SCIENTIFIC ABSTRACT VNUKOV, A.K. - VOBECKY, J.

VIMKOV, A.K.. kand.tekhn.nauk Leak,z in comWstion chambers, their influence on the operation of boilers and simple control methods. Teploenergetik-a 7 n0-3:44-48 Mr 160. (WRA 13:5) 1. Yuzhnoye otdeleniye Gov-,udarstvennogi) tresta po organizateii i ratsionalizataii elektrostantair. (Boilers)  SO-1/96-59-7-5/26 AUTHORS: Vnukov.-A,K. Candida-e of Technical Science,- and Engineer. TITLE: The Aut-omatic Control of Drum-type Ball Mills According to the Level of the Fuel in the rTlim (Avtomatizatsiya sharovykh barabannykh mel-nits po urovnyu to,)Iiva v barabane) PERIODICALt Teploenergetika, 1959, Xr 7, pp 1.9-21 (USSR) ABSTRACT: During the last year and a half many stations in the south of the country burning anthracite fines have intro- duced control of the loading of ball mills according to the level of fuel in the mill. Good results have been obtainedeven though the actual concept of fuel level is The word Ilevel^ is used on the ob s cu re. assumption that the milled fuel is in the lower part of the drum and behaves as a liquid. This concept has been used to explain the operation of the signalling devices, such as those illustrated in Figure 1, in the follo-wing way: two tubes through which air is blown are connected together externally by a differential pressure gauge. Card 1/6 Inside the mill the lower tube is at a certain dePth balow  S071915- 59-7-5/26 The Automatic Control of Driim-type Ball Wills According to the Level of the Fuel in thi.~- Driiia the level of fuel and the upper tube is in thhe air, The air in the !owe-,- t-%be has to overeome the resistance of the fuel layer and the magnitude of this re-oistance .,..s proportional to the depth of iiamersion. Instead' of pump- ingthe air in from outside it may be -induced by lowe~r.-1.njg the pressure in the mill., This induc-tion method was used 11 4- in studying t'-qe levei in a mi type Sh-16 millAing Donets anthracite fknes,, During 'he test the mill operated wi-th a 28-ton load of balls, and the fuel residue on an 83-mesh sieve was 7 to 9%. The' mill output could nct be measured, but the fuel level in the mill was maintained constant by automatic control. During the tes't, the upper tube remained fixed and different lower tubes were used so that the pressure-difference field could be measured in a number of places. The partial vacuum in the mill air-duct was 180 - 200 mm. water; the pressure drops obscrved at different places on the section of the mill about 150 mir, from the end of the drum are shown in Figure 2. A cuin~re Card 2/6 of pressure increase along the vertical diameter of the  SOVI'-i6 - t) '-'J-7 --- 5/26 The Automatic Control of Dr-,,im- Lype fial.11- Mil lo A7~,,cord ji-ng t,(-, Level of the Fuel in the Dr,~!-z drum is showta in Flgure Abi-ive- fu-l levt~l the pressure drop is practically arlid ljolow tbe lovel the pressure drop ir,.:~reases rapidly 'Vo 1.00 auu viciter. Although t1he assumption thr~t tbe fuel --'s a liquid satisfao'L---,rily explains the upe~cation of tht-. di-l-vi.ce- ill- ustxated iii Figux-e i. it was founi th.,?.-t the device con--- tinued to operate if the holes used to supply air to the tubes were stopped up. In order to investigate this question furtber, two tubes were intrDduced into the drum and differential pressure gauges connected belween them, as shown in Figure 4. The mill was emptied before -rhe test and at the sta--t- of the tes" the rate of --oal delivery was sharply inc:raased. As the 1---ad in the dn.4m inc--reased the partial vacuum in the lower tube steadily dropped to zero and af ter about 38 minutes theare was a pressure difference of 110 mm water. The process of pressur- increase was fo'Llowed until there were signs that the M.J.11 was becoming overloaded, it will be seen from the results Card 3/6 plotted in Y�gV,-,r--e 4 tha'j thE; pt--irtial var.%uum beyend the  so -- 5 q.- 7 _:V2~; The Automatic Control of R.,.,um-type ba.11 Mill's A~Iccrdirg tc the Level of the Fuel in The R-t;c_ m -1. ill measured 'Lln thp- way ~raried little an-A was about 190 mm wat--r. in -opper tiibe allso r1jan"r-red 1-i-TI-t-le, and was 2.2() um waT-er. 'fwG explarva~ions rf tKe fa,~tq aTe ossL _- . If' the fj.lel. behaves a,~j a liquid j.. may bp Jbir p su-oDosed thot the -dust penetrates i -nto the vertical -rja,-:-t.- of the lower tub? and e~cmpresses Qie air in it. An r; t h e r explanatic-n --*.s that the pl,essure-drop refle!-,-ts ';he a,-tua_- L air-pressure con,~it--ioiis withIn tvhe di-um,, -by Tput-ting a porous barri,-.!r J.'n ttie end of the- JC.W~_r 4 ube to prevent ingress of fuel JI-c- was shcwn tlk.~~t the fi-rsr, explanation does not 11-jid. The ~7iir-oressure distribu-~ioil in the Iru-rq can be explai-ned as follOws. AB the fuel and balis the fuel is thl-o,~m. to ~Ithie f,,:,.r side uf the. balls., as- shown in Figure 2. As t1he f,_,el falls back, the upper layers of fuel/air mixture compress the lower ones, ac, causing 4Fhe observed pressur,~. dist:vlbution. Ai:,.~ r;-reqsure j.S ajSj-, Se4.~ Card 4/6 up by rezarrda-i~,r. of fuel. particles and their mo-vemen-11 relata.ve to the As -the quant.-Ity of fued in tbe &rum  SO - 5'~';4_7 - 5126 The Automatic Control of Drum-ty-pe Ball 14-ill's According- to the Level of the Fuel in the Drim increases, the 'pressure starts to rise in the upper tuber In this case the pressure, idifference between tirie upper and lower tubes becomes almost constant, and does not de- pend on the air conditions in the dnuit, It; will be seer-, from Figure 4 th,-t ci~ianges in the ventilation ~f the mill had little effect on the i)ressure drop between the tubes. The effect is comDared wilh the useful, head during the circulation of a steam-water emulsion. In any case. there is a sim-Dle relation between the quantity of fuel in the drum and the p ressure drop between the tubes, villich provides a very convenient signal of fuel level, The best value of pressure-drop to be maintained should ~e determined from mill output tests. A mill automc,.tion !-~rran-cment based on this device was used nt a southern -oower station, A schema-tic dir~gram of -the equipipent is shown in Figure 5. The tubes are 16 mm diameter and are suppGrted at the point of entry int-o the drum; it is found thal they dc. not become blocked, presumably because they vibrate. This scheme has a number of advantages over previous ones; in particular Card 9./6  S Q V/0 r, -5 0 - 72 6 The Automatic Control of Drum-type Ball Mflls Accord-ing to the Level of the Fuel in the Drcm it is not necessary 'to maintain a constant, partial v-.---,- uum in the mill and the fuel load can be controlled over a very wide range. There are 5 figures and 2 Soviet references. ASSOCIATIOM. Yuzhno e otdeleniye ORGRES (Thtl~ Southcr-.a Division of ORGREST Card 6/6  VNUKOVq A.K., Cand Tech Sci -- (diss) "Certain 4~k,~M3-= the LIvov firing of high pressure cylindrical boilers" - Jd-v-WPY1957. 17 Pp I k-,de k e ~- with 22 cm (Min of Higher Education USSR. Mos Order of Lenin Power Engineering Inst in~(iiolotov). 100 copies (KL, 9-57, 101)  AID P 2038 Subject USSR/Engineering Card 1/1 Pub. 110-a - 11/14 Author ; Vnukov, A. K., Eng. Title : Experiments with the ignition of high-pressure boilers Periodical : Teploenergetika, 4, 54-57, Ap 1955 Abstract : The article describes experiments made with the firing of high-pressure boilers of two different designs. The main factors which determine the distribution and variation of temperature in boilers were investigated. The author reports some observations on the uneven heating of watertubes and drums and recommends complete and early valire opening before commencement of ignition. Six diagrams.' Institution: None Submitted : No date  VNUKOV, A.K., kand. takhn. nauk - - Electric radiometer as an instrument for determining the therml flow of radiant energy. Torploenergetike 5 no. 8:91-92 158s ~MIRA 11:8) (Radiometer)  AUTHOR: jnukov, A.K. (Cand,. Tech - Sci.) SOV/90-58-10-0/25 TITIZa Temperature conditions and thermal stresses in high-pressure boiler drums during normal and accelerated shut-down.(Temperaturnyy rezhim i termicheskiye napryazheniya v barabanaldi kotlov vysokogo davleniya pri obychnoy i uskorennoy ostanovke) PEELIODICALs. Teploenergetika, 1958, No.10. pp. 23-25 (USSR) ABSTRACT-. When a boiler cools down, heat exchange takes place between the walls of the drum, the surrounding atmosphere, and the substance filling the drum. The drum cools most rapidly from within. A cooling curve for the drum walls of a boiler type TP-230 is given in Fig.li the theoretical curve (1) is calenlatea by equation 2. The experimental curve (2) shows that cooling is actually four or five times more rapid than indicated by -curve (1). Uence, external cooling of the drum is of secondary importance and internal cooling predominates. This question is then considered in more detail. After disconnecting the boiler superheater, blow-down, is coutinued for up to an hour, or even longer during accelerated shut-down., During this time, the boiler operates as a heat accumulator, so that the whole mass of water is cooled as the pressure falls. During a normal shut-down, the drum continues to deliver steam, Yehich is condensed in the superheater tubes. Temperature changes of various points on the small and large drums of a boiler type TP-230 during shut-down are plotted in Fig.2. Typical Card 1/2 curves of temperature aifference along the length of the drum, and . . . . . . . . . .  SOV~96-51-10-6d,25 Tepperature conditions and thermal stresses in high-pressure be ler rums uring normal and accelerated s1hut-down. round the perimeter, are -,iven in Fitgps~ 3. & 4. r3spedtively. It is sitown that, during noimal cooling, temperature differences in the most massive part of the drum are not more than 200C, and the corresponding thermal stresses are uefrligible, Tests of rapid shut-down, with increased output of steam to ensure cooling, show that temperature differences of 80 - 1000C can arise in the salty sections of the boiler (See The corresponding stress conditions in the drum are estimiatea and the obange in -the maximum temperature difference during cooling is -.-aphed in Fig,O~ The cooling, stresses are greatest only after the internal pressure stresses have 1jeeome much reduced and, therefore, the total stresa is not ex-~essive. It is concluded that the cooling time of drum-type boilers could be out to 5 - 6 hours without risk to -ths (irum~ Tlis_-e ar!~ 6 figures and I Soviet reference,' ASSOCIATIONs Southern DivirAoli of OJIGRES kYv_z'Lroy-,, O'idelenive ORGRES) Card 2/2  sov/96-50-C-10/22 0 ~' / AUTHOR: Vilukov, 41. K. (%Candidr~ 'Go o.-L' Scic.".C5 TITIZ: An "lectrie-zad omoter all Ins,rumont for determinina the Thermal Flow of Radiant Bnor.-y (Elcktricheskiy radiometur pribor dlya o--)redoleniya to,.)lovoclo potoka luchistoy PERIODIC'AL: Toploenor[;etika; 1958, 1Tr 8, pp 91-92 (USSR) ABSTRACT; In tests on furnaces and radiant heating-surfaces, measurements of intensity of heat flow are usually iaade by means of water calorimeters. A, water supply is required and the me--hod of measurement is rather compli- U cated. A platinum-plate radiometer is somewhat simpler to use but also requires cooling water and periodic calibration. This article describes an instrument free from these defects; its oDeration is based on an equation of radiant-heat exlcl-ianse, that is given. There is a fairly wide tomporature range within which the temperature of the heatod body has practically no influence on trio heat flow. An equation is then written for the rate of temperature rise of a small thin plate insulated on one side. Tile equation used in the design of the instrument Card. 1/3 is based on these two formulae. Experimental curves of  sov/96-58-8--,,9/22 An Elec tric-radi ome ter - an Instrument- for determinin,2" t-h-O 'Ther Flow of Radiant Energy the temperature of the heated plate and the rate of change of temperature as functions of time are given in Fig 2. To make a measurement2 the instrument, which has previously been cooled, is rapidly placed in the furnace or flue and the time required for the gaivanometer needle to cover a Certain tomucra.ture range is noted. The heat flux is then calculated from the design formula. The heated element is in the forn of a disc insulated at the back and edges. A form of compensating guard plate is used, as illustrated in Fig and there are radial compensating rings, as shown in Fig A sectioned diagrain with dimen3ions is aiven in Fig 5. The particular instrument illustrated was intended for measuremento of the thermal loading of furnace Card 2/3  sov/96-58-8-19/22 An Electric-radiometer - an Instrument for determining the Thermal Flow of Radiant Energy screens* Special calculationg have shown that, with a thermal flux of 100,000 kcal/ml-tir, the total error of the instrument including the galvanometer does not exceed 3.5%7 which is very satisfactory. There are 5 fioures7 no literature references. a 1. Radiometers--Design 2. Radi8meters--Performance 3. Thermal radiationr-I-Meas-arement 4. Mathematics--Applications Card 3/3  WRIKOV, A.K.,--kand. tekhn. nauk Increase in the heat-releaee rate of gas and mazut furnaces. Energ. i elektrotekh. prom. no.1:5-8 Ja-Mr'64. (MIRA 17:5)  VNUKOV, A.K., kand. takhn. nauk; SINTAK3VICH, B.G., inzh.; CUBAN, 0.1., inzh. Heat loss due to external cooling of high and very high capacity units. Toploonergetika 5 no.4:94-95 AP '58. (MM 11:5) (Boilers) (Steam turbines)  V/V v /~-r- V 91-58-7-6/27 AUT';MS: Dutikov, S.S.; Shevelev, A.A.; Vaytsman, V.M., Engineers and Vn Candidate of Technical Sciences TITLE: Exchange of Experience(Obmen opytom). The Automated Oper- ation of Mills(Avtornatizatsiya raboty mellnits). PERIODICLL: Energetik, 1958, Nr 7, pp 19-20 (USSR). ABSTRACT: In 1957, 5 drum ball mills (4 mills of 'Sh-16" type and I biconical mill of "ShK-25" type) were automated according to the design suggested by Yuzhnoye otdeleniye ORGRES (the "ORGRES" South Branch Office). The following equipment was utilized: electronic controllers of "ER-III" type on 2 mills and electomechanical direct feedback columns of the "Energodetall " plant on 3 mills. Their structural details and operation are described. Tile first experimental ser- vice of this automated system proved its operational stabil- ity and wide control range, as well as easy maintenance, The various requirements to be met for automating mills, Card 1/2 such as good dust system, continuous aeration etc. are  Exchange of Experience 91-58-7-6/27 outlined. The "dust level" automation of mills must gua- rantee a decrease in consumption of electric energy for the preparation of pulverized coal by 3 to 4 kwh per ton of milling. There are 2 diagrams. 1. Ball mills--Operation 2. Ball mills--Electronic controls Card 2/2  DUTIKOV, S.S., inzh.; STUMBIXIV, A.A., inzh.: VATTSYMI, V.M., inzh.; VNUKOV, A.K., kand.tekhn.nauk Automatic control of ball nil! operation. Enargetik 6 no.7: 19-20 JI 158. (MA 11:10) (Pulveripars) (Automntle control)  - --- --- - - V-AYTS14AN-,-V - 1-1.-inzh.; VNUKOV, A.K.,kand.tekhn.TLquk; MARKO, V.P.,inzh. ... Automation of the chnrging of fuel into bell wills. Zlek.stn.29 no-3:85 Mr 158. (MLRA 11;5) (Pulverizers)  06-4-24/24 AUTHORS: Vnukov, A.K., Cand.Tcch.Sc., Sinyahevich, D.G., En-ineer -7JTHU-Gl-,~an,~O. I. , Encineer. TITLE: Theriual-lossev resultin!, from external coolin- of sets working at high and super-hie., steam conditions. (Teplovyye poteri ot naxuzhnogo okhlazhdeniya blokov -so- , , parai:ietrov). vysokilh i sverkhv~ -ilt 0 1'io.'[jpp.04-95- (USSR). PERIODICAL: Teplooner etilka, 195,31 ABSTRACT: In 1057 the Southern Division of ORGREI:.S tested the ther-,qal insulation of a hiUIa-pr~~ssure set in the Pridneprovsk re--ional po,.,.,er station and of a super-hiEh-prescure set in the Cherepetsh Power Station. Measurements viere made of the theiimal losses throur:h the insulation and of the distribution of the losses between sets and equipmaent. Therialal losses fro-m particular parts of the sets are tabulated. In the hiLh-pressure unit, 1,26% of the total heat was pazLin,~ throu~;h the insulation, and in th,_- super- hi--h-pre, s cure sets 1.4Wo. Not all this heat ic, wasted belau.~-,e sofae returns to the boiler aith the air blast. About 80% of the losses occur in the boiler-house. The losses are greater in the super-high-pressiu~e set because the temperature is hiGher and the pipin- is lonGer. Card 1/2 Considerable thermal losses occur throu,.-h uninsulated U  06-4-24 24 Thermal-losc-c-I rcf,ultin- ftom external coolinc; of -~e"i~, in at hi,Sh and supei-hich steaia conditions. parts of fittinLs. These form about a quarter of all the thermal losses. ShroudinG the insulation vi-ituh aluminiib-n sheet Sives a small reduction in the heat loss. There is 1 table. AVAILIULIE: Library of Congress. Card 2/2  VOKOV, A*K*, kand, telchn, nauk, T. Review of L.B. Krol's book "Characteristics of the high-pressure boiler installation." A.K. Tnukov..Bnergetik 6 no.2:39-40 F t58. (Boilf9re) (MIRA 11:1) (Krol, L.B,) .  VNUKOV. A.K., inzh.; YAKUBENKO, A.A., inzh. - - "swap--"" - Drying boiler linings. Xlek.sta. 29 no.1:89 Ja 158. (MIRA 11:2) (Boilers--Dr7ing) I  VMOV,,A.K., knndidat tekhnicheskikh nauk. Performance of metal in wall-tYpe radiation eteam superheatere. Toploonergettka 4 no.g.-45-48 S '57. (HLp-A 10:8) 1. TuzhORGRS. (Svnerheaters)  SOV/91-58-2-31/31 AUTHOR: Vnukov, A.K., Cand.of Techn. Sciences TITLE: A Review of the Book by L.B. Kroll "Characteristics of High-Pressure Boiler Sets", ublished by the Gosenergoizdat, 1957 etsenziya na knigg L.B. Krolya "Osobennosti R kotefnykh agregatov vysokogo davleniya", Gosenergoizdat, 1957 g) PERIODICAL: Energetik, 1958, Nr 2, p 39-40 (USSR) ABSTRACT: The above mentioned book is reviewed. C-a-rd 1/1  -VMMOV, SIITDMVICH, B.O.,iazh.; CHLBAH, 0.1.,Inzh. Investigiting heat losses to naieboriag nedia in electric power plants equipped with high- and superhigtL-pregaure traits. glek. eta. 29 no.11:19-22 IT 158. (MIRA 11:12) (Electric power plants)  I  \' .,/ \' '-, ~ - C '.~ IT-A i %- . AUTHORS: -yarema,-S Ya. (Eng.) and V A.K. (Eng.) 256 nukov, (Southern Division of ORGRES).- TITLE: On the question of the strength of boiler drums during starting and stopping. (K voprosu prochnosti barabanov kotlov pri puske i ostanovke). PERIODICAL: 11,Teploenergetikall (Thermal Power), Vol.4, No.4, April, 1957, pp. 33 - 36 (U.S.S.R.) ABSTRACT: According to existing standards in calculating the strength of boilers, temperature stresses that arise in the boiler walls during periods of starting up and shutting down are not taken into account. In operation the magnitude of the temperature stresses is limited by the permitted temperature differences. According to Soviet and some foreign standards the temperature difference betw8en any two points in the drum should not exceed 30 to 50 C. This article gives an evaluation of the magnitude of temperature stresses and their influence on the total stresses in the cylindrical part of the drum. Measurements carried out whilst steam was being raised in boilers showed that the temperature field on the outside of the drum can be represented by a simple diagram. The temperature of the walls above water level practically coincides with the saturation temperature of the steam with which they are in contact and is thus uniform over the entire surface. Starting at the water surface and below, the drum wall temperature decreases  256 On the question of the strength of boiler drum during starting and stopping. (Cont.) linearly and in the lower part of the drum the water temperature is again constant. This simplified diagram is shown to be in good agreement with practical measurements. Analysis of the solution of problems on temperature stresses in the cylindrical part of a drum shows that in the middle of the drum the normal stress acting in an axial direction preponderates over the tangential and radial stresses. A formula is given for this stress but it is applicable only to the middle part of the drum. The simplified diagram of the temperature field is then applied to this formula to give an evaluation of the normal stress which is plotted as a function of the position on the drum. Analysis of the equations shows that the maximum stresses occur at the inflection points in the temperature distribution and the corresponding values are substituted in the expression for the stress. The absolute values for the temperature stresses corresponding to measured temperature distributions are tabulated. In individual cases the stresses reach the aesi&ned values. The stress due to the internal steam pressure must be added to the internal temperature stress and an expression is obtained for their sum. Finally, an expression is derived for the permissible temperature difference between two points on  256 On the question of the strength of boiler drums during starting and stopping. (Cont.) the drum vrith a given conf iguration of temperature f*-i,-r-!-d and safety factor. The equation is solved and the results are plotted on a graph, iahich is applicable to the drum of a boiler TP-170. With a safety factor of 1.65 the safe temperSture difference at the commencement of firing may be 113 C. At the instant of connecting to the steam main (90 atm.) t~e temperature difference should not be greater than 85 C. With a safety factor of 1.11 the temperature difference at the start of firing is practically unlimited and. at the end should not exceed 148 C. The temperature difference of 50 C permitted in certain standards corresponds to a safety factor 1.93 at a pressure of 100 atm. and of 3.68 at a pressure of 10 atm. The calculated results were verified by tests on a model of a boiler drum which is described. The surface temperatures of the model were measured with thermocouples and the stresses by resistance strain gauges. The temperature distribution on the circumference of the model is plotted alongside a curve obtained on a high pressure boiler drum. The distribution of axial thermal stresses in the model are plotted, the normal stresses measured along an are in the middle part of the drum were quite small and are LLot shown in the graph. Results calculated from the  256 1 On the question of the strength of boiler drums during starting and stopping. (Cont.) temperature field of the model are plotted on the same graph. Good agreement is shown. 7 figures, 2 literature references (2 Russian).  VNUKOV, A.K., inshener; VOLKMA, Ye.l., inshener; PAVLIV, Yu.V., inzheaer. Measuring the temperatures in high-pressure boiler drams during firing. Znergetik 3 no.12:10-11 D 155. (KLRA 9:2) (Boilern)  VNUMV, A.L.,.Lnzhener* r Characteristics of a boiler installation equipped for rapid Istarting and shutting down. Teploonargatika 3 no.4:50-55 AP 156. WaA 9:6) l.Yuzhnoye otdeleniya Orgrom. (Boilers)  AID P - 4368 Subject USSR/Heat Engineering Card 1/1 Pub. 110-a - 13/19 Author Vnukov, A. K., Eng. Southern Branch of the Bureau for -the organization and Rationalization of Electric Power Plants and Networks. Title Some particular features In shaping boiler adjusted for quick starts and 6tops. Periodical : Teploenergetika, 4, 50-55, Ap 1956 Abstract ; The ways for quick firing and extinguishing the boiler are discussed. Recommendations are made for an improved design. Four diagrams. Institution : None Submitted ; No date  No ko V AID P - 2992 Subject USSR/Electricity Card 1/1 Pub. 29 - 7/28 Author VZ!Lkov, A. K., Eng. ~1"*W_W=MWW Title Prevention of deformation of the cooled panels of a chain-grate stocker Periodical Energetik, 6, 14-15, Je 1955 Abstract Deformation of panels was observed in several boilers. The author describes preventive methods. Two drawings. Institution : None Submitted : No date  AID F J699 Zubject USSR/Electricity Card 1/1 Pub. 29 - 4/25 Authors Vnukov, A. K., Ye. I. Volkova and Yu. V. Pavliv, Engs. Title Measuring the temperatures of drums of high pressure boilers during the firing Periodical : Energetik, 12, 10-11, D 1955 Abstract ; According to the circulars of the Technical Administration of the Ministry of Electric Power Stations 4/T52 and T1/54, the firing of high pressure boilers has to be done in such a way, that the temperature differences between the hotteut and 8oldest parts of the boiler drums do not exceed 30U to 50 C. The authors present a simplified method of measuring drum temperatures. Three drawings. Institution None Submitted No date  Wel,]Lng Flaurs in ;A.ace whure thermoalemeants are welded to pipes; Rab. euerg. 2 11o. 1, 1952. I List of Russian Accessions, Library of Congress, May 1952 9. L4onthl Uncl.  virjovj &- R. pipe 'lo. 1, Flaws in place where thermoelements are welded to ~Iipa3., Rab. energ., 2, 1 1952. 9. Monthl List of Russian Accessions, Library of Congress, I-lay 1952 iV~J, Uncl.  VNUKOIJ, Akt., kand.tekhti.nauk; PETS51101:, A.G., inzh.; PORGAYLO, K.M., inzh.; MIKSIMOV, A.I., inzh. Yethods for adjusting the furnaces of lar~-e boiler unit--. Elek. C sta. 32 no.11:10-13 N 161. (YIIRi~ 14:11) (Boilers) (Furnaces)  VOLKOVA, Ye.l.,, inzh.; KHIRIN, N.D. inzh.; BARYSHNIIKOV, A.P.-I inzh.; KOZHEVNIKOV, G.A., inzh.; ikxim, K.G., inzh.; BABKOV, V.A., inzh.; VNUKOV, A.K., kan Starting clutch for draft and blowing machinery and pit mills. Teploenergetika 8 no.6.-31-32 Je 161. (MIRA 14:10) ,a Yuzhnoye otdeleuiye Gosudarstvenhogo tresta po, organizataii i ratsionalizatsii elektrostantsiy. (Glutdhes (Machinery)) (Electric power planta-Equipment and Bupplies)  kand. te khn. nauk Rfficiency of burrdng rAzut. Elele.. sta. 34 no.5--R~-15 lIfy `63. 0,9RA 16:7) (Furnaces) (Mazut)  VM=v, N. Out dovn on the loss of work time. Sots.trid 4 no.11:136-137 N '59. (MIU 1):4) % 1. Starshly inzhener po trudu i zarabotnoy plate tresta "Sibstro7mekhanizatsi3ra" Mintransetroya SSSR. (Hours of labor) (Wages)  FEDIN, Ye.I., inzh.; VNV40v, P.K.', inzh. MsAanization and automatic control in industry Is the ymin road toward reducing labor consuming operations in reinforced conerete shipbuilding, Sudostroenie 28 no.1:59i-61 Ja 162. (MIRA 1617) Ships, Concrete) ipbuilding-Equipment and supplies) ft  VIIUKOV, Sergey Alekseyevich, inzh.. PERGAMENSHCHIROV, B.p red.; dkIW. red. [Mechanization and automation of industrial production; practice of enterprises of the Orel Economic Region] Me- khanizatsiia i avtomatizatsiia proizvodstva; Iz opyta predpriiatii Orlovskogo ekonomicheskogo achainistrativ- nogo raiona. Orel, Orlovskoe knizhnoe izd-vo~ 1960. 78 p. WILA 1?: 3)  U- - ____ - -_ -_ -_ ZAKHARIK' Ye.; USIKOV, N. [Oral economic region] Orlovskii ekonoiicheakii administrativnyi raion. Oral, Orlovskoe knizhnoe izd-vo, 1959. 78 p. (MIRA 13:8) (Orel Province--Economic conditions)  VMOV. V. D. ....... ....... Finishing worm-thread cutting. Stan.i instr. vol. 24 no.9:34 S '53. (KLR,i 6:10) (Spiral millirig)  OCHKIN. J.; GOROIZOV, N.I.; LOVTSOV, A.P.; VIXTOROVA, A.G.; SOKOLOVA, Ye.Ya.-, KOZLOV. A.N.-, BRYUCHIN,.Ji.P.. obahch-iy red. (Economy of Saratov Province; statistical collection] Narodnoe khoziaistvo Saratovskoi obleati; statisticheskil abornik. Saratov, Gos.statisticheskoe izd-vo, 1959. 205 P. (MIRA 12:11) 1. Saratov (Province) Statisticheskoye upravlaniye. 2. Nachallnik Statiaticheskogo upravleniya Sarstovskoy oblasti (for Dryuchin). (Saratov Province-Statistics)  VITUKOV, V.K. Gas branch pipe to the Cherkas:3y L-Iquid 11-wit. ll'=rciL. truboprov. 9 no.4:4-6 Ap 1611+0 WL-LA 17: 9) 1. Trest LPcrgazneftestray, Kiyev.  V14bKC-11, V.K. Inzh. Welding elongated sectiIns. Str2i. truboprw- 6 no.4:17 Ap 161. MRA 14:6) 1. Stroitellnyy uchastok - 12 tresta Ukrgazneftestroy, g. Baranovichi. (pipe lines-Welding)  V.K. ~bdel study of automatic control processes in irrigation systems. Izv.AN Kir.SSR.Ser.est.i tekh.n-auk 3 no.601-93 161. Off-RA 15:11) (Hydraulic models) (Automatic control) (Iriigation)  SOURCE CODE: Mt,10271/65/000/007/AO40/AO40 SOURCE: Ref. zh. Avtomatika, tolemekhanika i vychislitelinaya, tekhnika. Svodnyy tom, Abs. 7A291 AUTHOR: Vnukov~ V. K'. TITLE: Selecting some parameters of photoelectric funct!Wn generators CITED SOURCE: Sb. Avtomatiz. obltyektov irrigats. sistem.. Frunze, Ilim, 1964, 84-93 TOPIC TAGS: funation.generator, function generator desijP1 TRANSLATION: A universal function generator desigred with an electron-beam tube and a~photomultiplier is considered. The generator is intended for producing functions of any form. A filter at the photomultiplier output is uski for noise reduction. Operation of the system is analyzed. A total tracking orror is determined which is a sum of the desirable-signal error and the noise-causedl~ error (from the photomalti- plier). The desirable signal is regarded as a stationary random process; noise is assumed to be white. The filter time constant is determined on the basis of the specified mean-Bquare error and the noise signal* Bib 6, figs 4. SUB CODE: 09