attack the dolomite bottom of the converter. To avoid this, some designers recommend the use of thin copper tubes embedded in the bottom plate to act as protective lin­ers for the tuyeres. Quite recently some experiments were made with the so-called "dual-blast" converter in which air is blown upward through ordinary tuyeres in the bottom while high-purity oxygen from the top is directed down­ward at low impact pressure onto the surface of the bath. This oxygen is intended not so much to penetrate the metal as to flood the whole atmosphere above the converter bath with oxygen, thus promoting high concentration and reactiv­ity of iron oxide in the basic slag.

    By changing the number of open tuyeres in the bottom of the converter the ratio of oxygen going down to air going up can be varied within wide limits. The object of this de­parture is to develop a conversion process that will remove phosphorus from Thomas pig-iron before decarburization is complete. By passing oxygen downward onto the surface of the metal and the lime which are being agitated by the rising air blast, the necessary early liquefying of the lime is achieved and early dephosphorization takes place.

    3. OXYGEN ENRICHMENT IN THE BLAST FURNACE


    Oxygen enrichment by itself has been considered of marginal advantage in the blast furnace except in the production of ferro-alloys. This is because a greatly increased tuyere conetemperature upsets the thermal balance and leads to some difficulty in avoiding the production of high silicon iron. It has been found, however, that oxygen-enriched blast combined with steam injection serves to drive the furnace faster and generate a gas of greater reducing power with no significant change in hearth zone temperature.

    Some plants currently practice routine oxygen enrichment of blast furnace air for the production of steelmaking iron. Approximately 65 tons of oxygen per day per furnace are required for each 1 per cent of enrichment. With an avail­able oxygen supply of about 400 tons per day, it has been, found advantageous to spread this amount over four operat­ing furnaces rather than to concentrate it on one furnace.

    The economic attractiveness of oxygen enrichment in the blast furnace is greatest under conditions of capacity opera­tion when there is a strong demand for, the additional iron which can be produced. The most promising use of blast furnace oxygen enrichment lies in ferro-alloy smelting. The high hearth temperature produced with oxygen favours the reduction of non-ferrous metal oxides and formation of their high melting point slag.
    4. OXYGEN FOR DIRECT REDUCTION OF IRON ORE
    Basically the industry is still dependent on the units of production that characterized it in the early years of this century by-product coke ovens, blast furnaces, open hearths, blooming and secondary mills. Direct ore reduction processes may change this since they provide a potential replacement for the coke oven-blast furnace complex. The H-iron process is a typical example. This process consists in bringing into intimate contact, at about 900°F and 400 pounds per square inch, finely divided iron ore and preheated hydrogen gas.

    Pressurized hydrogen enters a large cylindrical reducing vessel at the bottom and in passing upward keeps the fine ore particles in a state of turbulent motion. In the reducer hydrogen reacts with the preheated iron oxide to form reduced iron and water:

    Fe2O3+3H2==2Fe+3H2O.

    The gas leaving the top of the reactor consists of unreacted hydrogen and water vapour. |

    Regenerated hydrogen, as well as fresh hydrogen to take the place of the hydrogen converted to water, is recycled to the reducer. The reduced iron product is briquetted, thermally passivated, and can then be charged directly to open hearth or electric furnaces to replace the scrap. The production of hydrogen for such a process may be accomplished b exothermic partial oxidation of natural gas of fuel oil.
    5. CRUCIBLE FURNACE
    The crucible furnace is one of the oldest furnaces for melting non-ferrous metals, and it is being used a great deal at the present time. High carbon steel is made by melt­ing scrap steel in a crucible too. The construction of a cruci­ble furnace consists of a shell which is made pf a steel plate about in. thick. It rests on a plate made of cast iron. The legs support the furnace high enough from the floor to allow for draft and ashes. The grate works on hinges so that it can be raised and dropped. The grate is turned by the han­dle. The cover holds down the flame. The furnace should be connected by the flue with a chimney. The melting capaci­ties of the crucible in one heat are from 20 to 300 lbs of brass or from 10 to 100 lbs of aluminium. The linings are made of brick and are applied about the same as in the cupola furnace.

    Sometimes the furnaces are set on the floor, but, in most cases, they are set in a pit because they are more easily oper­ated in such a setting. Shavings and kindling are placed on the grate with about 50 lbs of coke on the kindling. Af­ter the coke bed is well lighted, one should build up the coke bed so that the top of the crucible, when put in, will beeven with the top of the flue. The bottom of the furnace and grates should be kept free from ashes and cinders, or the draft will not get through, causing much trouble in getting the metal enough to run the castings.

    The crucible way is used for making high carbon steel andspecial steels. The percentage of carbon the scrap steel contains must be known.
    6. PORTABLE HARDNESS TESTER

    In use, the portable tester is applied to the work, as shown in Fig. 56, and a handpiece is depressed, with the result that a diamond indentor is brought into contact with thesurface. Continued move­ment of the handpiece causes the indentor to be pressed into the work under a рrе-determined load for a maximum depth of 0.005 in. A reading which corresponds tо the hardness value is then obtained on a large-diameter dial-type indicator. Scales of different colours are provided which give direct readings in Vickers pyramid, Brinell, and Rockwell values. The instrument is available in different types, one of which gives full scale readings for Vickers pyramid numbers from 80 to 1200, Brinell from 80 to 630, and Rockwell from 30 to 70. A second instrument gives full scale readings in Vickers pyramid numbers from 35 to 300. Another type provides readings of Rockwell A, B, and С values from 30 to 90, 40 to 100, and to 70. On the fourth

    Fig. 56. Portable Tester

    hardness tester the full scale readings obtainable range from 80 to 1200 Vickers pyramid, 80 to 420 Brinell, 35 to 99 Rockwell B, and 20 to 70 Rockwell C.
    7. HIGH-SPEED PRECISION BALL BEARING TESTING MACHINES
    Investigation has been carried out for several years on the performance of precision ball bearings of small diameter, as employed, for example, in instrument gyroscopes, and, machines have been developed for the measurement of frictional torque and vibrations in bearings of 5 to 15 mm bore, running at speeds as high as 60,000 rpm. Machines havenow been built for torque measurement. A machine consists of a high-speed driving unit, arrangements for applying variable radial and axial loads, and a sensitive recording torque meter. Because of the high speeds involved, and the need for great sensitivity, air bearings, specially developed for the purpose, are used throughout. These bearings have proved entirely satisfactory and have given some thousand of hours service without attention.1

    Drive to the main spindle, whereon the: test bearing is mounted, is provided by a high-frequency motor, which is mounted above, and supplied by a variable-speed motor-al ternator set housed in the machine base. An endless bell made from pure silk, impregnated with linseed oil dressing is used to transmit the drive from the crowned motor pulley to the main spindle. The inner race of the ball bearing under test is held in position on the end of the high-speed; spindle by means of a nut, and the outer race is clamped axially in a housing which floats freely in a secondary air bearing and serves as a virtually frictionless support.

    Radial loads can be applied by dead weights acting through the air film of the secondary bearing. Axial load are-applied pneumatically, so that no rotational constraint is imposed on the test bearing, and provision is made for lubricating the bearing with oil mist while tests are being carried out. Friction in the bearing is detected and measured with the aid of a torque arm fixed to the housing carrying the outer race.

    A photocell is arranged at one end of the arm to detect any movement due to frictional torque, and the resulting electrical signal is amplified and fed back to a moving coil wound on a copper former fixed to the torque arm, the coil being arranged to move in the field of a permanent magnet.

    ____________________

    1. have given some thousands of hours service without; attention — работают несколько тысяч часов без обслуживания


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