THE USE OF RADIOACTIVE ISOTOPES AND NUCLEAR RADIATION IN THE SOLUTION OF SOME PROBLEMS OF BLAST-FURNACE AND STEEL-MAKING PRODUCTION

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CIA-RDP80T00246A007900090002-4
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RIPPUB
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U
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27
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December 22, 2016
Document Release Date: 
April 29, 2009
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2
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Publication Date: 
October 8, 1959
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REPORT
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Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Next 1 Page(s) In Document Denied Iq Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Telesov S.A., Shvart an L.A. which the attainments of nuclear phyeioe have been utiliged9 by Afanaejev Vm19o9 Boljaev U.P.9 Bogdanova RoG.9 Bulsky M.T.9 Grusin P.L.9 Nikulinsky 10D09 Offongen- den A. ,, 9 Polovohenko IONS. 9 Pugaohev Ao V o 9Skrebt%ov AoH. 9 The extensive organi ation of work in ?etallur gy9 in Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 USE OF RADIOACTIVE ISOTOPES AND NUCLEAR RADIATIOZ SOLUTION OF SOME PROBLEMS OP BLAST-FUR PACE k D STILL-MAKING PRODUCTION in the USSR dates back to the years 1948?1949. The Institutes and plants of the Ferrous Metallurgy etwork of radiometric laboratories for the inspection and development of technological prooessesm Separate questions connected with the utili ation of radioactive isotopes and nuclear radiation in the metallurgical industry of the Soviet Union have been described in tho literature is detail. Some results have already been reported st international conferences. The present report deals only with Individual eples of the utilization of radioactive isotopes and nuclear radiation in the ferrous metal industry. Chief attention is paid to the results of work now in progress t the Kia etsk Iron and Steel forks, and the ?9Asovstal?? 9 the Daershinak9 the Ilich and the Stalinsk Iron and Steel ailla9 with the collaboration of the Central Scientific R.:sem orch Institute of the Ferrous Wetal Industry. I. BLAST-FUR1ACE PRODUCTION ~1. Re~eal,a$ion of I omi Charge in Bleat?Furnaoes In the field of oat iron manufacture the automation of the control of the operation of the blast-furnace process rr sir r R Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 is an important problem. In this connection there arises the need to provide contactless, continuous-acting low-inertia data units, which afford data on the run of processes,'as well as its transmission into the computer. In the solution of this problem in the Soviet Union great attention is paid to the utilization of radioactive isotopes. To that end there has been developed a radiometric installation de- signed for the regulation of blast-furnace incoming charge. At the present time the blast-furnace incoming charge is regulated on the basis of indications of mechanical soundings, which give satisfactory results only when the blast-furnace runs smoothly. Sounding diagrams often-do not characterize the position of the surface of the charge and do not permit to regulate the level of filling. Great difficulties are experi- enced when mechanical soundings are utilized in the operat- ion of large volume blast-furnaces,when the pressure under the furnace top is raised. The radioactive method regulating the level of filling of the blast-furnace with charge materials is based on the ab sorption of gamma-rays from radioactive sources. In the given case one may utilize radioactive isotopes of cobalt and other elements with a hard gamma-radiation (with energies of I MeV ore) and with a sufficiently large half-life (one year and more). Closed sources of radiation with activities of about 200 mcuries (depending upon ray hardness and furnace dimen- sions) are set up in the furnace refractory masonry at a definite level of fill of charge materials, or under the bell (Fig. 1). At various points along the furnace periphery in the refr Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 ) are Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 installed, whose cables are connected to the recorder with a light panel. Detectors are set up on a number of horizons, four on each horizon. When the charge material level of fill is lower that the location of any one of the detectors, the irradiation intensity of the detector increases abruptly, and the respective signal lamp on the control board ignites. The radiometric method of regulation of the level of filling is being used on one of the blast-furnaces of the Dzerzhinsk plant. The diagram of the radiometric regulator of the level of filling, developed by personnel of the plant, of CSRIFMI and of the Ukrainian Institute of Metals, is shown on Figures 9 and 2. In this case two sources of radio- active cobalt, 500 mouries each, were placed on the blast- furnace, under the level of the material, along the furnace top circumference, between the vertical rows of counters (See Fig. 2). Sources and counters have been arranged in such a manner that the radiation of each source acts only upon the two vertical rows of counters, which are opposite to it. The possibility of shifting the sources in pipes permits to carry it out with fascility. A comparison of the readings of the radiometric instal- lation and of the mechanical soundings leads to the following conclusions: a. The readings of the installation from the side of the cast iron tap and air heaters rarely coincide with sounding data when the furnace runs very smoothly; as a rule, the read- ings of mechanical soundings are considerably lower than the surface of the fill, as revealed by radiometric control; b. Due to the fact that the soundings are drawn in by the charge, the actual level of materials is in many cases higher Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 that the bottom position of the edge of the large bell; as a result, the orientation by mechanical sounding readings often leads to the overloading of furnaces. The passage to the con- trol of the loading of furnaces by radiometric control data evens out the running of furnaces. The new regulator of filling clearly manifests a nonuni- form speed of incoming materials along the circumference. The Dzerzhinsk Plant, CSRIFMI the Ukrainian Institute of Metals and the Tallin measuring instruments plant have worked out an industrial standard for the radiometric fill regulator. During the cars 1959 and 1960 regulators will be installed on blast-furnaces at a number of plants. 2. Control of the Quality of the Charge and Ore In order to control the blast duty a reliable and quick determination of the granulometric composition of the charge is needed. At some plants the screen composition of charge materials is determined by the screen sizing of samples weighing about one ton, selected in 24 hours. This very labo- rious method dose not offer any possibility to obtain in the time alloted to it the necessary true results, which conside- rably lowers its validity. The study of the absorption of gamma-radiation by the blast-furnace charge components carried out on the Dzerzhinsk and Novo?Tulsk Steel Plants revealed the possibility of con- trolling the gas-permeability of charge materials by the ram diometrio method. It has been found that the absorption of gamma-rays in that case depends upon the density, the bulk weight of the material connected with the screen composition. Personnel of the CSRIFMI and of the Dzerzhinsk Plant develo- .._ _a...m_a .,Q.~,nro 4rnan4ehl rliwwi [?.R?4m for the measu- red Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 rement of the lunpimg of cokep upon whome screen composition depends the general gas-permeability of the charge colusss (coke occupies about 60% of the charge volume). The device ha a been installed at one of the blast?furna- oee of the D ershinak Plant, at the left-hand weight funnel of the lift of the blaot'furnace. The weight funnel a (Pig.3) le traneluced by a radioactive isotope of cobalt (Co60)9 with a 300 mourie activity, situated in a protective collimator b, which i be displaced by guides, either bringing it closer to the funnel, or removing it from the funnel. The data unit d, located on the opposite side p from centres at the point e consists of eight CTC 6 counters. It measures the intensity f the beam of rays, which passes through the coke, which reooreded by a specially constructed recorder. Coke lumping is recorded separately for each skip by its filling the weight funnel, simultaneously with the stoppegs of the disk sieve, which delivers coke from the hopper into the funnel. In wakJxg records on the band appear wpeak& of the radiation intensity (Fig. 4) varying in size, depending upon the density of the material. A cos parison of records of the device, obtained at the Daerzhinsk Plant, with readings of furnace operation,has re- v?aled that the absorption of gals -rays by coke varied from 5.0 to 12.7c of the moan value; at a mini absorption the coke ore load reached 2540 Ig/t and at a maziou it was lo- tiered to 2210 kg/t,j that is9 it pas lowered 1". That does not agree with the existing ideas on the possible effect of ook(@ lumping upon the ther&l oondition of the furnace and of echo cones ption (the amount of carbon in the charge rdl.y changes thereby) ? FU=900 operation observations revs- Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 led, that at poriod@ of isau a aboorption of g N? ?rryo by coke the extraction of coke out of the furnace with Gl increases (not only with the lc or, but al@o Vitt the MpPGg slag). Individual cast Iran yields were followed by tho carrying away of appro-RinatelY up to 10-12 tons of ool ? with the lower slag; a oomaidorabl3 amount of Who full into slag ladles through @l tapio Sino? the ?o r left the hearth heated to 1350?1400 ?C9 tho noti??able hoot l?@sG> nuot b? oaloulated? Th?s? fuel bosses i ndioate that it iG n?ooosary to inoroase ooko 14Bpffi008 in op?ratir fire creased gas pr?csuren to PM9 a greater attentio intenanoe of oaot iron cape and to the limitation Of 61 to yere dislensions Blast?furna?e output is in a considerable measure deter- ined by the preparation of ore materials. In the solution of thie problom the control Of the prop?se of iron ?r? r?fin- nd of agglomerate sintoring le an important link. Tho .utilisation of radi?active leotopes has proved to be very effeotiv0 in thie Qt?ld alo?a At the Ku notok Iron and Steel fork a radiometer was d?einged for the deteroiinati?n of the agglomerate denoity0 Instrument operation to bas?d on tho aboerption of radioaotivo euiceion of isotopes. Inotru ent t?oto at the ezzlomerato plant havo ehoun that It my bo used far the c?mtrel of tho process of are cintorin in cbtaimias the awlesormte. Further rationalis tion ?f the r oth?1? amd development of reliable inotalltatione for the control of the properties Of ooko,oro and awlo0orat? offer a p?cgibilitY to obtain data relation to the aoroync c re ietanoo ?f the oharff0? Tho MOO. of radiom?trie inotallationg for controlling the doneity Of Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 :ot e9 ore and agglomerate permits to increase blast-furnace output and also creates new prerequisites for the automation of laborious processes and for the sanitation of the oonditio of labour. ~, Determination of the Speed of Notion and of the Time during which the Charge stays in the Slash- rnace For a number of years on several plants in the Soviet Union is the motion of charge aterials in blast?gurcnaoee controlled. This work is of great practical value for the control of the blast furnaoe process and for the determination of optimal duties of furnace operation and of a rational shaft profile, For the study of the motion of the charge by means of dioaotive Isotopes two particular methods are used. The first method (the method of measuring the radioactivity of tests of melt products) determines the total time during which the materials are in the furnace - from the instant of loading to their getting into the hearth and their dissolution in cast iron. In this case materials are carried Into the furnace in the zone of the top at a definite time prior to the output of oast iron. The time of their getting into the hearth is established by the appearance of radioactivity in the cast iron. This method requires no special equipment 9 but it offers no possibility for the determination of the speed of the mooring charge on separate sections of the furnace shaft. The time during which various charge materials stay at a desired point In the furnace was determined on furnaces o$ a variety of volumes and designs. Tests at the Novo-Tulsk Plans have shown that in the zone of the body and in the lower MOW- Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 I' 1 1..111 Approved For Release 2009/04/29: CIA-RD P80T00246A007900090002-4 materials,which lessens the actual Word.ng volume of the furnace by 10-15'. This information is partially corroborated by limestone tests at the "izovstal" Plant. The mean speed of lowering materials, in a number of oases, was greater in in the centre of the furnace than at the periphery - directly at shaft walls, which depends both upon the system of loading and upon the physical properties of charge materials. The relative alteration of the mean speed along radii of two fur- naces of the "Azovstal" Plant is shown on Fig. 5. On the blast- furnace A the speed increases continuously from the periphery to the centre, while on the blast-furnace B it reaches a ma- ximum at a distance about 0.46 m from the shaft wall, and becomes less and less thereon. In both cases the speed is higher in the centre than at the periphery. The second method - of radiometrio sondage (developed by Fellows of NTMP , the Dserzhinsk Plant and CSRIFMI ) - permits to determine the speed of individual components of the charge on any section of the shaft. The diagram of the test in the points study of the speed of motion of the charge with eight pof of investigation is shown on Fig. 6. Radioactive granules o the charge were brought in to the level of filling, at a desired distance from the centre of the furnace, while at ho- rizons I - VI were introduced radiometric soundings consisting of a system of three coaxial pipes, between which there is provided the circulation of water, which maintains in the in- terior pipe a temperature not more than 400. In the interior pipe, which is sealed hermetically against the seepage of moisture, there is arraf?d a radiation detector' (a self-quen- ched counter). non traced oharge granules are lowered from the upper horizon, the radioaotivity is rooor~:ad in suooession on the Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 lower horizons. The speed with which the charge is moving on separate sections of the furnace is determined by the time intervals between maximum intensity of radiations which cor- respond to the passage of a granule through two adjacent horizons, or by the speed of the growth of intensivity at each horizon. For the location of the detector three variants are used: a. Outside the shaft, at the furnace hood; b. In the shaft lining; 3. In the interior of the furnace. The method of radiometric sondage was used on large volume furnaces. Tests revealed the displacement of the charge to the furnace centre at the second horizon) which was somewhat greater for coke than for ore. Between the second and third horizons both coke and ore deflect towards the periphery, the coke further than the ore. In the lower portion of the shaft materials also get displaced towards the periphery. In the axial zone the speed at which the mate- rials were lowering was in some sections higher than at the periphery. In the tuyere zone the movement of materials was investigated by means of soundings inserted through the tuyeres. It was found that radiation sources in one minute both approach the tuyere nozzle and move away from it many times. In the study of the motion of limestone on a furnace of medium volume it was found that the speed with which it moves dec- reases while it is being lowered; the limestone speed is maxi- al between the first and second horizons. In the lower part of the shaft at a distance of about 3.7 m from the wall limes- tone gets lowered faster than at the periphery: the lowering speed at a datum 20,520 at the periphery was 3 M/h, while at a distance of 2.5 m from the wall it was about 5.5 m/h. Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 4. motion of Cast Iron in a H?arth of a bar a Blast- Furnac By the method of radioactive indicators may be investiga- ted both the intermixing of smelting products and the motion of cast iron in the blast-furnace hearth. The method is based on the following principle. A radio- active isotope phosphorus-32 is introduced through the tuyere into the liquid cast iron and slag, which is in the hearth. Conclusions as to the nature of the motion of cast iron in the hearth are reached by the results of measurement of radio- active probes selected in definite time intervals. The present work was conducted at the Ilich Plant blast-furnace having a volume of 19719 cu. metres. The results of investigation are shown on Fig. 7. Different amounts of the radioactive indica- tor were applied in different tests. Therefore, on the axis of ordinates of Fig. 7 is laid off the radioactivity of sample expressed in percentages of the maximum radioactivity for each test. The weight of cast iron output is taken to be 1004,ahile the time of selpo'.ion of cast iron samples is also shown in relative units, taking into account the duration of the out- put. On the basic of the investigation made it was established that in the jntm-vaU between outputs cast iron in the hearth of the blast-furnace is mixed poorely. Some mixing and evening out of the temperature of cast iron and of the chemical com- position takes place, in the main, in the period of its outlet, as a result of the motion of cast iron in the hearth, and while it passes through the cast iron tap. When it is let out of the blast-furnace hearth, cast iron comes out first from ---4-- r %f the cast iron tap and last of all from the regi? the Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 of the hearth at the side of air heaters. In this process the upper layers of cast iron move considerably faster than the lower ones. 'Chen the central part of the furnace operate actively and when the cast iron tap is in a normal state,the rate with which the hearth is freed of cast iron is the s both for a furnaoo with a volume of 19033 cu m and for a fur- nace with a volume of 1,719 eu ma Practically from 10 to 15il of cast iron, which did not co e out during the output of cast iron,rera1ns in a blast-furnaoe,which has a useful volume of 1033-1719 cu m, which does not influence to any considerable degree the operation of the furnace. From the point of view of completness of outflow of cast iron out of a furnace during output there is no need in pro- viding a second cast iron tap for furnaces with a volume of 2,286 ou m having a 1003 m hearth diameter. t7hen the furnace a larger output and cast iron is let out frequently9 the ormal working state of the tap can be ensured by the utiliza- tion of high-quality carbon steel for the tap and of powerful electrical guns (,with an S0 kg/cm2 piston pressure). Cast iron is completely changed in the furnace on an average c' from 2 to 3 outputs, although some insignificant amount of cast iron still remains in the furnace. That is one of the factors conditioning both the blast-furnace hearth and the gradual composition of cast iron. thermal inertia of change of the ohs ical The change of the temperature of cast iron whilo the output proceeds is one of the indications of the completeness With which the hearth is being freed of smelting products. During cast iron output, especially on a large furnace, the moo meld Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 evidences a local cooling of the hearth, remains unnoticed, just the same as the beginning of important cooling of the hearth. For the prevention and timely liquidation of possiblo coolings and for the maintenance of a more stable heat state of the hearth it is necessary to keep up constantly a greater heat in the central part of the hearth and to heat the hearth from tuyere to tuyere evenly, by means of selecting the cor- responding systems of loading and operating duty of the ro- tating charge distributor, as well as to equip the blast- furnaceswith instruments for the automatic measurement and recording of the temperature of cast iron and slag in the run of the output. 5. Control of the Scouring of the Lining of Blaet-Furnao At a number of plants the methods of radioactive inserts and of radioactive sondage are used for controlling the wear of lining of the hearth bottom and of i;he shaft of blast- furnaces, in order to investigate the strength (resistance to wear) of refractories and select a rational design of the blast-furnace. By the utilization of radioactive indicators quantitativ data on the wear of a definite layer of shaft lining of a blast-furnaoe can be otained and the time required fo.T th destruction of the given layer determined. The use of radioactive isotopes in the study of the wear of blast-furnace hearth bottom linings led to the mastery of the dynamics of wear and permitted to set up a rational ehapo of the hearth bottom. Hearth bottoms, which are cylindrical in form and have coolers along the periphery of the lower part, have the gre, test strength. Hearth bottoms having the shape of a trunca- Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 tod cone offer less favourable conditions for cooling and got destroyed quicker. It was found advisable to use radioactiv? bsotopes for the control of scouring of blastmfurnaoe h arth bottoms in those oases when the hearth bottom installed is Of % now design. Lately such an investigation was conducted at the Ilich plants where the hearth bottom was made of a high- strength high?aluminous brick. Preliminary results indicate that such a hearth bottom is stronger than a chamotto hearth bottom. Due to the data of this work Design Offices have provided stronger hearth bottoms. II. STEEL SI LTING 1. The Study of the kbsorptiOn of Su1.phur Out of Gasous Fuel in Sweltin Steel ii-r Op n-Hearth Furnaces At the Stalinsk Iron and Steel Plant the mined coke and blast?furnaoo gas, used in heating the Open-Hearth furnacesfl has before the headpiece from 5 to 8 g of sulphur per cu mg while before it enters the head ? about 0.8 g of sulphur per ou m, In the process of smelting the sulphur is from its gasG? our phase partially transformed into metal n due to which its concentration in finished steel is raised. Below are preeentodm a description of the method of deter- urination of tho amounts of sulphaarfl which pass from the gas into the charge in smelting in open-Hearth furnaces at the Stalinsk Plant, and of the results obtained by it. The method is based on the determination of the weight of liquid metal and liquid slag in the furnace in the process of smelting and upon a subsequent preparation of a material balance, by sulphurs with the utilimation of the data of chcmioal 1?'9 -wan o n{? oammnl rdaA of both metal and slag. Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 The weight of both d slag is date eta fined by tho method of Isotope Dilution. In experimental melts a radicactiro cobalt in a non-metallic state was introduced, to an aaouit of 0.1 m Cu per ton of metal, into liquid cast iron befoxo it is poured into the Openmfearth furnace. In the prooeM of smelting metal samples were selected in the furnaao and urod Into the cast iron would. Cylindrical, ingots oo obtained aero placed In the contra of a protecting chamber, along whose of oumference 12 gas counters were arranged. As the melting went on the radioactivity of metal samples kept on decreasing due to the increase of the amount of metal in melting scrap. The weight of the total amount of liquid metal in t Nt in the furnace at the time instant t was calculated from the results of measurements of ingot radioactivity by means of the following equatio n00 io where t No m is the weight of the liquid cast iro furnace, in tons; io - is the speed of counting fro in imp/min.g.; poured into the a sample of that cast iron, i$ a is the speed of counting from a sample of metal selected out of the furnace in a ti e instant t, imp/min.g. The changa of weight of liquid metal in the run of one of the experimental melts is shosn graphically on Fig. 9. For the determination of the weight of liquid slag In the furnace radioactive calcium was used; it was placed into petal cartridges as CaO and arranged on the surface of solid cage materials on the bottom of the Open BIoarth before cast s poured. The CaP content in the final slag was 7 m Cu per ton. Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 As the melting went on slag samples were taken. The measu- rements of calcium radioactivity in slag samples, together with the calculation of the weight of the wetted slag, per t- ted to determine the weight of liquid slag in the furnace in the process of smelting. On Figs 10 on ooordinates counting speed ? time is given the curve of dilution of radiooaloium in slag in one of the experimental melts. In all test melts slag was weighed after the melt was completed and the ingot weight determined. That permitted to correct results of radioactivity measurements. The totality of experimental data on radioactivity and of the results of the chemical analysis of all samples of metal and slag for sulphur content permitted to make up balance sheets of melts for that element. Thus, the amount of sulphur, which went over from the fuel into the charge, can be determined as the diffe- rence between the actual weight of sulphur in the metal-slag system and the weight of sulphur carried into the furnace along with charge materials. 12 melts have been investigated by the method described. It was found that during the periods of heaping up, warming and pouring cast iron the open-hearth bath consumes on the average about 3 kg of sulphur per hour, or approximately 11 kg during that entire period. Met makes up approximately 15% of the total weight of sulphur in the metal-slag syste During the melting period the bath consumes so of sulphur, the amounts oonsu the sulphur content in the ewMt mor ed increasing with the growth of ixed coke and blast-furnace gas. The results of oaloulations indicate that during the pe- riod of metlink. the mat1.. nn An awranv-ova_ 41 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 of sulphur from the fuel, while in the period of final ing about 105 kg of olt? eulphug passes over from the etal into the slag. In all during the melt from fuel into etoel passes over about 20 of sulphur, which is appg? RS? tely 0.01%. Usually in melts made under conditions as described ebcv? the ready metal has a sulphur content of 0?04"0 Thus9 on the average, approximately one third of that amount is the oomponcnt that eats into steal from the fuel. However, if we turn from average values to the consideration of individual, olts, then we will note that in some oases during the period of final malting there is observed a considerable decrease of the sulphur content in the metal. Soft in one of the test site in this period about 13 kg of 'o sulphur was re- moved from the steel, i.e., almost 0.010 The result obtained indicates that there is a possibility to considerably lover the steel sulphur content by means of bettering the slag regime. It was found that the greatest negative effect upon the process of desulphuratiorq is produced by the slag silica content, the silica entering the slag from the ore charged into the furnace. In that connection the Stalinsk Plant intro- duced the practice of changing a part of the ore by cinderss which contain no silica. Such a modification of the teohnology ensures a substantial lowering of the metal sulphur content and a lessening of the duration of melts. At the present time operitione9 in W. ',Oh the weight of liquid steel in the furnace has to be de'ermined, are carried out by the aitilimation of radioactive ruthenium in place of radioeobalt. In that deter ination the intensity of radiation of metal samples is measured by means of a soi Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4 tillation counter, which permits to decrease more than gn order the concentration of the radioactive isotope in the Metal. 2. The Studer of S1Ca rormatlon in Saslting steel in Open -Hearth Furnaces The "Asovstal" Iron and Steel Plant processes cast iron with a high phosphorus contont o Therefore 9 tho rationaliastion of the Open-Hearth furnace slag regime is of especial intGreet to it, in Oder to most effectively dephosphorlse the petal, s well as to obtain slags with a high content of phosphorus pentoxide, used as agricultural fertiliser. In the open?h@arth shop a technology was specified, by which in the furnace, after the ready steel is let out, somo ount of slag is left. That ease tre ie aimed to fasoilitato the foreation of slag during the welting period in the next elt. The optimal conditions for the utiliMation Of such t slag were worked out by means of the method of radioactive isotopes. To the slag, which was left in the furnace, radioao- tive sulphur rims added, and then, as the prooese of melting was being carried on, slag samples were tckeno By the results of measurements of the radioactivity of these samples it was established that the earlier the slam which was left over in the furnace, begins to melt, the more suooessfml is the flow of the dephosphorization process. In this co 91c4, which is seed from the furnace in the final period of bath refining, may again be need in subsequent melts as a slag fore ng osterial. In thin ease the slag, which prvioisly d=P@d on the hsap9 now beoo es a circulating material, & percito to educe the oonsu ntioln n? '21M ,fn4-,,M- ft-a Approved For Release 2009/04/29: CIA-RDP80T00246A007900090002-4s Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 the use of such a formed slag should fascilitate the melting of ore and limestone charged into the furnace and, therefore, should better the conditions of dephosphorization of metal during the.initial period of melti Below are described tests on Open Hearth furnaces of the 'Azovstal" Iron and Steel Plant, in which the speed of molting of the circulating slag and its effect upon the run of melting were determined. For that purpose the circulating slag was traced with radioactive phosphorus. From 30 to 40 mutes before the last polished slag was skimmed, into the metal bath have been introduced a few grams of iron phosphide enriched P32. In the interval up to the and of the melt radio- phosphorus was oxidized and was uniformly spread in the liquid slag volume. When poured out of the furnace the slag was subjected to crushing in the ram engine shop to sizes of 30- 100 mm and was then used in melts. The amount of this slag, which was charged into the furnace, was from 1.3 to 40 by weight of the metallic part of the charge. The judgment of the speed of melting of the solid slag was made by the radioactivity of slag samples, which were taken from the furnace in the process of melting. Tests have shown that the first samples of slag, taken directly after the pouring of cast iron, were characterized by a maximal radioactivity. That can be illustrated on Fig. 11, on which is given a curve indicating the variation of radioactivity of slag samples with the run of the melting. From an analysis of this Fig. it follows that the circulating slag almost entirely passes into the liquid state directly after the pouring of the cast iron into the furnace. Thus, an analysis of the above mentioned tests shows that the use of circula- Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 ting slag should lead to the contraction of the duration of melting. A comparison of melts made by the usual and by the new technology corroborated that assertion. It showed that in the last case on the average the duration of melts has been lessened considerably. Taking into account the lessening si- multaneously of the consumption of limestone, it may be con- sidered that the new technology possesses important economic advantages. At the present time it is being mastered by the plant. 3. The Effect of the Quantity of Slay Upon the Quality of Steel in the Period of Pure Boiling At the "Azovstal" Iron and Steel Plant the radioactive isotope of phosphorus was also utilized for the determination of the weight of slag in an open-hearth furnace in the period of pure boiling, Radlophosphorus was introduced into the furnace in the middle of that period. The weight of slag was determined by the measurement of the radioactivity of its samples. Tests have shown that the flow of processes of steel melts and the quality of the ready metal both depend upon the quantity of slag in the furnace. So, Fig, 12 shows that the speed of oxidation of carbon, when all other conditions are the same, Is a maximum for mean quantities, of slag com- prising about 60 of the weight of the metal. Both for greater and for smaller quantities of slag the oxidation is retarded. It is interesting to note that with such an optimal quantity of slag in the furnace there also is observed a maxi- mal speed in the heating of the metal and a highest output of steel of the first class. That can be illustrated by Fig. 139 on which the output of first class rails is shown to be a func? tion of the weight of slag in the furnace Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Conclusions The examples presented in the report indicate the effect- iveness of the utilization of radioactive isotopes in the so- lution of technological problems of metallurgical production. The further advance of wor on the utilization of the attainments of nuclear physics for the benefit of metallurgy will, seemingly9 to a considerable degree depend upon the r suite of the activities of scientists and engineers in the field of physics of the isotopy of elements and of nuclear radiation, as well as the achievements in the design of radio- metric apparatus and of individual nuclear physics installa tions.Here should, in the first place, be named such questions as the availability of radioactive and stable isotopes of a series of light elements, which can be handled conveniently, the design of high-sensitive portable radiometric apparatus which will make possible to conduct measurements on a wide range of temperatures, the creation of small-size powerful neutron sources. With greater intensity should the development of questions connected with radiation safety in working with isotopes and radiation, under conditions of industrial produc- tion, be continued. Exchanges of experiences obtained in various countries on the above-indicated questions of applied uclear physics may suostantially accelerate the advance of this field of science and technique. Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Approved For Release 2009/04/29: CIA-RDP80T00246AO07900090002-4 Fi . . Distance from ra11, Fi . 6. 1) Horizons; 2) To tuyere No. 8; 3) To tuy r No. 9; 4) To tuyere No. 8; To horizons I-V Fi o 1) Radioactivity of cast iro tests, 00; 2) Weight of cast iron melt, 0. E . 1) Scrap smelting melt No. 316l; 2) Weight in tons; 3) Time in minutes. Li .10. 1) Melt No. 3149; 2) Dilution Ca43; 2) Im n. 0 3) Time, rain. IMP. Fem. 1) a 2) Time, hour- 3) Pouring I II III cast iron in; F ?12? 1) 0 - rail stool X - loci carbon atecla 2) Speed of b rninj of oarbon, 0 Cmin.; 3) Pero?nt of 0184 fro weight of met&lo Fi 130 1) Percent of first clasp rails; 2) Percent of slag from weight of metal. 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