THERMAL ELECTRIC POWER PLANTS OF THE U.S.S.R.

Document Type: 
Collection: 
Document Number (FOIA) /ESDN (CREST): 
CIA-RDP81-01043R001600080008-4
Release Decision: 
RIPPUB
Original Classification: 
K
Document Page Count: 
349
Document Creation Date: 
December 27, 2016
Document Release Date: 
February 25, 2013
Sequence Number: 
8
Case Number: 
Publication Date: 
September 1, 1957
Content Type: 
REPORT
File: 
AttachmentSize
PDF icon CIA-RDP81-01043R001600080008-4.pdf33.12 MB
Body: 
Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 STAT Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 VOW. RIXMIC mina nuns or U.S.S.R. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 r7-1- TABLE OF CONTENTS Volume I List of Plates Bibliography Preface Introduction Chapter I. General Layout of the Main Plant Building 9 Four Types of Design 11 Chapter II. Construction of the Main Power Plant Building 36 1. Building; Materials 36 2. A. Construction Treatient of the Power Plant Building 3j6 B. Construction of the Main Power Plant Building of the First Type Design 38 Structural Types 38" Wall Coverings 0 38 Roof Construction 38 Roof Coverings 38 Floor Construction 38 Crane Girders , 38 Overhead Bridge Cranes 38 Columns 39 Foundations 39 Bay Lengths 39 Frames Supporting the Smoke-elindnating Installations .11.o Construction of Some Main Power Plant Buildings of the First Type Design 40 Ivanovo ORES 140 Stalingrad,GRES - la ? ? Zuyevka ORES 41 Kuznetsk TETs Stelinogorak GREd 41 First Type Design p0oured-in-place Reinforced Concrete with Weldedf,Rigid Steel Skeletons 42 C. Stacks Brick Masonry Stacks Monolithia Reinforced ConcreteStacks ii - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ?-???f' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 D. Construction of the Main Power Plant Building of the W, Second Type Design 44 Structural Types 45 Reinforced Concrete Frames with Rigid Welded Steel Skeletons 45 Steel Frames 45 Wall Coverings 46 Roof Construction 46 Roof Coverings 46 Roofing 46 Floor Construction 46 Overhead Bridge Cranes 46 Reinforced Concrete Columns 47 Foundations 47 Stacks 47 Examples of the Second. Type Design 47 Nesvetay GRES 47 Stalinsk TETs 48 E. Construction of the Man Power Plant Building of the Third. Type Design 48 F. Construction of the Man Power Plant Building of the Fourth Type Design Steel Frame Construction Monolithic Reinforced Concrete Construction with Rigid Welded Steel Skeleton Reinforcement Precast Reinforced Concrete Construction Mixed Type Construction Examples of the Fourth Type Construction Appendix. "Principal Regulations Governing The Design of Electric Power Mantle Volume II Chapter //I. Some of the Principal Soviet Power Plants. Data and Photographs ii 48 49 50 51 57 59 60 90 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 k LIST OF KATES ? Plate No: 1 /MOW .04?1101.1...?111111.0 PaSe Iftp of Di.strict Electric Power Plants 5 2 Map of principal power plants at the end. of the lit Piatiletka 6 ; 3 Hap of Regional Power Plants in 3936 1 8 34, Capacity of Pagloi,u.1 Electric Power Plants in 1936 i 7 4, Fig. 3. Plan of Gorekly peat4iring GUS 14. i 4, Fig: 2 Plan of Mature. pe .firing CMS 1 14 1 I i 5 1k4brotyka peat-firing GRES: Sec:bion through thc rialii 'Wilding I 15 i 6 Shterovka MS. Plan of power plan' -t min building 17 t f I Shterovka ORES. Site plan I 16 6A x 1 i 1 I ivanoyO peat-firing GRESi; Plea and section .1 18 i 1 8 1 Model of a 5 x 50p30 kvi. pulveriitcd coal-firing 1 I ORES. SeC:tiOn ?.' .q. 39 i; at i Mcid.cl of a 200,006 kw: peat-firing power plant 1 20 Zuyevica ORES: Se4tion through the boilei house i ! and buidter station t 21 ; 9A 1 Zuyeyka ORES. SeCtion through the boiler house and, ,i ? , 1 ' fee*ater rizap ekaticin 22 , .t.. ? ) I+ ''- # 10 Stalingrad CMS: _Section through the main building 23 1 , , 3.1 ithsnetek TETo: Section through the main plant building 3.3A Kuznetsk TETs: Plan, of power plant Stalinogorsk CBES 4 Section th* 'tough the meta builditi8 . -1 Stalinogowsk MS: Drawing of the plant Neirietiky t3RES: Section through the itid.n balding lieisvetay GRES: Plan of payer Plant smain struCture Stalinak (240SEIDiRGO No U) =Ts in Moskva: 86640.4 throu8A t'll.! 3iiin, b141.444 / 9 1 iii Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Plate No. 15 15A 16 17A 17B (Fig.1-3) 18A (Fig.1-2) 1 22C (1'1g.1-4 23A Title Orsk TETs. Section through the main building Orsk TETs. Plan of the main building Page Cherenet, GEES. Section through the main building Cherepet' GRES. Plan of power plant main structure First Type power plant design. Section through the main building 33 I 32 35 65 Structural details of reinforced concrete frames shown on Plate 171k 1 66 Turbogenerator foundations of monolithic reinforced concrete Individual foundations. Turbogenerator and its auxiliary equipment foundations underneath the turbine hall Type of construction with abasement floor built on a monolithic reinforced concrete mat. Turbo- generator foundations underneath the turbine hall Stacks - brick and reinforced concrete Second Type power plant design. The load bearing monolithic reinforced concrete transverse frames Structural details of reinforced concrete frames shown on Plate 2QA Construction of the main power plant building of the Second Type. Design in steel Conversion tables for steel sections shown on plate 21A, Fig. 1 Construction of the main power plant building of the Fourth Type design in steel Conversion tables for steel sections shown on plate 22A, Fig, 1 Structural details of the steel frame principal joints in the main power plant 'building Construction of the main power plant building of the Fourth Type design in steel S. 67 68 69 70 71 72-75 77- 76 79 i 78 80 t5 82 iv Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Az+ , - ? Fourth Type Of poen' plant desifin two *methods of frame oconecti5a Construotiaa a i:4e. main payer -plant building of the Fourth Type design in monolithic reinforced 'Conarete vithlded rigid steel skeleton reinforce- ment qz1.4 straclural details Construction of,the mixt pOwer ?plent building a the Fourth TYPe':disign in precast -reinforced concrete and-it4tural detain., ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Itt 'az - _ Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? r Plate No. 1 . Title 2a4. Gorekiy GRES. One of the GRES buildings under construction 288 Go:01'1y GRES. Partial interior view of the turbine 280 - 29 ZOB 29c 30 300 30D 305' '4....mmar;u4roorier GorikLy GEES. Partial interior view of the turbine hall &shire, GM& Geral view of the boll= house and the open air ,substaticm, Kashira GRES. 7aur first section ,of the Kashira GRES ? &shire. GUS. Thi secOnd section of the Kashira MS under construction Nagbire, GRES. A 59)000 kw. turbpgenerator built by the "E3ektrosi1e." pleat iNshira ORES. Partial interior view of the turbine hen Itexhira GRES. Co*1 pulverizing. equipment Kaabira GRIM., Partial view of an outdoor substa... tion gezhiya GM. Partial view of'':thei 115 kw. out., door substation Kashlra GEMS. Shteravka Etterovka GRES. froia the south Shterovka GRES. Shterovks, Step...up transtrase.' r bank General view of the plant View of the main strtacture General view of the GPM 17'doi1isr room under ocestructica 81-ite.wv1-..a, GRES. The third eeetion of the plant under ecostruction Shteravka ORM Partial turbogenerator ,bail ate:orbs GRES. PartItal the generator hal ? ,2.1 interior liiev of the interior side view of "OWN. 107 108 109 111 112 113 Uk 325 116 119 421 11,271 No????01. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 30GI Shterovka ORES. Partial interior view of the turbine balls second section 31 Zwevka ORES. View of the ORES and wen-air substation 3111 Zuyevka ORES. General view 333 Zuyevica ORES. 130,000 km. turbogenerator at the partially' reoonstructed Wye**, GEMS 32 Ivanove (formerly Ivanovo-Vosnesensk) ORES. Side view of the Ilea :building, under colurtruction 324 Ivan,ovo (formerly Ivanovo.Vosnesenek) ORES. Construction vork at the ORES 303 ivauovo (formerly; Ivanovo-Vommisensk) ORES. Main structure in the advanced stage of construction 320 Ivanovo (ftammerlY Ivanovo-Voznesensk) ORES. ORES under construction 32D Ivenovo- (formerly Ivanovo-Vomnesenak) GEES. Side view . 32E Ivanovo (formerly Ivanovo-Vosnemenak) ORES. View of the main 'building and steel fuel delivery trestle 33 Stalinosorsk ORES. The (ES undex? construction 33k Stalinosorsk ORES. "Stalin" ORES under 1 3B construction 3 on Stalinogorsk GRES. Exterior view 330 I Stalinogorsk GEES. Exterior view 33D 1 Stelinogorsk Auxiliary Power Plant. General view 1 33E i 1 Stalinogorsk A4134417 Power Plont. Partial view of atudllary power plant 34 ' 1 Stalingrad ORES. Main building under constructi 34A Stalingrad ORES. Partial exterior view 1-----r-"-----943 Stalingrad. ORES. Exterior vim VU Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1 Stalingrad Tractor Plant Power Station. View of the boiler =OM 152 White Russian GRES. General view 154 White Russian ORES. The first section of the plant 155 35B Mite Russian GEES. Exterior view 56 35C White Russian ?kis. The ORES under construction 157 35D White Russian GRES, Partial View of the roof 158 35 Berezniki Ms., Boretniki TETs under construe:14u 160 , 36A Berezniki MT.. Partial exterior view of the t Ms serving the Berezniki Chemical. Works 181 , /, t36B Berezniki Ms. Exterior view of the the =a serving the Beressaiki Chemical Works 262 360 Bersniki Ms. Tuzilogenerator hcai. 163 37 ,,.?. -, SoMelnik GIS. Partial view from the eindotr of another building , 16$ Kuznetsk Mee Central power station at the bietallurgical Plant in the process of Construction 187 168 38D 39 39A 140 Magnitogorsk %!S. Aerial view) 'GES =der construction 1 176, Magi3itogorsk GES. GU under construction 3.77 ? Kuznetsk, Ma. Central power station at the bietallurgiOal Works Diznetsk Ms. Central power station at the Metallurgical Works &met& TRW. Partial View or the. TETs Kuznetsk TRW. - Partial view of the =Us shOwing the spray pond Chelyabinsk G. GRES usatler construction Chelyabinsk GlIES. General ?view of the first section nearing ocupletion 169 no 3,13 174 viii nprlassified in Part- Sanitized Copy Approved forRelease2013/02/25 CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Plate No. 100B 43. 4IA 42 43 43A 45 45A 45B 450 46 ,464, 1 45D 45E 4 477A 47B 48 50 Title Page Mmoitogorsk Partial (=tailor view 178 leramatorsk GE& Aerial view leo .Kratlatorsk GEE, Water cooling, towers 181 Kateravo Ma. Partial exterior view 183 Strerdlovsk TET. ':'.:Partiel exterior view of the TVs serving "Urelassbartroi" (t!re3. Machine Biiildlaag'WOrks) ' SV?rdlovsk TETs.- supply trestle 3esen to the bucker gallery Of the TETs Votoshilovsk GEO.. General vise' of the GES serving the VorosbilOV Metallurgical Plant 188 SeratOv ORES. The ORES under Construction 190 Saratov ORES. Ti* ORES under construction 191 Saratciv ORES. Partial Visa of GRES under construction 392 Seratov ORES. GUS =Wet conetruction 193 .? Saratov S. General view 194 Saratov GRES. Partial view Of the steam piping system 195 Yaroslavl' ORES. Bids view of the boiler house 397 Yaroslavl' Ws at the Rubber sad Asbestos Plant. Partial 'eXteriat *low ShOwing re1324. forced concrete .pee delivery trestle Baku "Knave *ads" GRE. qttle1131 view Baku "ItteAnckya Zvezda" GRES* Side view Baku "mare (104 Partial view of the plant and IDO" kw. copanair substance ? NavorOsolisk GRIM Front view, Voronezh ORES. Partial 'view of .the GRES and ?p.n.-air ? ficubstation Eaten' MO, Partial 'extoriar view ix 199 231 202 204 .2q8 210 Messamittsialasa, t t 41????????t. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? i? Plate No. 5CA 51 51e. 51A -533 51a 51D 53s 533 52 524 53 Title Kunio Te. Partial exterior view Maim:a TETs "Stelin". Genexvil view Moskva 2STs "Stalin". Partial view during eonotruetzion. 14aalma GE13 "axidavieh". General view libeksza. GE O "Seddavieh". Side View Mciakia GES nalaidoXieh". Exterior 'view a the bollsx? house 7 4rva GEO Nitaidevieh". ConatruatioN detail kbakva Ugh Preuinre TETs? General view ? -0 Elektivigorsk GEO "Mame. Side view Artee GR ES "KIROV4. Side view , ?. Artere. GEEp, ?WM". Side view-. , ' i.?, ? - .... Mironevskaya MES. Interior view of the turbine hall - 54 Slavyanak GRES. Paz?tial interfoi view of the turbine baLl r, 54A -Slavyanak GM& Partial interior view of the turbine hall 55 Cherepety GMS. 9enewal view 55A Chirezeti tatbine ho,11 14* Co4x, .55D 'partial interiur view of the z . Cherepets GEES. 'Turbine ban hoiusing a 150,000 kvt. 'turbine 211 22.3 224 216 217 218 219 221 223 225 226 228 2.33 231 233 234 235 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 luxthor BIBLIOGRAPHY Title: DLC Call No, Akademiya Arkititektury SSSR Antipov, I. P. Carr, T. R. Collective Study Collective Study toachenko, V. I. Ermakov, D. A. Flakserman, Yu. Flakserman, YU. N. Getf,f_ert, G. A. Glavelektro ClavnoYe Inektricheskoye Upravlenlye G3.azunov, A. A. Monographs, Arkhitektura pluoyablennykh sooxuz- heniN (Architecture of indnstrial Plants) 1956. Arkbitektura-elektrostansiy (Power Station Architecture), 1939, Power Station Civil Engtneering and. Building Works, Rugeley, Stafford- shire, 1944. Electric Power Development in the USSR, 1935. 15 Eiserne Schritte (Fifteen Iron Steps) Pe.rlin, 1932. Piatnadtsat' let leninskogo plena elektrifikatsii (Fifteen Years of the Lenin Electrification nen) 1936. Ojat eksploatatsii kashirskoy GRES Vashira GRES Operation Practice), 1956, Elektrifikatsiya SSSR (Electrifi- cation of USSR) 1931. glektrokhoziaystvo SSSR k nao.halu 1927-28 g. (Electrification of the USSR Toward the Beginning of 1927-28), 1928? Sta Power Stations 4-th ed. New York, 1952. Szbigani.ye antratsitr:ogo shtyba no. shterovskoy ORES (Calm Firing at the Shterovka GEES) 1929i Statistika elektricheskilth stantsiy SSSR 1922..1926. (USSR Per Station Statistics), 1927. Energeticheskiye systeray. (P. over Z3gineering Systeme..), 1952 xi 1m074634) 934581.A5 TH1151X34 71095Z6 ECK,6.163 TiOBS.D6 m286 .i? et85.F58 c85 .F6 T.3400430 1952 193 .R965 !1a193 ?A5 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Author (14sco3repha =it'd ta.0 Call X. Gosudarstvennaya Kanissiya Elektrifikatsii Rossii Kanenetakiy, N. 0. lftrkin, A. B. Flea Elektrifikataii 1SFSE6 2-n3. ed. 1955. Fervyyn russklye elektrostaatsil (First Rassiaa Electric Stations) 1951. Mmausbeheye elektrifikataii SSSR (The Future or Elektrification in the USSR) 1956. /4:1-nisterstvo Stroitel tits& Pavil 'you "Eaergeticheakoye liaektriostentaiy SSSR sfroitel'atve SEER" (Exhibition Pavilion "Power auxtneering Building in the USSR."), 1956. Paler Plant' Thal neering and 'belga, 2-rid ed. New Ycat, 1942. Pefos OsvoYen, (Pathos or Norse, F. T. NOSkovokoye Blum inzbenemv Oftoletko, K. Rabinovich, 14. Sherehov, S. V. Sisin, P. R. Streletskly, Ni So 7elezhnikov, V. E. Veytkov, F. liastering) 193l. Boyevoy marshrut elektrifikatsii (Tile Fightine Path a EtLectrifi- catica) 1933. Plan GOELRO i ego osuahebestvleniye (MIRO PI= and Its lalizations) 1952. 1ewinsko-stallnsks4a elektrifikatsi- Ya SSSR. (Leninist-Stalinst Filectri- ficatico a the U.S.S.R.), 195.1. evyt eksploatatsii zuyevskoy GPM (Zwievka GIES Operational Practice), 1954. Stalznye kaistruktaii (Steel Structures) 1952. FuzadaTenty-pod oborudovaniye elektrostentsly Mayk:12. iSZVer4k11. motthchnestey (Foundatiais for the Equipment a a2213. ona Capacity Power Stations.) 1936. Kok sozdavalas) elektrifikatalya strany sovetov (Bow the Electrifi- =taw of the Country of the Soviets Was Developed) 1947. xii 2095.1173, 3.955 m193 ?R9K3 M35.1-13 Tin, 93 ,B9t6 Ta3.91./494 3.942 Ta5.B9t6 =93.1003 u:85 .12 7.4c85 .$47 Ten93.B9S5 m6.11.575 uni4581.T4 Tic85 4/11rhs'. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Author (MbnograPhs cot') Walter, Writer, A. V. Wefts, V. I. Welts, V. I. Welts, V. I. Wats, V. I. Title: DLC Call NO. lto61 5. perapaktivy razvitiya sovetakay energetiki (Results of and. the Outlook for Development of the Soviet Power Engineering) 1950. Elektrltataiyanasheystrany 2-nd ed. (Electrification of Our Country), 1956. Elektroenergetike. SSSR Tan 1; (Electric Power Engineering in the USSR), Vbl. IA 19344 Electric Power Development in the USSR, 1936. Mektrifikatsiyanarodnogo Rhoziayatva SSSR (Phe Electrifi- cation of National Establishment in the USSR) 194.9. Ot plena MEMO k velikim stroyk= kcismunizma (Fran the GOESLO Plan to Great Construe- tions of Cam=ism) 1952. SW35.V5 TE85.v49, 1956. SM1193-E9E4 THI185.E6,1936 565 .14 Td35 4442 Periodicals inthitektara SSSR 24 1936, Etenanic Review of the Soviet Union 1930-33. NA6 . A74 E0331.E3 M.ektricheskiye stantsii, (Electric Power Stations), 1929-1954.- 22K4.E725 Elektrotechnische 2eitschrift (Electrotechnical Nagazine), Berlin, 1930. TIC3.E8 Prozhektor, 1930-1934 Unclassified . Soviet tbion, 1950-1955 Stroitel tner? PITIV,Nrg,5-64? Teploenergetikal (Beat-power Engineering) 1957. USSR in Contruction 19304937 _xiii 266.2S574 2a4.$85 11C26743,U3 ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 _ Author - T.1.t3.4e DLC: Cal. No. , tvsers izvestiya, #168, 3.953 Trud, #1784 1956 Zerya,Voetoka (Dom of the East) Tbilisi, 1955. xiv AP30.Z3 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 PREFAcE This report is designed to provide the analyst with a brief but comprehensive account of the layout, structural design, and structural details of steam-powered electric power plants in the Soviet Union. Included/tare some plants producing both electric power and steam for heating. Ii , The subject is extensive, and the time (3 months, including extensions) for preparing the work is limited. Seventy-five per cent of the electric power produced in the USSR comes from thermal plants. Reports on 45 Soviet hydroelectric installations made up nearly half of a two-year program completed by the Air Information Division in 1955. It was Obvious from the outset that a strict limit must be placed on the coverage of the present work. The Structural Engineering Section therefore decided to eXclude the following phases of the subject: ?f ? ? Small plants, especially those serving single industrial installations: Design of the mechanical and electrical equipment of the plants, even of the boilers, turbines, and generators; Water and fuel supply installations; Layouts of electric systems; Transformer and switch yards; Transmission lines and substations; Structure of cooling towers (views of several examples of these, however)appear in the plates). Only large steam turbine power plants are included in the report. The scanning of possibly useful periodicals, too, had to be cut off where the probable take was too thin to justify the expenditure of man-hours. The coverage exploited was still extensive, as maybe seen from the Bibliography. A general list of titles explored (whether fruitfully or not) is on file with the SES copy of the report. In the .introduction, the general course of the Soviet electrification development is briefly outlined. The/first chapter deals with the layouts of different sections of the *int power plant building. The four basic types of widely used plant q4sign'are described, and examples of some existing power plants typifyi#gl these different layouts of sections are shown. / 'I\ Th7ecg. , ond chapter analyzes the structural details of the main plant buildin t ( , / 1 / XV Declassified in Part- Sanitized Copy Approved for Release 2013/02/25 ? CIA-RDP81 01041RnniAnnnpnrinsz A Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ;;E? 4k.gi The third chapter deals with separate large Soviet thermal power plants giving for each all available and some estimated data and photo- tiaphic illustrations. A word of caution is in order concerning data on plants in those parts of the Soviet Union that were overrun by the Germans in World War II. Al]. existing power stations in those regions were presumably demolished by the invaders. It is understood that most of the early reconstruction work was based on the original designs. This Section, however, has no informatiom-a-6.to the total amount of new and updated design work that went into the reconstruction effort. :It is therefore anybody's guess whether the data in this report on any plant in regions which were under German occupation represents what is there now, or whether it has been replaced by a more modern installation. xvi Declassified in Part- Sanitized CopyApprovedforRelease2013/02/25 ? CIA-RDP81-01043R00160008onnFL4 c, Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - INTRODUCTION .7_ The electrification of Soviet Ruessia went through several stages in the course of its development. The original electrification plan "Goelro" (State Commission for the Electrification of Russia) was approved in 1921 and the construction of electric power plants received first priority. Tho guiding principles of the "Goelro" plan were: the restoration and reconstruction of old power plants% (part A of the Plan); the construction of 30 large regional power stations, mostly thermal (GRES), built in places where local low-gide fuel resources were available (peat, brown coal, anthracite culm, etc.); and connected with high-tension lines to form several main regional electric power grids (part B of the Plan). Part A of "Goolro" plan was fulfilled by 1923, and part B around 1930. In the tlrat Piatiletka (1928.- 1932) the original "Goelro" plan was extended, first by the increase of installed capacities in the already existing plants and secondly, by building 20 more power plants, almost all thermal. (See maps on Plates 1 and 2) The main building of these power plants built up to the end of the first Piatiletka was usually a poured-in-place reinforced concrete frame structure with masonry curtain walls or brick panel walls and ;. steel or wooden roof trusses. Columns were rigidly connected to poured- in-place pile-supported foundations and were entirely separate from the special pile-supported poured-in-place reinforced concrete foundations for the machinery. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R00160ooRnom4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Up to the end of the First Piatiletka very few hydroelectric stations wore built. The main reason for this slow-down was that previously made geological surveys proved to be inadequate for the construction of dams and that more accurate surveys and plans were necessary. Beginning with the Second PiatilOca (1933 - 1937) the construction of hydroelectric stations was started on a much larger scale. The thermal power capacity was further expanded, mostly by additional installations in existing plants, and by building not only some new large power plants but also smaller local electrical stations which wore switched into the steadily expanding regional grids. Larger new power plants were built, mostly in cities and around industrial centers. (See map on Plate 3). The poured-in-place reinforced concrete type of construction was being gradually replaced by construction with precast reinforced concrete elements, such as columns, beams, and girders; the plant foundations and substructures, however, were still built of monolythic reinforced concrete. This trend continued during the aITW_EkltLlzgkLDJIVL=AaAll. During this time larger power and heat-and-power stations were built in the East, in the Ural Mountains, in Siberia, and in Central Asia; this building program in the East was especially intensified during the War. During the War, preeast reinforced concrete elements were not used in the construction of power stations because the precast fabricating plants were not operating. -2? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 After the War, during the. Fourth PipAgetka (1946 - 1950) the first task was to rebuild the destroyed power plants. Next, rural electrifi- cation was greatly increased and extended whenever possible by the con- struction of small local hydroelectric plants. During the Fifth (1951 - 1955) and the present Sixth (1956 - ) Piatiletkas large hydroelectric projects were carried out. The share of electrical energy produced by hydroeleorric plants rose to 25% of the total. In the design and construction of new thermal power plants more standardization was attempted. The power plants are under the Ministry of Electric Power Stations and plans for new stations are designed by the Institut Teploelektro-proyekt. The Institute prepares suggested master schemes for thermal plant con- struction. Precast reinforced concrete elements were prevailingly used in construction of plants; also rigid welded steel reinforcing skeletons which form the' main reinforcement for the concrete frames of the building. Certain elements, usually roof beams, are of prestressed reinforced concrete. In the design of power plant foundations, instead of providing a separate foundation for each piece of auxiliary equipment, the design called for a basement with a heavy reinforced-concrete slab foundation. Only (1) the columns have separate footings, and (2) the boilers and turbogenerators rest on separate monolithic poured-in-place concrete blocks. -3- nprlacsifiRd in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 111111111 .1 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 With boiler efficiencie'S increased so that a single boiler is sufficient to serve one turbogenerator, the design of thermal power plants has become simpler. The turbine hall is parallel to the boiler house, the turbogenerators are placed lengthwise to the turbine hall, and since one turbogenerator set longitudinally occupies the same space as its boilers, the condensing equipment being placed underneath in the basement, a block system boiler?turbine can be introduced. Instead of a central fuel preparation system (pulverizing for coal and milling for peat) at present each boiler has its own separate fuel preparation unit. Because boilers and turbogenerator sets are now (1956) larger and heavier, power plant construction has become stronger, foundations heavier, travelling bridge cranes of greater load?lifting capacities (100 ? 200 m. tons), and consequently columns and girders stronger. The cross?section widths, however, of the boiler and turbine rooms can remain unchanged. One of the building's end walls is made as a temporary structure to be moved in case the plant is extended for the installation of new boiler? turbine block units. The unit capacities of these new boiler?turbogenerator sets have been increased. The boilers presently (1956) installed, work at higher pressures (up to 300 atm.) and higher temperatures (up to 650?C = 1200?F), and turbogenerators can be installed at higher capacity ratings (up to 150,000 kw.) -4- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 MAP OF DISTRICT ELECTRIC POWER PLANTS AT THE END OF THE PIATYLETKA (OCTOBER ley, 1933) INDICATING POWER PLANTS WORKING IN 1930, THOSE BEING ENLARGED AND OTHERS UNDER ERECTION oft 0.01 1761 IN 11,20,14 ?Ni (0C ?".{ :112. 011100 ?/?? Nontsi Solo V24.44,' 00 610a1'. 111C11101 W /06?114 OP 10 0 liss. .001:00) ?r.Aor 6 cmraaftrod SPOIlt PComa4 CD z 0.1linak I I ,1111110 ta11111C111111111 00 a rta 1?9242a PERETASLAV de u IMP TIPOINCINCINTAI ? o..siors.ne TINIIIIMOSINN ,?.....?4.Ix .AtZ II Nom. r RIONES mactilt.2.LowsK .44:4 .- ..IS A Tosgustsztowi,, 0 ? VDDIPIN r--- ' l'iaLta 0 KOLVA La DNIftml TIRAMIDACCIMial =MC.s \ Triss.ssonsvo P I I II ..1,N.,, ft. ' ( ?r e.." '............/l , : Z10101,a C0(11001000 II NIZIINI SALOA as Cipli? . Maparri.t Ef...6 Mar ...remitters& at/f,, CEMZEN:17 1.24 BRIARSI tttttt IA,. 36 0 i 607..mtel ? Kursk Kilo as"'.' 20 ? ? T1.11. BOBRIKOV ? LIP IT Zit 0 orandae .??? BB Kaoas.a*a DRIEPROPETROVSI ZVI,/ KRIVOI Roc A 372(506) L'arosorth Dosso08 AV! NESTETAI mftft32) SARATOT 0 STALINGRAD 0 / ? OVOROSSIS KRASNODAR No 042 OM DESIGNATIONS I. 1533 STEAM. POWER PLANTS: ?I. t000laotaloac 0 la ..2?01.10a. 100,17 vorog 0 la 11?10.1.0 NYD.ROSTATIONS golie? ..... A ,. ...1014100 ss ...... L loo 1.00 . .1 101119 wv. Isms Iola .01. MM. The telogaalt.? 104?09 ???? al tie .1.0 ttttttttt ....01, aBol.....?00 a.. Lia/ he vs... at 00.00. tttttt laIle?s: ttttt 0.1 C C?vroot. N1 01 Vaal. a 0? ttttttt Olv Int t??????????00.0.0 C h_.......4 tog C?al ??? 0a, 0000000000 oly 000.1.1 000000 bilvealls. la 11101 1$00101111 la "00 00000 VASNIRN I. ..m.m.ft? .04 ....oft...ma I. 0000000 tttttt ova. AO 'MIMI C ,,, OfFe A_ SLIM (..'.3.1" O. , .Vakilut ..........j ?OIL moo m ACHAL 22 1' lad liadar 15"I ? Rtom ?74? Kafol. BANS& TOPANAVAN ? D z 011.1:E1 A KARASACIIKA 22 KAMANIN 20(60/ Ato BAKU 2 PP ?1,INSItt (It PIATE 1. .5., - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 AIL OPT.MrAPICA ele..00P"" ACIXAMrEA0CV "C.' 2 5E/.0MOPCTPON f 00.4 s.......4....., CPICb ? *041111 ...r.41413?4 !L... . 0 1:00,C.2.......ireAH0,7 Ab i sw.........o...,....... ?-? a ? fax U.1 iltroobsews. eirrEsoc 11"KPEcei?1,,,,,?, 01 1,0?0022??? 11.11 MOCKBA tkommonashwym.?, 411 411V11.44 tail 43, otAyl..... 00,0" ~Wet romr.A. ' ? j-ratfilliaZ451.^47 AfeAt .06014gt, lal 0 P ?BWOJEPA KAMA 111TA1I1I1OB- ngurnuincu COA1JKAMC Da - 103,./Cot arelf/X. TA4r0rAwre ? ne Kur08.1.1" dircOPOMOK ? PO.00..? unicoi mAT:e walk .CrAilicTpAxAtibl ? ?Clid "r".;* L..' ? . ICA1.4tigOi014{7 Aa..4 OCt P4APA ? O....6" "411irtni 3,A ifib44k.KPACHOIcTrAAto'''''...Ck ?CAAAA ...woad ? 44421., ..tRec=ajm 1111.24EA061.01CK ? MUMIT 50PCIOt osisruce ."EPC81171.5:171:1- HollOCL4540,96, cAn ATLICC".. 41n: AK?401....C.1 4194.70a. 2-11 ArAPIAA Akar P aj,111.e. EMICIAAATUHCK ? ....mho 174,719 gimicron.wwwww.; aigg*: MAP SHOWING =MAIN SOVIET POWER STATIONS AT THE END OF THE FIRST PIATILETKA IN PRINCIPAL INDUSTRIAL CENTERSI, Source: Prozhektor, 1933, No. 1, AP50.116 PLATE 2. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 ? LIST OF REGPNAL ELECTRIC POWER POWER STATION I. NIVA HYDRO-ELECTRIC STATION 2. KONDOPOGA HYDRO-ELECTRIC STATION 3. LENINGRAD POWER STATIONS ? ? ? ? 4. VOLKHOV HYDRO-ELECTRIC STATION 5. LOWER SVIR HYDRO-ELECTRIC STATION 6. MOSCOW POWER STATIONS ? 7. SHATURA REGIONAL POWER STATION 8. KASHIRA REGIOgIAL POWER STATION 9. STALINOGORSK REGIONAL POWER STATION 10. KALININ POWER STATIONS - ? ? 11. WHITE RUSSIAN REGIONAL POWER STATION 12. VORONEZH REGIONAL POWER STATION 13. BRIANSK REGIONAL POWER STATION 14. KIEV POWER STATION 15. KHARKOV POWER STATIONS (TOGETHER WITH KRASNOZAVODSK HEAT-AND-POWER STATION) 16. KRIVOI ROG REGIONAL POWER STATION ? 17. RYKOV POWER STATION ? ? ? ? 18. KAMENSKOYE POWER STATION ? ? STATIONS IN THE USSR IN 1936 CAPACITY 30,000 KW. 4,500 378 000 66,000 100.000 314.000 180,000 POWER STATION 30. OTHER CENTRAL. POWER STATIONS OF THE DONBAS 31. NOVOROSSISK REGIONAL POWER STATION 32. GIZELDON HYDRO-ELECTRIC STATION ? . ? 33. RION HYDRO-ELECTRIC STATION ? ? ? ? ? ? ? 34. ZEMO?AVCHAU HYDRO-ELECTRIC STATION \ 35. DZORAGET HYDRO-ELECTRIC STATION ? ? 36. BAKU REGIONAL POWER STATION ? ? ? ? ? CAPACITY 45,000 KW. 20,000 ? 23,000 a 48,000 ? 25,000 a 22.500 176,000 186,000 37. KADYRYA HYDRO-ELECTRIC STATION 13,000 100,000 38. EIURJAR HYDRO-ELECTRIC STATION ? ? 3.300 19,000 p. 39. BOZ-SU HYDRO-ELECTRIC STATION 3,000 20,000 40. TASHKENT POWER STATION - 3500 24.000 p. 41. FERGANA REGIONAL POWER STATION 8.200 22,000 a 42. NOVOSIBIRSK HEAT-AND-POWER STATION 35.500 64.000 43. KEMEROVO REGIONAL POWER STATION . 48,000 44. CHEUABINSK REGIONAL POWER STATION ? ? ? ? ? 150.000 98,000 45. KIZEL REGIONAL POWER STATION ? ? ? 98.000 44,000 46. YEGORSHINO REGIONAL POWER STATION ? ? ? 24,500 6,000 47. SVERDLOV REGIONAL POWER STATION ? 11,000 48,000 98. PERM REGIONAL POWER STATION ? ? ? ? 8,000 19. DNIEPER HYDRO-ELECTRIC STATION 558,000 20. ODESSA POWER STATION ? 37,000 21. NIKOLAYEVSK POWER STATION 13.500 22. SEVASTOPOL REGIONAL POWER STATIONS 8.000 23. SIMFEROPOL CITY POWER STATION ? 1,700 24. YALTA CITY POWER STATION 1,300 25. ROSTOV POWER STATIONS. . 128,000 26. KRASNODAR REGIONAL:POWER STATION ? ? 10.000 27. SHTEROVKA REGIONAL POWER STATION ? ? ? 152.000 28. ZUYEVKA REGIONAL POWER STATION ? ? ? ? ? 200,000 19. NORTHERN DONETS REGIONAL POWER STATION ? 65.000 49. MIDDLE URALS REGIONAL POWER STATION ? 50. BEREZNIKI HEAT-AND-POWER STATION 51. KUIBYSHEV REGIONAL POWER STATION 52. STALINGRAD REGIONAL POWER STATION 53. SARATOV POWER STATIONS 54. KAZAN POWER STATION 55. GORKI REGIONAL POWER STATION 56. IVANOVO POWER STATIONS 57. VLADIMIR HEAT-AND-POWER STATION 58. YAROSLAVL REGIONAL POWER STATION 59. ARCHANGEL REGIONAL POWER STATION (THE NUMBERS AGAINST THE STATIONS IN THIS UST CORRESPOND TO THE NUMBERS SHOWN IN THE CHART). 50,000 93,000 27.000 75.000 22,000 24,000 204,000 ? 113,000 3500 ? 36,000 16.000 CAPACITIES IN KW OF REGIONAL POWER STATIONS IN THE USSR IN 1936 SHOWN ON MAP, PLATS 2. PLA_MX.. ta-ervY neclassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ,HE GOELRO PLAN FULFILLED ROUGH CHART OF THE REGIONAL ELECTRIC II;(kOWER STATIONS OF THE USSR IN 1936) Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 CHAPTER I GENERAL LAYOUT OF THE MAIN PLANT BUILDING The larger thermal electric power plants in the USSR have iiteam turbines as primery movers. Steam piston engines have been completely discarded, gas turbines are still only in an experimental stage and Diesel motors are used in power plants of smaller capacity serving local needs. The layout of plants has been influenced principft33y by the kind, efficiency and size of equipment installed, by the kind of fuel fired, and also, to certain extent, by the type of the station, i.e. whether it Fis'Acondensing or a heat-and-power producing plant. The general scheme of a plant layout is mainly centered on the proper placing of the boiler house as the most complex section of the plant and on the grouping of the turbine hall and other sections in relation to it. When the steam turbine was introduced as the prime mover, the total capacity of several boilers was necempary to produce a sufficient amount of steam for one turbine. In the first peat-firing plants built in the twenties therefore, we find that either: 1/ the boiler rooms are placed at right angles to the turbine hall; or 2/ the turbine hall is placed parallel between two boiler rooms. Examples of the first type of arrangement are:. 1/ the first priority of the 204,000 kw. Gorikly GRES (see Plate 4, Fig. 1) which has three. double-row boiler rooms, 6 boilers to a turbine; 2/ the first and second priorities of the 180,000 kw. Shatura ORES (see Plate 4. Fig. 2) which has threw single-row boiler rooms, 4boilers to a turbine. nprlacsifiRd in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 t ; An example of the second type of arrangement is the 100,000 kw. . 11 i i. i I Dubrovka GRES where the turb/ s 1 is placed between two boiler rooms 2/ and parallel to them (see1" 'ate 0. I / With the rapid advaW/' of baler engineering, the improved boiler- turbilie ratio madd it/'s3ibe to lay out electric power stations with ! the turbine hall aneene boiler house parallel. At first, when 2 boilers were still needP9'fo1 one turbine, the boilers were arranged either in a double row-, aa in,it e 152,000 kw. Shterovkla pulverized-coal ORES .' i (Plate 6) di in eh.? le row but with somewhat spread-out turbo-generator sets as in the peat-bunAtng 120,000 kw. Ivanevo ORES (see Plato 7). Further increase in boiler capacities made it possible to design stations with one boiler installed per turbine. The turbogenerator sets are arranged lengthwise to the axis of the turbine hall in all stations, with the exception of the first priority of the Shatura and the Dubrovka plants, where the turbogenerators are installed crosswise. The main building of a thermal electric power (or heat-and-power) station is composed of the following sections: 1. The fuel bunker gallery section, in most cases with the peat. milling or coal-pulverizing installation (central or individual for each boiler); 2. The boiler house; 3. The smoke discharge section (smoke exhaust flues, induced-draft fans;) 4. The section of feedwater tanks, feedwater pumps, deaerators etc; 5. The turbogenerator hall and auxiliary equipment. ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 4 ?:( Those sections can be clearly identified on the model of a ? 5 x 50,000 kw. pulverized-coal station (see Plate 8) or on the model of a 200,000 kw. peat-firing power plant tsee Plate 8e). Different arrangements of these sections in relation to each other characterize the specific types of the main building design of thermal- electric power plants. The central point to be considered in a power plant design is the location of the boiler house as the most complex section of the plant. The boiler house can have one or two free side walls - that is, walls that do not adjoin the turbine room or its auxiliary section. Outside a free side wall the designer can place the auxiliary sections of the boiler house, namely: 1. the bunker section (bringing and storing of fuel, and its preparation for burning, i.e. the milling or pulverizing equipment) and; 2. the smoke discharge section (smoke exhaust flues, % induced-draft fans, smoke stacks). According to the location of the boiler house, the main buildings of thermal-power and heat-and-power plants can be -classified in four general groups. First Group . In the first group, the boiler house has one free wall, outside of which is the fuel bunker section. In this group, the stacks are in or next to the boiler house; they and the induced-draft fans are set on a high specially-constructed frame, or on top of the frame that supports the feedwater tank, pump, and deaerator section. -11? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Second Group ?. The Second Group includes power plants where the boiler house also has one free side wall, with the fuel bunker section adjoining; however, the smoke discharge installations are separated from the boiler house. Smoke flues are brought underneath the fuel bunker section, the induced? draft fans are placed low, on the ground floor, and.the stacks are separated front the main building. Third Group ???? In the Third Group, the boiler house has two free side walls, the fuel bunker section on one side and the smoke discharge section on the other. Fourth Group The fourth Group is like the Third Inptiddipre, lAtt?a-rrarged more compactly, with the fuel bunker section set in a frame common to that of the turbine room. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - The design of each of the groups is based on the general scheme of arrangement of the sections; however, within the framework of one group: some individual solutions ilk the design of the plant are feasible. The first group is the most common, especially in power plants built in the twenties and thirties. Ekamples of the First Group arrangement are: a. Zuyevka 96,000 kw. pulverized,-coal GRES (see Plates9 & 9a). b. Ktuznetsk 108,000 kw. pulverized-coal heat-and-power TETs. (see Plate 11) c. Stalihogorsk pulverized coal GRES (see Plates 12 & 12a) d. Ivanovo peat.;.burhing GRES (see Plate 7) e. Stalingrad pulverized-coal GRES (see Plate 10) e. The layout of the First Group has the drawback that'smoke eliminating arrangement is located either totally or partially in the boiler house, and the induced-draft fans are placed at a high level, so that their draft capacity is reduced. In the Second Group design, this problem is solved by bringing the smoke exhaust flues to the lower level and placing the induced-draft fans and smoke stacks outside the boiler house. Examples of the Second Group are: a. Nesvetay GRES 4see Plate 13) b. Stalinak (Mosenergo #11) TETs in Moscow (see Plate 14) The First and Second Groups form the "compact" groupings of the station sections. The Third Group is called the "disjointed design", the boiler house and the turbine hall being in different buildings. An example of this arrangement is the Orsk TETs (see Plate 15). The Fourth Group arrangement is the latest design of the power plant ; building. Some power plants have already been built according to this arrangement, probably the, Cherepethlic GRES; also Mirouovsk GRES and Slavyansk GRES. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - ti I = t.% . A "Irs' Ftc. 37.?Gorki regional station (plan view). Fig. 1 - Gor'kiy Peat-Wiring GEES F16. 38.?Shatura regional station (plan view). Fig. 2 - Shatura Peat-Firing GRES THERMAL POWER PLANTS WITH BOILER, ROOKS AT RIGHT ANGLE TO TURBINE HALL. Source: Weitz, 1. ed. Electric Power Development in the USSR, 1936. TIC85.E6. ??- _ PLATE 4. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? _ Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ott_Piao, 66o' 1/1445' am ? ommusu:nmum: llll mt... .,___,Igemounni.. llll niumuniiii Mira, ,.. ...,,,,......gr,Agigligem,.....". 1 A 'II' OPI-PrlitiW'''d ._-_.--:,:f.F.1111 um, ria Q---6 Firmi....p. i i "Attie' Oh- I rilrireN 2f/.4 -IlL,IirlliglIIMERMEtifil?P.Wir-r-3111 ilk A volan _ 111111Eli ,TtlAttil; ? Ri jii,:rilWas4=1;:ii=momnrczkaLmwicommalgOli 3111111-aumwasionn. bitOtet& 97.e' Itrw' -?8474 R6.3' - ION ct o 4461- ViL7-1U1Wr-1-1-4ev tIn4 L. 74 fnm 116.5' 90.0' 1 - Peat car; 2 - Steel peat bunker; 3 - Peat Chute to th'e furnace well; 4 - Furnace well; 5 - Mechanical Chain grate; 6 - Furnace; 7 - 3-drum water-Ube boiler, capacity - 135/160 t./h.; 8 - Water economizer; 9 - Air preheater; 10 - Smoke-exhaust fan (induced draft); 11 - Forced draft fan; 12 - Stack; 13-- Ash and cinewr bunkers; 14 - Feedwater pipeline; 15 - Steam pipeline; 16 - Steam turbine, capacity 50,000 kw.; 17 - Condenser; 18 - Three-phase generator; 19 - Crane bridge;. 20 - Mechanical filter meth; 21 - Circulation pumps; 22 - Water main; 23 - Drainage Channel; 24 - Feedwater tanks. LUBROVKA AT - FIRED GRES. Source: Weitz, b. Electric Power Development 1936. TK85.E6,1936. Antipov, I. P: Arkhitektura elekrostantsiy? 1939. TE458140. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 egargrorshro~sa I 01$44reorati glagamefta.a Siedforti?serZoicenawymr - _ /..., Tr/ ..... .,. /1 i-44 .......?, '.........-- - - irrr ------..? --..".'"Ift................ .......... ..\ e .. ;, I (,' v _ ?....._ ta i.? r...---... 1 ' ' \Ia. , I I.MTAS.64.41?? rr7i- 4.R *t t. '"? '91141.11.0. ../111?. C ? V , Site plan and sections of main buildings. SHTEROVKA PULVERIZED COAL FIRING GRES (Capacity: 1520000 kw.) Source: StroitelinaTa Promyshlennost' 1924, #42 p. 242. PLATE 6A Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1.? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 4 .,,---t---1 -,e.:ii - . '_, . it .n. ? ? : '11iLrf ? IrL4 ? 14=t? . a . ? ? ?`,". 4\ 1 S49:1 0-7 *or I air Awl goo 1-ms 1 ???, 1= rIAAH CTAHUMH 11:I III 1111111.1' .. 1 I. 11'11 H. (.../1 y1111.1 11.14?11 II 11 .11 11:1, 11 1.I.? 1 1,.1 II, . 1.11II ki art, lit.. m.. \dung, ..111 ma. hi, ,1111,11. 1,..?11?111. 11 11 11 .1 1.I.t ?III 1..1.11.. II, %I. IllilIlls 11;11 II pi' 11%1 11 1..11.11. 11.1111.11 II 11111.1..X1. $11111' :1011 II II 1 liallo'.1.11,11,1 1..1.11,..? 1P.M...111011 II.' 0..111% 1111 Ilt? ? I "I I"' u11 \ iII 1.1 nor...11.M 1.11- ??? Plan of power plant. 1. Boiler house. 2. Pump section 3. Turbine hall 4. Control soction 5. Reserve transformers 6. Oil.section 7. Work shop Source: 8. Service quarters 9. Accumulator section 10. 6,600 Volt distributing installation. 11. Locker room for workers 12. Circuit breakers 13. Transformer section 14. Cooling section SHTEROVKA PULVERIZED COAL?FIRING GRES (Capacity: 152,000 kw.) Stroitel'naya Promyshlennostl, 1924, #4, p 243. PLATE :61) Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 .98 . 0 I II to - 4.9. 2 ? r- 4.9.2' .1 4 ? 4 ? ? ? ? 1 4 ria ??1 ? ?--1 ? ? -4 ??? r 1: i . ri:;?er.t.1,4 ri .. 4 ; , ; : ; ; I ; ; ;141.1... ? ? ?-? ? ? ? a 4-?-?-? 6 re-+ ?-4-?-? 4 44-4- ?-? ??1-4 ?-?-? ? ?-?-?-1.1 ibi 111:11F3- E--=.} ser-t1.2,&*t.ruit-A.*A4 ? ?-?-?-?-?- ?-?-? 4- I juji..44444.4-4 3000 /64 //. 0' zn ' /6.4. ?XI _ 1-71 /.27. ' , ? \ / ,70.5 69. o' tot- ---7-7?mmwommwmangi 744N001;a2W-- 16 56.4' 11200 Ir.-- 7250 ,450 7 .23.0' 0c', .`-:.----i..- - - -_-_-_-. ?_ . /5 49.7, 6 3. 0 ' ..), r4600 ?1-- 800o ?197?41 6"7"[---- : 0 1 ,0 'SO ?? ...-7000 ?I Nan building, section and. plan: 1 - Electric locomotive in the over-bunker gallery; 2 - Peat bunker; 3 - Peat Chute to the furnace; 4 - Mechanical Chain grate; 5 - Furnace; 6 - Boller; 7 - Water economizer; 8 -Air preheater; 9 - Smoke-ekhaust fan (induced draft); 10 - Stack; 11 - Forced-draft fan; 12 - Ash and cinder bunker; 13 - Turbogenerator, capacity - 24,000 kw.; 14 - Water Channel and sump; circulation pumps; 15 - Drainage Channel; 16 - Crane bridge; 17 - Feedwater tank; 18 - Feedwater preheaters; 19 - Boiler feedwater pumps. IVANOVO PEAT -F/RIN3 GRES Source: Antipov, I. P. and S. S. Bakita. Arkhitektura elektrostantsiy, 1939, TH4581.A5. Weitz, B. ed. Electric power d e1oprnet, 005.E6 1936. MATE 17. -18- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 -?????? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 (11 1. Bunker gallery 2. Boiler house 3. Induced draft fan gallery 4. Pump gallery 5. Turbine hall 6. Catwalk MO= OF A 5 x 50,00011twe PULVER/ZED-COAL-FIRING MIES. (Section through the Main Power Pltuit Building.) Source: Antipcm, I. P. and S. S. Rakital ArkbitekturaL Elektrostantaiy, 1939 TH.4581,A5. PLATE 8.4 .19.. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 +0, ?_Bunker,section with the peat,pulverizirg_installation; 2 ?.Boiler house; 3 - Forced draft fans and smoke exhaust installation; 4 - ftedwater tanks .feedwater pumps, deaerators etc. bay; 5 - Turbine hall. MODEL OF A 200,000 kw. PEAT?FIRING ELECTRIC POWER PLANT. Sources Elektricheshiye Stantsii, 1932, No. 7, front cover TK4.E725. PLATE 8.A. - , - ? " Declassified in Part- Sanitized CopyApproved forRelease2013/02/25 : CIA-RDP81-01043R001600680608-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Cross section through the boiler house and the bunker gallery. The feed pump and tank section and the turbine hall are not shown - they adjoin the boiler house to the right. ZUYEVKA 200,000 kw PULVERIZED-COAL GRES Elektroenergetika SSSR 1934 p. 68 TK 1193 R9 E4 PLATE 9,. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Cross section through 'he boiler house and the feedwater pump and tank section. The bunker section is to the left of the boiler house and the turbine hall to the right of the feedvater pump and tank section. Source: Elektroenergetika SSR 1934 p. 68, Tk 1193 R9E4- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part-Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 , LEGEND: PLATE 10 1. Belt conveyers 2. Raw coal bunker 3: Automatic scales - 44 Ball mills' 5. Pulverized-coal injector Pulverized-coal ducts 7. Pulverized-coal burners 8. Furnace chamber 9. Boiler 10. Air preheater U. Smoke exhaust fan (induced draft fan) 12. Stack 13: -Forced-draft fan 14. Cinder bunker 15. Ash bunker 16. Steam turbine, capacity 24,000 kw. -17. -Boiler-feed-pump 18. Feedwater tit:* STALINGRAD PULVERIZED-COAL GRES Source: Antipov, I. P. and S. S. Rakita,A,rkhitektursLSIPktroatantsiy; 1939i TH:4581.45 Weitz, B. Elektroenergetika ss.R. T. 1, 1934 TE1193.R9E4. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 f ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 0:0 ??? ? 0 fria Ar \D 1 L !?1,1' ' v_ r, _ - - - - 0 t411'. 0 ! - cc:0 Section through the main power plant building. Smoke?discharge section is part of boiler house with exhaust arrangement in upper part of structure. STALINGRAD PULVERIZED?COAL GRES PLATE 10. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 41' ? 416 171 611 i -0-0_ T-0-7 4-r-e- 0- - 6. 6 - - -1- $ t 3- mum aemsmommosem gIV-- *If ? ? . LEGEND PLATE 11A. `T 1. Bunker section. 2. Bola er house. , 3. Feadwater pump and tank section.; 4. Turbine hall. 5. Switch boards. 6. Service accommodations. LEGEND: PLATE n. 1 - Belt conveyers; 2 - Raw coal bunker; 3 - Automatic scales; 4 - Ball mills; 5 - Dust remover conveyers; 6 Worm dust conveyers; 7 - Pulverized-coal burners; 8 - Worm conveyer feeder4 9 - Pulverized-coal burners; 10 - Airmace; 11 -7 Boilers; 12 - Air preheater; 11 - Ash intereepting cyclone; 14 - Induced.draft fan; 15- Stack; 16 - Pierced-draft fan; 17 - Cinder bunker; 18 -.Ash . bunker; 19 - Steam line to the engine room; 20 . Steam turbine; capacity - 24,000 kw: 21,=.Condenserj 22 Water outlet lines; 23 - Crane bridge; 24 - Station distributor; 25 - Feedwater tanks; 26 . Feedwater preheaters; 27 ii7,-Artler.4eedwateir pumps; 28 -; Fisedwater line; 29 - High pressure heaters. EITZBETSIC PULVERIZED-COM, TETs Pr THE METALLURGICAL PLANT. Sources Ant1p2v, X. P. Arkhitekura Elektrostantsiy, 1939: p. 177. TE 4581.45. PLATE 11A. ? A A N?r.s Cl Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? ?1" ? 69 . _,173 ;6-4; 4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ?.- 19 ? 4 rjjjfir : .1431 fr /36. 4110 t? I %.? ' I ?44 -,- .? ? 3? 2 ? ??? - ? ? 25 I :2 cel '5 00 149. 3 ' ..SCO $500 23.0' Lidso_ 27.2' J? COO 22 ? 1000 8 8 ? .5" ? 7000 $V 11.?? - 1;0 s. ? 17000 020 ? Section through the main plant building. KUZNETSK PULVERIZED-COAL HEAT-AND-POWER STATION TETe PLATE U. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part- Sanitized Copy Approved forRelease2013/02/25 : CIA-RDP81-01043R001600080008-4 ? PLATE 12a: STALINOGORSK PULVERIZED-COAL GRES General layout of the power plant building on the bunker side and coal conveying and crushing installations. I-Coal-crushing installation; 2 -Cpal-43unker section; 3 - Boller house; 4 -Water tank and pump section, with smoke exhausts and stacks are installed above; 5 - Turbine hall. Source: Weitz, B., Electric rower Development in the USSR, 1936 TE85.E6, and Antipov, I. P. Arkhitektura elekrostantsiy, 1939. T84581.A5 LEEGEND: PLATE 12 6 -Ball mills; 7 - Pulverized-coal bunker; 10 - Boiler room; 11 - Boiler-feedwater pump; 12 - Switchboard; 13 -Water tanks; 15 - Induced-draft fan gallery; 18 - Steam turbine; 19 -.Circulat- ing pump; 21 - Control room; 22 - Switching and distributing installation. ar.rrsr. ,Aas Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 rTh 1 rt.) o Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ezTi 1/3.0 .---..,-?--- . - .7------zz=a---- --- st 7-= :1 4'E:1 _zr..., f " i_ "ri 10 Pi. ft! c ?. 9 17. C; A I r )?:; 6 4T171L'llr-r- 8 : ' /32 .0 ' 13 875' 1177. -17 X 83.oi 21 11 112 - re) 18 ? f-2:4711-i ?-;* 11*.% 6 '.0' -21000 .:.; /3. 3 40001-.7 000 ? 96 . 0 27500 - - '15 1?11 22 iTax47J'' 1 1 6.11 8500 H 6 202501 p .-r 37.7' .!500 -r?-- 15840 Cl; 9 ti+4 2141/ ?.I 7450 ? Cross section through .the in power plant building. STALINOGOBSK PULVERIZRD?COAL GRES PLATE 12. - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Legend To Plate 13a 1. Turbine hall 2. Peedwater-pump and tank section 3. Boiler house 4. Bunker section 5. Switchboard for lights 6. Transformers 7. Switchboard for 500 volts 134. Personnel accommodations 9. Electric filters. 10. Smoke eliminating section 11. Stacks. 12. Chemical water-cleaning installation 17,7 CD =00 ? ? ? ? : sarzia.ok?Lr--. 000 ? ? ?P?orglatli? ?? J cr1 a6 CI Plan of the first floor of the main building. NESVETAX PULVERIZED COAL GS. PLATE 13A. 1011?' emmi man tougnuomo "Trit71=?=17.10.M. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 (Th Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 flE 10 0 Os. 49111.'1' Sectica through the man building! NESVETAY PULVER.T.23D-COAL GRES Source: Antipov, /. P. Arkhitekture. ElektrostAuxteiy, 1939, TH.4581.45, sad Elektricheskiye Stantsii, 1947, No. 5, TK4a725. PLATE 13. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 '14 1 - I I - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 MEND: PLATE 14 1. Belt conveyers 2. Raw coal bunker 3. Duct 4. Automatic scales 5. Drying duct 6. Drying cyclone 7. Mills 8. Pulverized-coal separator 9. Pulverized-coal cyclone 10. Mill fan 11. Primary air fan 12. Primary air collector 13.. Pulverized-coal worm conveyers 14. Pulverized-coal bunker 6 15. Pulverized-coal ducts 16. Pulverised-coal burners 17. Furnace chamber 18. Three-drum boiler; capacity 150-180 t./1,. 19. Air heater 20. Electric filters 21. Induction fans 22. Forced-draft fans 23. Steam poloer azxl heat turbines; capacity - 25,000 kv. 24. tarter heating apparatus for district heating lines 25. Deaerators 26. Feedwater tanks 27. Stations own - need switchboard Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ( E?52- /O6-5' *;1 27 ? - Kvn 2 6. 2! L. -41 r !I1111 aL7-7qT1411777.1.4.;; -"NJ. 1???? .1 5 ta 22x -Laza.= Y-411::: ..---"' 1-F: -- ....: ..-4--; - ? .. -I': . ' - - ? 1.2.1. ? ' .? - - - - . ? --, e iir .41ifgaltrsrumnr? A .171%.1:93.:;. C ;;;....,:tri: '"'Aa . : : :wf 1 21e04??-- 8500 ??-:???? E.7.747 ; 74' 279' /9.7' Z0450 S 9-9 s Section through the main building - Stacks located 40 in. apart from the building the bunker section are not showit'on the drawing. STALINSK (MOSENERGO #11) PULVERIZED-COAL TETs IN MOSCCW Source: on side of Elektricheakiya Stantsii, 1947, #5 and #8, TIC4Z725 Antipov, I. P. Arkhitektura Elektrostantsiy, 1939, TH4581.A5. PLATE 14. ??? Declassified in Part- Sanitized Copy Approved forRelease2013/02/25 : CIA-RDP81-01043R001600080008-4 ? 1 ?:?? ? .4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? ?2? M ? 4:- *ti - k?- .; -4,f--431 8 R.., r t4.4.t N.) . 10- - TT' .10 4i? ? f " faa ti 'r :1 1. ;!. 7, 11. t tit 1 - I !NJ, ? t F; S.; -I 7 .t.I . ? 7, ? It. o.,?:.1 '9-9 --:-.1.: - - - ?-'.." ?? - ?X'S.. .1'..* .............! r? .--I ' L -...? - -- ? - ..._ _ -;-?-??,-:7??? -.--1. - - - --" ?? ? I Plan of the-mein building of the station. OESK PULVERIZED-COAL TtTs Source: Weitz, b., Electric Power Development in the USSR, 1936, T1. E6, Antipov, I. P. Arkhitektura elekrostantsiy, 1939, 4581.A5. PLATE 15A. -)s `t?-.??=?-v ' ? ? V V ???,, Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - - 1i 0I tiri:__7r,u 14 i .II1_'1_,c., !,-)?_-1r_... 4.r17i.i Iir,. :' 1?ft.i..-' %:.,'ii3 ... t f - -4,.; " i . 7i4;:iti,, f- ,? a 0 _, coo 11 r 0 'HO ,,....- - . .. A ? .t ???? ? a . .., : I ? ? : : : .. r .-.. -, L .1. : - 1 .. ? .? ...el ???? ..'le4.1'llili_.,t-V. a i. I 1-- -? r:oo ---;-- cm - --1--scsa ..:-. - - - --- -- i 24.31_ . ? - ? ? . r A 1 e ? t -0/1.M?i, 4 gr6 '?,_ _ ... _,?7 r 3 2.)--'1:1r.;.4. r 52.!- _________1.-. ___........-.....?_? 0 3D. i'' ' ?6.3' .23 -I) 's .., Type of "disjointed" desikpa of station with low-set induced-draft fans and with the front of boilereiSh turbine ha.U. ORSK PULVERIZED 03AL TETs CROSS SECTION THROUGH TBE MAIN PLANT BUILDING Source: Weitz, B. Electric power Development in the USSR, 3936$ TK.85. E6$ Antipov$ I. P. Arkhitektura elekrostantsiy, 1939, Ta14583..A5. Fume 15. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 pun of the main b-trilding. CHEREPETa PIILVERIMm-coa HIGH PREF.:SUM GRES Source: Elektricheysiklye Stantsii, 1947, No. 5, p. 11 TEV.E725. PLATE 16A. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 '411G Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1 briffornitirai50.4j? 11.0 /06,0 .4 117 22,0 ; u ,1?,, , lb,- u "?, . A of- In 1. WE- E - fi-ii. d ZoNa,,0251 OP. .lli .W14, Jill itu. II111 u - nritsili - .....,fraio.....misuit w.. LIL441 Al .7..b? dt-% --0.0-15,10 750d- WOO "--.21XO 70X SOX 27000 68..9' 23.0' 8 8 ' "MO Cross section of the main building. am. 52.5' 740 -.1 ?J 3. - Boiler; 2 - Induce&draft fan; 3 - Shaft mill; 14. - Cyclones; 5 - Belt feeder; 6 - Turbogenerator; 7 - Electric feed pump; 8 - Turboine-driven centrifUgal feed pump; 9 - Deeerator; 10 - Forced-draft fan; 11 - Staff accommodation. CHEREPETi EUIVEBIZED-CUL BIGH-PRESSURE GEES Source: Elektricheskiye Stantsii, 19471 No. 51 p. 111 TK4.E725. PLATE 16. ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 CHAPTER II CONSTRUCTION OF THE MAIN POWER PLANT BUILDING 1. DUPING MATERIALS - The principal building materials used in the construction of the main power plant building and the switch Ileum are the following: a. Reinforced Concrete - monolithic poured-in-place (with either bar l an4 rigid welded steel skeleton reinforcement) and precast (with bar ek oz pre-stressed wire reinforcement). Reinforced concrete is used for frames, columns, beams, girders, floors, foundation blocks, slabs and mats, roof supporting beams, well panels, roof cowring slabs, and stacks; b. Steel - used for framesscolumns, beams, girders, oof trusses, open steel grid floorings, window sash, steel plate stacks (when the stacks are built on top of the building); c. Brick - used for curtain wells braced to structural steel or rein- forced concrete frames, also for stacks.* d. Wood - now used very seldom in any part of the power plant building. In earlier plant construction wood was used for roof trusses (later replaced by steel trusses) and roof sheathing (later replaced by reinforced concrete slabs). At present wood is till used for roof trusses, roof sheathing, window sash, etc. in office and staff accommodation buildings. 2. A.XLMIRaM:g_QZI_TIIMIAMBILPILTirPREA4EM"P'41. The construction of the main power plant building has received different kinds of treatment, depending mainly upon the time when the plant was built and the type of the plant layout. * In older stations brick was used for wall-bearing construction, but now is very seldom used for the main power plant building. ?36? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Structural practice in the building of power plants has varied widely with time mainly in that the prevailing use at the outset of Soviet rule of poured-in-place reinforced concrete with bar reinforcing for the main supporting frames andtalebehtslof the bilildihg has been gradually shifting to the use of poured-in-place reinforced concrete with rigid welded stool skeleton reinforcement and precast reinforced concrete parts with reinforcement of bars and prestressed wire. The type of the plant layout influenced its construction mainly because in the main power plant building the two-story wide-span and high-roof transverse frames of the boiler house and the turbine hall can be differently arranged with the multistory short-span frames of the bunker, smoke-eliminating and feed-water pump and tank sections, and with those different arrangements different parts of the building can serve as the principal structural supporting frames. The first Soviet power plants (Shatura, Dubrovka, first part of the Gor'kly plant) have special layout designs and are built in a different way from any others. The Shatura peat-firing plant (Plate 41 Fig. 2) had two and later three separate boiler houses with separate bunker sections built transversely to the turbine hall which connects them. Separate steel trestles for peat delivery are built for each boiler house. The main power plant building is therefore not one compact structure, but consists of four separate buildings (3 boiler houses and one connecting turbine hall). The buildings are constructed as separate reinforced concrete frames with brick curtain walls and steel roof trusses. The Dubrovka peat-firing power plant (Plate 5) has the turbine hall located between two boiler houses and its steel roof trusses are placed on brackets supported by the columns of the two adjoining boiler houses frames. ? I Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Art> -4_ These early power plant designs did not form any patterns to he followed in later built plants. The subsequent power plant layouts were of the four principal types described in Chapter One. Power plants built in the twenties and early thirties belong mostly to the First Type. In the second part of the thirties the design of the Second Type was introduced and became the prevailing pattern up to and after the war, when Type Four was designed. Type Three design did not become popular and there are few examples of this type of layout. B. CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE FIRST TYPE DESIGN The main structural features are: Structural taas: poured-in-place reinforced concrete frames or steel frames (in cases when the load-hearing capacity of the soil was low and there was danger of foundation settlement, or when the construction job had to be completed in a short period of time). Wall covering2A brick curtain wells. Roof construction: Steel trusses, and reinforced concrete roof beams. Roof coverings; wood sheathing hoards, later changed to reinforced conerete slabs. Floor, construction: reinforced concrete slab, beam and girder con- struction and steel grids on steel stanchions. Crane girders in the machine wall: -steel, solid web. Overhead bridge in inihe generator room. 18 am., WM Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Reinforced concrete columns of the outside well of:the generator room are built in four different ways; 1. Column of a rigid bent. 2. Stepped column. 3. Double column. 4. A-typo column. Fig. 5 ? Reinforced concrete crane columns for generator room. depending on the typo of roof-supporting structures (steel trusses or reinforced concrete beams) and the load-lifting capacities of the over- head bridge cranes. Foundations: poured-in-place reinforced concrete slab and mat footings (often on wood or concrete piling in lines or clusters) and separate monolithic reinforced concrete blocks for each boiler and each turbogenerator sot. The reinforced concrete blocks for the turbogenerator sots have a specialfbrm in order to permit the instsUation of pipes and cables also the condenser. Typical reinforced concrete foundation block for a turbogenerator set of 50,)00 kw. and 1,500 rpm. is shown on Plate 18a, Fig. 1. These foundations are set 4 in. (13 ft.) underground, and as a rule, are placed on clusters or wood or concrete piles. Stacks: steel plate with an inside protective coating. They are placed on the roof of the main building extending 7-8 m. (23 - 26 ft.) above the roof top, 2.5 - 3.0 (8 -10 ft.) in diameter. hel_lmlvs.....Titha 5-6 in. (16-20 ft.) with the exception of the inner wall of the bunker section and the boiler room where the columns placed between boilers are spaced 15-18 in. (49-59 ft.) -39- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Framer supportim the smoke-eliminatina installation In some buildings of the first Group design the smoke-exhaust flues, induced-draft fans and stqcks are placed on a special reinforced concrete frame built in the boiler house. This special frame. is supported on one side by the columns of the feed pump and tank section frame and on the other side by reinforced concrete columns erected between boilers. In other stations of this first Group the smoke discharge install- ations are placed directly on top of the upper floor multi-story frame of the feed pump and tank section. Constructiorkof4some main mwor 'plant buildimizs of the_ First Grow. Thc Ivanovo, 100,000 kw. peat-firing GRES is shown in Plate 74 The trusses of the boiler house rest on the reinforced concrete frames of the bunker section on one side and of the turbine hall on the other side. Inside the boiler house space the 3-story poured-in-place reinforced concrete frame of the feed pump 'Ind tank section is built, and on the top floor of this frame are placed the induced-draft fans and the steel stacks. In the frame for the turbine hall and feed pump and tank sections the columns are on-116.4 ft. centers; in the bunker section. frame on 49.2 ft. centers. The roof of the boiler house is supported by Warren-type cambered steel trusses of 86 ft. span. In the bunker section and the turbine hall the roof is on reinforced concrete beams. The roof covering, originally of wood sheathing, was later replaced by reinforced concrete slabs covered with ruberad. The outside walls are brick, of the curtain type. -40- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 In the St4inara4 pulverized-coal ORES (Plate 10) the smoke-eliminating installations are placed on a special monolithic reinforced concrete frame in the boiler house space; it rests on reinforced concrete columns placed between the boilers at one end and on reinforced concrete columns of the feed pump and tank section frame at the other. On top of this special frame short columns are placed, which support one end of the Warren-type parallel-chord steel roof trusses. The other ends of those rest on the reinforced concrete three-story bunker frame. The special frame for the smoke-eliminating section adjoins a 5-story reinforced concrete frame of the feed pump and tank section, which forms a part of the reinforced concrete frame of the turbine hall. The roofs of the bunker, feed pump and tank sections And the turbine hall are supported by reinforced concrete beams. The roofing is of ruberoid laid on reinforced concrete slabs. The Zuyevka 200,000 kw. pulverized-coal GRES (Plate 9 and 9a) has a construction very similar to the Stalingrad ORES. In the ftznetsk pulverized-Coal TETs (Plate 11 and 11a) and in the Stelinworsk pulverized-coal ORES (Plato 12 And 12a) the smoke-eliminating section is placed directly on the monolithic reinforced multi-story frame of the feed water pump and tank section. In each plant the steel roof 'trusses of the boiler house are supported by the reinforced concrete frame of the bunker se6tion at one end-ad-by that of the feed water pump and tank section at the other. In bah stations the frames of the building are of poured-in-place reinforced concrete with reinforced concrete roof beams, except in the boiler house and in the turbine hall, whero the roof is supported by steel trusses. 'The roofing is of rubeAld laid on reinforced concrete slabs. -41- ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 _ The construction of other power plants belonging to the First Type built in the twenties and thirties is similar to the one described above, but with some minor differences. A postwar deiTnof thF1st Tv-le, also has main supporting frames of poured-in-niece reinforced concrete, not with ordinary bar reinforcing but wi?th welded ri? sgetons (see Plates 17a). This method has the advantage of eliminating the necessity of scaffoldings for the entire building to support the forms for the poured-in-place concrete; used instead are small portable forms suspended from the rigid welded steel skeleton. This rigid steel skeleton is strong enough to carry its own might and also the weight of the suspended forms filled with fresh wet concrete. When the concrete hardens in one section, the portable forms are transferred to the next. The rigid welded steel skeleton, embedded in the poured concrete, acts as its reinforcing. On Plate 17a the two frames of the bunker and the feed-water pump and tank sections are shown. The roof trusses of the boiler house are supported by those two frames. The turbine hall, located to the left of the feed-water pump and tank section, is not shown on this diagram. Induced-draft smoke fans are placed directly on top of the feed-water pump and tank reinforced' concrete frame which also supports the steel plate stack 14 in. (46 ft.) high, 4 m. (13 ft.) in diameter and weighing 26 in. tons: The details of the load-bearing skeleton reinforcement are shown on Plate 17b. The welded steel skeleton of a column is composed of four laced angles. Supplementary reinforcing bars are placed at the outer edges Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R00160nosnnnR_4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 of the section. Special supporting angles are provided for the assembly . of rigid frames which consist of girders, beams and braces. The connection of column sections is made with the principal four angles and with the supplementary bar reinforcements. C. STAMM Main power plant buildings of the First Type design can easily be recognized as they are the only ones ams having stacks placed on the roof. The other three types have freestendinp stacks outnide the main building. 4 Those stacks areAbrick or reinforced concrete construction (Plate 19). They are located approximately 50 m. (164 ft.) from the main power house building, and are connected with it by 2-3 underground smoke flues. At the base of the stack the flues are brought to the surface and are connected with the stack shaft. The connection of the flue to the stack is reinforced with a cast iron ring 5 cm. (2 in.) thick. At the bottom beside the flue connectiontwo soot doors are provided. The stacks stand on reinforced concrete foundation mats supported by rein? forced concrete piles. The height of stacks is determined by the fuel combustion draft requirements and also by the amount of sulphur in the smoke discharge. Sone Soviet coals have a high sulphur content, and bee special smoke smoke cleaning installations havetdeVised to eliminate injurious sulphuric gases fin. the smoke. Previously, without these cleaning installations, much higher stacks were needed than those built under current practice. The brick masonry stack shown on Plate 19 Fig.1 is 120 m. (394 ft.) high . Its foundation is a reinforced concrete mat supported by 252 reinforced 43? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 concrete piles. Up to the 20 m. (66 ft.) level the stack is octagonal with an inside diameter of 9.95 m. (32 ft.) and an outside diameter of 13.20 m. (43 ft.). The shaft is straight vertical up to the 66 ft. level. Above 66 ft. the stack is round and conical with an outside diameter of 12 m. (39 ft.) at the bottom and 5.76 in. (18 ft.) at the top. The brick walls are 103 cm. (40 in) thick at the bottom and gradually are reduced to a thickness of 0.38 m. (15 in.) at the top. Up to the 20 in. (66 ft.) level the shaft is lined with a fire brick lining 25 cm. (9.8 in.) thick, which is insulated from the structural brick masonry by a 10 cm. (64 in.) layer of tripoli. In the upper conical part of the shaft the fire brick lining is 12 cm. (440 ins) thick and the insulation tripoli layer is 5 cm. (442 in.) thick. The monolithic reinforced concrete stack shown on Plate 19 Fig. 2 is 115 in. (377 ft.) high. It is divided into 7 sections, each section being of constant wall thickness decreasing from 1.05 in. (41.3 in.) in the bottom section to 0.8 in. (31.5 in.) in the top section. In order to protect the reinforced concrete from the corrosive effect of the sulphuric gases the stack has a fire brick lining 25 cm. (9.8 in.) thick in the first three lower sections and 12.5 cm. (4.9 in.) thick in the four upper sections. The out- side diameter of the .2-tack is 10 m. at the top. D. CONSTRUCTION OF 11ib. ItAII (32.8 ft.) at the base and 5 m. (16 ft.) POWER PLANT BUILDING OF THE SECOND 'ME DESIGN - Structurally the most important difference between the First and the Second Type design is the removal from the boiler house of the smoke- eliminating installations. The boiler house is located between the bunker section on one side and the feedwater pap and tank section on r Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 the other. The se two multistory short-span frames and the outside wall of the turbine hall constitute the main load-bearing elements of the building,. The columns of the bunker and of the feedwater pump sections adjacent to the boiler house have stepped extensions which support the roof trusses of the boiler house. The smoke flues at the back of boilers 'are laid on the ground floor of the bunker section, where the smoke-cleaning cyclones and induced- draft fans are also installed; sometimes they are placed outside the main building in a special small annex building which stands between the mai n building end the freestanding stacks. Main structural features of the main building of the second Type design are similar to those of the First Type design with SOW changes: Structural type: reinforced concrete frames, are built mostly of pre- cast structural members of complete structural parts of the frame. After the War, in 1946, a new method for reinforced concrete framed was d ?signed by the Teploelektroproyekt? namely monolithic reinforced concrete frames with rig lodd-bearing welded steel Skeletons as reinforcement. This method was also applied to some power plant buildings of the First Type design built after the War. Plates 20A - 211E show the details of this kind of construction. The steel welded skeletons are prefabricated in sections of one or a group of structural member!, forming a Dart of the frame. These prefabricated parts weighing 3 to 5 m. tons (depending on the lifting capacity of the assembly , crane), with wood or steel forms attached to them are then lifted and welded to each other in the process of building erection, and the concrete is poured into these forms. Sometimes the monolithic parts are combined with some precast structural members as Shown on Plate 20E fig. 8. Besides reinforced concrete frames steel frames are also used. (See .12-tWe- -4?,7 -45- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 - (See Plate 21). The main steel frames are shown in Fig. 1 with the section of principal structural members. Figs. 2 and 3 give two different treatments of principal frame connections, the rigid-frame type (Fig. 2) and the later type with hinged frame connections (Fig. 3). At present (1957) the construction design of steel frames is based on the following principles: 1. The transverse combined frame is composed of main supporting rigid frames and adjoining hinged structural members. 2. The number of rigid joints is kept at a minimum and they are executed in the form of connections between columns and trussed cross girdere. 3. The transfer of transverse stresses in joint connections is accomplished through supporting plates and the connection between con- tinuous girders and columns is made by flange joints. 4. The solid web column and continuous girder sections are made in 1-form composed of three built-up plates. Wall coverings: brick curtain walls for the turbine hall outside wall ere 51 cm. (20 in.) thick; for the blinker section outside mall, 38 am. (15 in.) thick. Roof eonstruption: steel trusses and reinforced concrete beams. Roof covering: reinforced concrete slabs. Roofinm: ruboroid or corrugated steel sheets (hen roof sUppor:iing construction is of steel trusses with steel purlins.). agaz.ssnUabacjant-: reinforced concrete slab, beam and girder construction and steel grids on steel stanchions. Overh9ad bridge .cranes: in the turbine hall and often in the boiler house. -46- " - nnt-laccifiPri in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 crane girders: steel. atillomIsoaczete_..jci4uma: for the outside wail of the turbine hall - as in First Type design (see p.3.9.). Foundations: the separate poured-in-place reinforced concrete foundation footings for each piece of auxiliary machinery has been replaced by a monolithic reinforced concrete basement floor mat on which all auxiliary machinery equipment and cables are laid. (See Plates 1,?B and iso.) Separate poured-in-place reinforced concrete footings were still used for each column and for each boiler, and special reinforced concrete blocks, placed 4 in. (13 ft.) underground for each turbogenerator unit (see Plate 18A). In monolithic construction with rigid steel welded skeleton reinforcement the embedment of the column in its foundation footings is shown on Plate 20D, Fig. 5. Stacks: are built outside the building as described above under C. Examples of the Second Type design construction are: the power plants in Nesvetay (Plates 13 and 13A) with separate building for the smoke- -eliminating section; and in Moscow, the Stalinsk TETs (Plate 14), where the smoke-eliminating installations (electric cyclone filters and induced- -draft fans) are placed on the ground floor of the boiler house. The Nesvetay main power plant building, built in 1936-38, has steel frames, one for the bunker section, the other a combined transverse two-aisle frame for the feed-water pump section and the turbine hall with continoous two-span transverse girders. The steel roof trusses of the boiler house are supported by the stepped columns of the bunker section and of the feed-water pump section. The transverse frames of the machine hall and feed-water pump section are on 6 m. (20 ft.) centers and of the bunker section Dari - Aniti7ed COM/ Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008 -4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 on 9 in. (30 ft.) centers. The smoko-eliminating section annex hae transverne steel bents. The boiler house and the machine hall are equipped with over- head bridge cranes. mamzurnisbsi..) kfk gRFA (470 591 NI 37? 19' E) is similar to the power plant in No svetay. The Ste] insk TETs in Moscow has reinforced concrete frames partly of pre- cast structural members. The roof trusses in the turbine hall ard the boiler house are of steel; the bunker and the feed-water pump section have rein- forced concrete roof beams. The boiler house has no overhead bridge crane. Of interest are the foundations of the boiler house, built an one monolithic reinforced concrete mat. E. CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE THIRD TYPE DESIGN Structurally the main difference between the Second and the Third Type design is the "disj ointing" of the main power plant building into two separate buildings. One contains the boiler house, placed between the bunker section on one side and the Essoke-eliminating section on the other. The other building contains the feedwater pump and tank nection and the turbine hall; it is connected with the first building by an 80-100 ft. long gallery housing the switching instilations. The main structural features do not differ from those described for the Second Type design. This typo of construction has not been widely used, as it proved more expensive and required a wider area than other types. An example of this type if the Orsk TET s (plates 15 and 15A), built as reinforced concrete frames with reinforced concrete roof beams. F. CONSTRUCT/ON OF THE MAID POWER PLANT BUILDING OF THE FOURTH TYPE DESIGN This type is the latest in Soviet power plant construction. It was designed by the Institut Teploeloktroproyekt in 1947. At that time 4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 7?. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ; also new regulations were issued under the title "Principle Regulations Governing the Design of Electric Power Plants, Substations, and Heat and Power Distributing Syetems." Main articles of those regulations relating specifically to the structural part of the main power plant building construction are annexed at the end of this Chapter. The Fourth Type design has been prevalent since 1950$ in the Fifth and Sixth Piatiletkaq some power plants of the Second Type design,' however, ire still being built. The layout of the Fourth Type design is shown on p. /2. The main structural features are similar to those of the Second Type design (see p. 46. ). The Fourth Type layout has been designed in steel, in monolithic reinforced concrete with rigid welded steel skeleton reinforcement and in precast reinforced concrete with some prestressed-wire-reinforced structural members. The steel frame construction is ehown on Plates 22A and 223. stok transverse frames of the building are on Fig. 1 with the main - structural members given. (Allowable steel stresses 1400 kg/Cm 19,900 lb/in). Figure 2 shows the boiler house and the turbine bail- ee rigid steel frames. The steel columns between the bunker and the food water pump section are connected with those two frames by hinged structural members. All steel columns are rigidly connected withiheir foundation footings.. The weight of steel required by this design is given in the table on Plate 220. Plate 220 dhows the details of the 4 principal joints. another desp of the Fourth tv-pe in stoolie:Shown.on Plate 23A and 233. Here two alternatives are considerad,' :In the first scheme ' ? ? the combined frame or the bunker andj:rdwat'7,p_um.pisc.toi,-,Mde:th.?: a ? ? -? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 principal rigid supporting element of the whole building, with the two outside walls of the turbine hall and the boiler room attached to this central frame by hinged structural members. In the second scheme the two other frames of the building, namely of the boiler house and of the turbine hall are made rigid; they are connected by hinged structural members to form the middle frame of the bunker and the feed-water pump section. The second scheme is considered more advantageous and easier in assembly, having a smaller number of rigid joints. The construction of the Fourth Type in monolithic reinforced concrete with rigid welded steel skeleton reinforcement is shown on Plates 24A and 248. The transverse frames of the building are shown on Fig. 1. For this medium-size power plant the weight of equipment on one square meter of floor space is calculated to be 1 m. ton (20.48 lb./ft2). The floor heights are 12-18 m. (39-59 rt.). The load on a column in the lower floor sections is calculated to be 400-600 m. tons. The combined two-aisle multistory frame of the bunker and feed-water pump sections is built as a monolithic reinforced concrete frame with rigid welded steel skeleton reinforcement. It consists of a lattice of steel angles and round bars melded together. The frame of the outside wall of the turbine hall is of reinforced concrete. The frame of the boiler house (except the inside wall up to the 25 m. (82 ft.) level) with the upper floor of the bunker section, and the structural members supporting the roofs of the turbine hall and boiler house are of steel.. The inter-story floors in the bunker and the feed-water pump sections are of beam-and-slab monolithic reinforced concrete construction. -50-- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 am. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 41. Details of the steel skeleton reinforcement of the monolithic reinforced concrete frame of the bunker and the feed-water pump socpions are shown on Plates 24A and 240. In the process of construction the rigid welded steel skeleton supports only its own weight and the weight of forms which are attached to it and filled with poured-in-place wet concrete for the height of one story. When the building is finished the frame members must carry the complete dead load of the building and also of the equipment. This combined load is much greater than that during construction: for girders and beams 2-3 times greater, for columns in lower story sections 8-10 times greater. Thus the original rigid welded steel skeleton is not sufficient, as the final reinforcement and additional reinforcing steel round bars must be added. The steel skeleton is mounted in prefabricated sections of steel members for one floor together with attached wood or steel forms as shown on Fig. 7. Al]. columns are rigidly embedded in their reinforced concrete stepped footings. The erection of the rigid steel skeleton for the bunker section is shown on Plate 24B, Fig. 8. In 1956 the Institut Teploelektroproyekt designed am/form construclon scheme of the main power plant building 2i2.1hjIP,.,2.c_n_willips.,/ez5Lui,jazz_casli sagmalLsammsda. (Plates 25A - 25D) On Plate 25A, Fig. 1 the cross-section through the building is shown with the transverse precast reinforced concrete frames, and sections of their principal structural members. The suggested dimensions of the plant make it possible to install turbogenerators of various capacities (250000, 50,000 and 100,000 kw.) and boilers of 160 to 220 t./hr. steam -51- Declassified in Part - Sanitized Copy Approved for Release 2013 . A-R _ - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Vroducing capacities without. changing the aisle span or the bay length of the structural frames. In ease some additional units should be installed the building need only be extended lengthwise. According to this design a TETs of 150,000 kw, capacity will have 26 bays each 6 m. (19.7 ft.) long making the total length of the building 156 M4 (512 ft.). The two-aisle multistory rigid frame - Plate 25a, fig. 1 (07WS B, 0, D) of the bunker and feed water pump sections ensure the trans- verse stability of the building. The outside columns of the turbine hall (mi A) and of the boiler house (now 1') are connected to the central rigid frame by hinged roof beams. The longitudinal stability of the building is ensured by longitudinal girders connecting the transverse frames and columns in the outside rows. All the elements of the building sUperstructure (columns, girders, beams, floor and roof pare1.4 are of precast reinforced concrete. Wall coverings are of reinforced foam concrete panels. For columns, concrete "300K is used (with a compressive strength of 300 kg./cm2 = 426 lb./in2); for all other members concrete n2001, is used, (with a compressive strength of 200 kg./cm2 0 284 lbs/1n2.) The cross sections of the columns have a uniform width of 0.6 in. (24 in.) and depths of 2, 1, 0.8 and 0.6m. (78, 39, 31 and 24 in.). For the inter-story floor covering a untform type of panel is selected (Fig. 2). These panels have two longitudinal and five transverse ribs. The panels are 5.351 5.55, 5.65, 5.97 M. (17.6, 18.2, 18.6, 19.6 ft.) long and 1.49 in. (4.9 ft.) wide. Rebates 60 x 70 mm. (2.36 x 2.76 in.) are provided along the longitudinal ribs of the panels for setting flat cover plates for floor openings. The openings between panels are obtained by moving apart the panels for the necessary distance. -52- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 The bunkers are designed in the form of two longitudinal partitions made up of precast reinforced concrete ribbed panels which are supported by beams resting on the cross girders of the frame. The transverse partition walls of the bunker also serve as cross-girders of the bunker section frame, on them rest the floor panels at floor level 23.00 m. (76 ft.). The bunker feed hopers are of steel. The roof beams of the turbine hall (span 27 m. 88,6 ft.) of the boiler house (span 24 m. Z.! 78.7 ft.) are of precast reinforced concrete with pre- stressed wire reinforcement. They support large reinforced concrete roof panels. The precast structural elements are fabricated in sections weighing not more than 15 m. tons. At the building site the prefabricated seCtions of the columns are joined together to form sections weighing up to 40 m. tons, if they are to be assembled in places where the crane beam can lift such a. load. Thus most columns are erected completely assembled, with the exception of the outside wall of the boiler house, where the assembly jib crane been is most extended and can lift only shorter sections, which must be connected in the process of erection. The column sections are connected on the ground by welding the pro- truding bars of their reinforcement and then pouring concrete over the joint to make it monolithic (Fig. 3). The connection of column sections in the process of erection (field joints) along row D is accomplished by welding the reinforcing bare of these sections, but without pouring concrete over the joint, because of the considerable height at which the work must be dons (Fig. 4). These joints are provided with central steel plates for better transfer of vertical forces, and with steel side plates welded to steel hoops, to fasten the two connecting column elements so as to withstand any bending moment which night tgeur in the column Joint (Fig. 4). The ends. of ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized CO .y Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 column elements to be connected are reinforced with steel mash Which increases the strength of the concrete in the area of local compression. To align.the two connecting column elements assembly bolts are provided. After adjustment, the side plates are welded and the assembly bolts and supporting angles are cut off. Than the joint is cemented. Such a column joint can withstand a vertical force of 250 m. tone and a moment of 200 ton-meters (1400 ft. kips). When the building has a basement and a floor above it at gound level 0.0 the Iris joint of the column with the foundation is formed by embedding the column/a recess in the foundation footing (Fig. 5); the floor cover then rests on the top edge of the foundation footing. To ensure the transfer of vertical loads to the foundation footing, the end of the column is provided with a pin, thus providing for filling the space under the base of the column with concrete. The column is adjusted and fixed by means of wedges. The foundation recess is provided with an opening for cleaning and flushing. The vertical force transferred by such a column joint can reach 600 m. tons and the bending moment 50 in. ton meters (360 ft. kips). When the building has no basement and no floor at gound level 0.0, the joint of the column with the foundation is formed by welding the projecting reinforcing bars of the foundation and the column (Fig. 6). While, the column is being set up the vertical load is transferred through a steel pipe. The bendingmaneits can be transferred by the reinforcing bars only after welding. The melding of the four corner reinforcing tars ensures the necessary stability to the column in the process of erection. After all reinforcing bars are welded and the joint poured with concrete, all the live load is transferred from the column to the foundation. Declassified in Part- Sanitized Copy Approved forRelease2013/02/25 ? CIA RDP81-ninalpnnl Rnnnonnno A Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 The joint of a cross girder with a column shown on fig. 7 is formed by welding,the projecting upper and lower reinforcing bars of the two members ,with the aid of steel insertion rods. Welding is done by the submerged-arc -,method. Concrete is then poured into the joint to mike it monolithic, in order to'provide compressive strength. Well coverings are of reinforced foam concrete panels (see fig. 8). On the outside the panels are covered with a 35 n10316 (1.4 in.) rough-finished lxyer of heavy concrete 11200*. The foam concrete is of the nark 75 (with a compressive strength of 75 kg./cm? = 1066 lb./in2.) and a volume weight of 900 kg./63 = 55 lb./ft3. The fastening of panels to the columns is flexible, with bolts, so that the panel load is not transmitted to the columns. The substructure of the main power plant building is usually built in the form of a great number of separate foundation slabs for various units of ewipment, tunnels, channels, etc. placed at different levels. In this project, one basement floor is designed, under the turbine hall, bunker, and feed water pump sections (see plates 18B & 18C). Foundations for auxiliary equipment are placed in the basement at level 0.0. The basement floor is of flat precast reinforced concrete slabs with prestressed vire reinforcement 3 m. x 3 m. (10 ft. x 10 ft.) and 0.25 m. (10 in.) thick. The slabs rest at their corners on precast rein- forced concrete columns with caps. This construction has the necessary height to accomodate all the auxiliary equipment. Column foundation footings, supporting walls, and other structural elements in the substructure are of prestressed reinforced concrete. The foundation slab under the banding, and the foundations blocks under the turbogenerator and boiler are of monolithic reinforced concrete. In special cases when ground water is high, the basoment floor is placed on a continuous monolithic ribbed reinforced concrete it. The amount of reinforced, concrete necessary for the new-design of basement floor is 1.2, m3/m2 (0.146 yd3/ft2) of -55- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 TOLE / Ira DE MAT UM MEM =UM BEEISS. MS SUE Ma mart ramia aansa zona =I AIM QOM .QF & =2 Mal lit Main. as of .the structural mem timber ot sizes of each type Weight of sash structural member atone Number of units Volume of re- 110.913111Lagandd *3 7d3 1ii..21marstrantacit Collates Cross girders' ,of supporting beams Floor beams Floor and roof panels Bunker members Various members (flat panels monitors etc.) 44====lvija=1:0416=2===50==?=140 24 13 2 6 2 5 3.5 - 15.6 6:5 10.3 17.5 - 21.0 0.5 - 3.4 114 - 2.6 1.1 6.2 549 228 60 721 1943 360 2,400 3,110 778 1,010 462 600 540 700 1,579 2,020 -5566 740 375 490 6.70k .8400 p. Substructur, Colrain foundation footings and shoes Columns Concrete blocks Supporting im-Uti Flat slabs and panels for floors ard ceilingi Beams, ducts, passage tunnels cable support blocks Various elements Total r. aggitattarandartmaa 9 3 4 1 6 a 2.0 - 14.5 1.0 3.0 0.4- 1.2 1.7 0.07 - 5.6 0.07 - 1.8 0.31 - 2.3 270 480 922 86 1,046 1,414 1,9)0 1,174 428 434 146 1,138 213 87 1,520 560 565 190 1,480 277 117 2,480 3,230 Source: Stroitellnaya Promyshlennost I, 1956, 163. 6, Me 24 -56- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ( floor space as compared to the required volume of 1.35 OM (0464 yd3/ft2) of reinforced concrete for the previous method of separate foundations for auxiliary equipment. The list of precast reinforced concrete structural members for the con- struction of the main pOwer plant building is given on table 1. The total volume of reinforced concrete for the superstructure of the main building amounts to 7100 m3 (250;000 ft3)of which 95% or 6700 m3 (256,000 ft3) consists of precast members.. In the substructure (together with the foundations for the turbo-gene- rators) the total volume of reinforced concrete amounts to 15,020 m, (530,000 ft3), of which 24% or 3620 m3 (128,000 ft3) consists of predast members. The monolithic reinforced concrete in the substructure is used for the continuous foundation mat and for foundation blocks for the turbo- /operators and boilers-. photo showing a main power plant building in erection according to the 1 above design is shown on Plate 25, Te 9. The latest regulations, issued in 1947; concerning the design of thermal power plants recommend instead of a building frame entirely in reinforced concrete (Plate 25e *fig: 2) a mixed type construction for the main building, 1 (Plate 25e fig. 1); The recommended scheme consists of precast reinforced concrete for the main structural frame and for its heavily loaded members and steel for lightly loaded meMbersgofmembers placed at high levels, such as the _ r upper part of the turbine ball waltiabove-the crane girder, the Upper floOr framip of the bunker aid feed water Dump sections,the upper parts of the boiler house inside wall abionr,", the roof of the bunker section; and for crane girders. -5q- c Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 014 ? ? 7 - ? TABLE g =7 STAMM) MIMD-PirtPE CONSTRUCTION 0 4_. a EEL L DP: 8 ? IL 111 ; 11_,11 _ Diver structural members Mixed-type construction All-reinforced-concrete of the bUilding frame design (Table 25e, fig. 1). conitruction design built either in steel or Weight at required steel. (table 25e, figr2). in reinforced concrete. Volume of required reinforced concrete. Modbers of the upper part of the turbine hall outside mall (above creme girders). m tons 0 ..3 5.94 6.3 8.2 NeMbers of the upper floor frame of the bunker and feed-water pump section. I 17.2 . 57.0 74.2 Members of the upper 1;:...0 Iplitz.'bf the boiler house inside wall (Above the roof of the bunker section). 8.7 8.4 11.0 Source: Elektrichi4kiye'Stantsiii-1947) VO:77, page 10, =58- - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? The amount of material (steel or reinforced concrete) required for the construction of the upper structural members for 181a. (59 ft.) length of building (width of one boiler unit) - see Plate 18a - according to the two alternative treatments (Plate 25e, fig. 1 and 2) is shown on table 2. The total amount of material (steel and reinforced concrete) required for the construction of the entire frame for 18 m. (59 ft.) according Ur those two alternatives is: Alternative 1 Alternative 2 (fig. 1) (fig. 2) Reinforced concrete 451 s3 (590 id3) 553 u3 (720 7413) Steel construction 107 mwtons 6? ..ton. ftwoles of the iburthlhis dodo The 3 large newly built thermal power plants, the Mironovskaya 400,000 kw.. coal-fired GUS near Artemovsk in Stalinskaya oblast', the Slavyansisla ORIS, and the Cherepeto GR ES (projected capacity 600,000 kw.) are probably built according to the Fourth-Type layout design (see also plate 16 aad 16a). There may be only small differences in their transverse dimensions; the In4eiih of the building* will change with the nuiber of installed boiler and turbo-generator unite* -59- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 APPENDIL "PRINCIPAL REGULATIONS GOVERNING THE DESIGN OF ELECTRIC POWER PLANTS, SUBSTATIONS, HEAT AND POWER DISTRIBUTING SYSTEMS" ISSUED BY THE MINISTRY OF ELECTRIC PCWER STATIONS USSR IN 1947. PARAGRAPHS RELATING TO THE CONSTRUCTION OF THE MAIN POWER PLANT BUILDING AND THE DISTRIBUTING INSTALLATIONS, Construction alb/ Baill blar lsat =Liu Z. The bay length in the main buildings should be uniform and a multiple of the width of the boiler unit. Ja. Deformation Joints are provided in the main building at the end of a boiler *lit. Settlement joints are provided in places where any structure adjoins the main building. Deformation joints in the principal frame of the main building are built in the form of double Aolumns. ...1122.. Stiffness and stability of the building are achieved by means of rigid frames, both traisverse and longitudinal. al, In the ease where the skeleton of the main building is of steely the Constructien is as follows: rigid:bents with columns rigidly connected with the foundations; hinged members between the bents; continuous welded members; field joints on erection 1iolt6z. sa. in cases where the skeletonof the main building is of reinforced concrete, the structural members carrying heavy loads are of reinforced concrete. Steel. is used for the lightly loadedelementi, which forthe most part-carry their own load and that of the facing; steel is also used for long? span members subject to bending. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - 322. The crane girders in the turbine hall are of steel as a rule. laho Bunkers, as a rule, are wholly of steel. 321. The boiler and engine roam end walls (permanent and temporary) should be built on a steel frame. 3116.. A temporary end wall must be built so that the work in the part of the building which is to be expanded may proceed without dismantling of the wall; construction of an end wall should also be such that the wall can be moved to form a new end wall. 322. Concrete n140" (2,000 lb./in2) should be used in the main reinforced concrete construction of the main building. 3211. Steel "3" (23,000 lb./in2) is to be used for the steel Construction of the Main building skeleton. 3224 The following construction is adopted fbrrthensogdi-tearing ro,9fraembAr_sestf the engine and boiler room in both reinforced concrete and steel structures with-6-7 m. (19.7 - 23:0 ft.) bays: ' a) with span up to 24.m. (78.7 ft.): steel frames with solid web beams; b) with span over 24 m (78.7 ft.): frames with latticed teams or roof trusses. 33.1. The inside walls separating the boiler room from other c9mpartments (engine room, service quarters, bunker gallery) are made of fireproof material; the thickness of the walls is: a) not less than 25 cm. (9.8 in.) for brick wells; b) not less than 20 cm. (1.9 in.) for walls of block material (ceramic blocks, slag-concrete blocks, etc.). 2320 The wall covering for the main building frame is to be of fireproof and frost--and humidity-resisting construction. mg. The outside uslls.(brick construction) of the boiler room above the boiler servicinglevel are to be half a brick (one brick* American notation) in thickness for any climatic conditions. -61- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 213,. Walls thicker than one and a half brick .(threiez-13rhiCII:AM6ridiirlir::4 A .(i11 steel.frdthe?constiuotions) should be self?supporting. .The use of reinforced concrete walls and partitions is not allowed as a rule. . MI. Compartment partitians of plant-service distributing installations with % small-.size oil or air circuit breakers consist of steel skeleton and gypsum or asbestos-cement panels. algt, Roof covering load-bearing members are of fire-resistant ot semi-fire resistant materials. 327. The roofing of the main building consists of three layers: a layer of rUberoid over two layers of artificial parchment paper with mastic adhesive. ax. A special basement is provided under the engine room and the deaeratar compartment to acommdate the underground communications. Auxiliary equipment and platform supports are installed directly' on the reinforced canorete floor above the basement, 332, The underground communication lines of the engine room are laid in duets and tunnels in cases where the ground water level is high. 314. The boiler room underground communication lines are laid as a rule in duets and channels. 342, The foundations of the turbogenerator units are of reinforced-concrete (for any unit capacity), or steel (for unit capacity up to 25,060 kw.). 3112. The boiler .foundations are of 'reinforced concrete in the substructure and of steel in the superstructure; this is achieved by extending t6 Steel skeleton to the ash compartment floor or by building Individual steel foundations: ?62 ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 _ 342. Ball mill foundations are built, as a rule, as separate reinforced concrete bases - (under the bearings, the electric motor and the reduction gear) which are located on the solid foundation slab of the bunker section. 3Aho Induced-draft fan foundations and the foundations for similar large size auxiliary equipment are built of lightly reinforced concrete on undisturbed ground. 3A1. Floors of service quarters and ceilings are of reinforced concrete or mood; floors and ceilings in toilets, showers and washrooms, laboratories, workshops, and archives are made of reinforced concrete exclusively. The partitions in the above.-mentioned rooms are of brick, half a brick (one brick American notation) in thickness. !bin RidEllailing InsUillationp Ind Switch &ma 3Agi, Whenever the control panel and main distribution installation are located in a structure outside the main building, a heated passage should be provided to connect these two buildings. 31h2. The building housing the main distribution installation with small size or non-oil circuit breakers is designed to have load-bearing walls, and floors and ceilings; the partitions are not included in the number of load-bearing structural elementS of the building. Partitions of compartments are assembled from precast gypsum or similar panels, which are set in steel frames. Light steel frames joined to the main skeleton of the building are provided for the panel erection. ug, Low walls and racks in bus.-bar construction are also made of gypsum or similar panels which are fastened to a frame. 3. The thickness of outside brick walls of the main distribution installation 'are not to exceed 38 cm. (15 in.) irrespective of the climatic conditions. -63- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Q. Floors, ceilings and roofs are to be of reinforced concrete laid on steel beams. 321. The roofing of the main distribution installation and that of the control panel should consist of three layers: a layer of ruberoid over two layers of artificial parchment paper with mastic adhesive. 12. No windows are provided in the building of the main distribution installation. Natural lighting is to be provided in the control panel building. 'Window casings aid sash are to be of wood. (Source: Elektricheskiye Stantsii, 1947). -64- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 74'5' ' 227 ' 7/9' 219,25 ? 690. 207,6 641o, 19475 ? ? ettes 207,0 UU t; 9500 :grow hi r : ? -??? - I 4:72.4 . L:N 28200 ''I '"I 114 . I 4_A litri 4800?r? 85(K) 16:21' *74' Monolithic reinforced concrete frame construction with rigid welded. steel skeleton reinforcement. The turbine hail is to the right of' the feed-water pAmp and tank section (not shown on 'this diagram) SECTION THRODGH THE MAIN POWER PLANT BUILDING OF THE FIRST-TYPE DESIGN Source: Elektripheskiye Stanton, 1949, #1, p. 28, TIC44725 PkATE 17A. -\ Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 'Ow 40.4.4 Fig. 1 - lagicnielded Steel Skeleton Reinforcement of a Column. Fig. 3 - Legend 1. Bar reinforcement of the beam. 2. Bar reinforcement of the beam-column joint. 3. Rigid welded steel skeleton reinforce- ment or the beam. 4. Plates for adjusting connecting lattices. 5. Erection suppo rte. 6. Erection angles. - 0 Fig. 1 - Legend 1. Stiffening Cross bars. 2. Joint connecting angles of the load-bearing reinforcement. 3. Reduction of the column to a smaller cross section. 4. Plates for adjusting connecting lattices. 5. Erection supports. 6. Bar reinforcement. 7. Rigid welded steel skeleton reinforce- ment. .Sec/ion A-A OwmmkA JL I. Fig. 2 - Details of a Joint of the Column Sections 1. Upper column section. 2. Lower column section. 3. Reinforcement of the skeleton lattice of the column. 4. Bar reinforcement of the column. 5. Joint angle. 6. Stiffening cross bars of the column. 4( la!! 1,111" +.? r?-A 1257 /o/6 k/&,- Bud afexy 4 _ 5010nEMIPIONETAPPP11111014WIMINIEPWAMA ?Mlib ,26.4/ 8050 9.500 3/. ' SW/10,44A1 etyma/PA-A Fig. 3 7 Rigid Welded Steel Reinforcement of a Cross Girder. DETAILS OF THE RIGID WELDED sTaL SKELETON REINFORCENENT FOR REINFCRCED CONCRETE FRAMES SHOWN ON PLATE 17A. Source: Elektricheikiye Stanton, 1948, #6, P. 14, TK4.E725 PLATE 17B, Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 - Monolithic reinforced concrete foundations of turbozenfrator units. Antipov, I. P. Arkhitektura elektrostantsiy, 1939, (TH110145) Elektricheskiye stantsii, 1954, No. 9, p. 22 (T14 .E(25). PIATE 18A. ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 S1fc77oN2T-I Paopeo no I-I I is A; st iiW 111111 ''',111 P7?? I dis /4 ? II II II II 0 ' 0 ao Pcope3 no ff-ff JEC17oiV7T 7T. Legend 1. Fbundation under the turbogenerator; 2. Foundations under the electric feed pumps; 3. Foundation under the turbine feed pump; 4. Foundation under the overflow pump and plantforms; 5. Foundation under the platforms; 6. Foundation under the separator; 7. Foundations under the platforms; 8. Foundation under the electric polAenset.4mmp; 9. Foundation under the condenser turbo-pump; 10: Foundation under the lubricating turbo-pump; il. Foundation under the lubricating turbo-pump; 12. Foundation under the lubrication-oil cooler; 13. Foundation under the overflow tank; 14. Cable tunnel. Foundation of a turbogenerator unit and of its 1U:ciliary equipment underneath the machine hall. TYPE OF CCNSTRUCTION WITH IND/VIDUAL FOUNDATIONS. \'72, Source: Elektricheakiye stataii, 1947, #1, p. 11 TAIL21.4.- -68- 1 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ,"St. " - , ; - ? ? ;Z.., ? ?c frz.,77 - Pape 3 no 11-11 Foundation under the turbogenerator; Electric feed pumps; Turbine feed pump; Overflow pump and platforms; Separator; Posts under platforms; Electric condensing pump; Condensing turbo-Imp; Lubricating oil turbo-pump; Electric lubricating oil pump; Lubricating oil cooler; Overflow tank* TYPE OF CONSTRUCTION WITH A BASEMENT FLOOR PLACED ON A MONOLITHIC REINFORCED CONCRETE MAT* Source: Elektricheskiye stantsii, 1947, No. 7, p* 12* PLATE 18C* Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: dIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 , d ' 340 I/1.6 36,0 /18./ 88.9izr "6.2eiv 240 613.9/ 15/5 saes' .1 rj., :L ? :el i.47:4 ;:E.Fi A -? 74 :! ,1 ' 21. .41 ..I..1 :?\41 440 r4 VA r. I .4 :,' ? :4 . Xer43Pa- 74 .4 MORHOe de/retitle *eae/14.4 .1. c .Jectio." 8,0 14,0 .9?5:,9 570;1;3 8,0 R6,25, 4-oase...) Kome.nktfait - The separate frames of the bunker, the deaerator sections and the outside wall of the turbine hall have rigid steel welded skeleton reinforcement. THE LOAD BEARING MONOLITHIC REINFORCED CONCRETE TRANSVERSE FRAMES OF THE MAIN POWER PLANT BUILDING OF THE .SECOND?TYPE .DESIGN Source: Elektrichealciye Stantsii, 1952, #2, p. 25. (T1c4.E725) ,PLATE 204 ?71- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ^ I -110112 c, 0l2. 21:( Pa3pe3 170 .1-1 P 9 00 O 0 0 6 I a /280- decliem 77 -27 Pave, "off-fl - L75:5 ? 41. 1 125- eteht.r.Aozn conehiumeft:two Acteintaa 4onaanumrfihmele omeado(n ..tj 11 /1 cIcl,Viok ae4At ?tr adt s Xonontfuffrenkmas apmamypa nele-477oncLe tceincrit . Fig. 3. ? Reinforcing skeleton of the -column. \027 Aaeg,71-1- .aonamtumenbtfaR cpAeamypa I 42/c47i6 itaikiZzceiri ekt Fig. 2 ? Reinforcing akeleton of the cross girder DETAILS OF THE RIGID STPRT, WELDED SKELETON REINFORCEMENT OF THE MONOLITHIC REINFORCED CONCRETE FRAMES SHOWN ON PLATE 20A. Source: Elektricheekiye Stantsii, 1952, #2 p. 23-26. PLATE 208. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 i - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ibe IT .4-1 4ono.nri1me.obitan apeampa 17c/c/iliomet ein)4teehfets'e 2?8 -754 Noll 'OS zr 018 2018 /94447;?onez-e, //IA zc eine / ? .4ononnameflot1a, apAiamypa A?job., 'Z Zi68 Pa3peJ no I-I Sec4'vi, 7-1 nal Pa3pes no If-47 Sec/A.4 .77- r Fig : 3 ? Reinforcing skeleton of the beam zysids ? ..-recho4 7- 2" Pospes no I-I Ir II IN 1 41 , r kid! , , . . akoOttnammlloommasoloilL. Arl s I fro . *dem. am, . t-to ,nna.vca. eeuee... 1I. ? 111111611111 Fig. 4 - Connection of the skeletons of the column and. the foundation footing-at the level of the floor of the first story. DETAILS OF TEEE RIGID STEEL WELEED REINFORCENENT OF TEE HONOLITIIIC,REINFORCED CONGAREE FRAMS SHOWN ON PLATE 20A: Source: ElektrichesklyetStantsii, 1952 No. 2, p. PIA 20C. 20C. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part- Sanitized Copy Approved forRelease2013/02/25 : CIA-RDP81-01043R001600080008-4 (2'1 Pave) no 1-/ Sec-4%0h 7---7 Aft MEL ..A.,.. ? Giek ca...h.s 77-7 ? Bud no 17-11 Faapes /10 is?-i sec f,???-r Ll Paape3/7017-11 1 - IETAILS 6?---Coloasetio.zpotAliskeleton3_of: the and the cross girierw - a. When the girder crosses the column - be When the girder ends at the column. OF THE RIGID STEEL WELDED REINFORCEMENT OF THE MONOLITHICS REINFORCED CONCRETE FRAMES SHOWN ON PLATE 26A4 Source: Niektricheskiye Stanton, 1952, 02, p. 25 PLATE 20D.' 611 474 5emomisoyeinco ochforfpe,wet?mo monotemod te 7e. is ihmtatahaolt...se, e 0 H4- Momma.vcimui ova? Ezeclion Coet .?- --Embedment.af the?-..column- skeleton in the foundai.; tion footing. eq.:Attachment of the Okeleton to the foundOion plate to:Eabedpant 0 the skeleton in the fOundation villa , ; Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 /- ? Declassified in Part.- Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 ? exec/ion.Ivecii,g. Morana.xwas clayma Eoca-,1 ? tcfn o oAai aphaimgpa tramai Ciitin6oLi , yrcatm. ? nnecti'on Qngee. ._ .1------;; , , , , , , , ,? , , )1 ,, ? . ?...., , , , 1,,,. 1 i .?,, t i.?! -...6..-_-.4 Sece(on. 7 -7 Paspei /70 1-1 ------- -- ? Fig. 8-- Connection of the precast re- inforced concrete beam to the skeleton of the transverse girder. /9c7c47;*c4,;..Ceo.r.24/- gecer,;',7, ,tev,i6z..cefrn CV Fig.-7 -Connection-of-tne-stelezonsc,aqs-z. of the girder to the beam. Fig. 9 - Legend Fastenings of the form to the Skeleton a. Construction of the fastening of plank forms for the beams. b. Construction of the fastening of plank forms for the girders. c. Construction of the fastening of plank: forms for the column. pr)1.1_d IL Lat.1070/ 0/74.1Y?971 / Aa" e t.c6 ? ..50g.745p4'c r dileact113 m 4? x25. Feat-a .80a. pa h 2/S?41.5.8 11111/77113 &lam 8=40 Act,;ee 1/) . ? ? 21euah:; tinamta 139Aatdra WUM J decor g a 5 flodleac VO-12 *ange,e_. 525/0-he Ozpahavumesh ..540 pie 70415 life 0-0;11 coep.mbi S/016 Nece, azgarmlvamew 1141/77 u. gawk th-f0 Pane.e s'o 6) 77e /6 ea..cle_. caul/am anammt dam U.1 docom = ..a....t.d4onee Fig. 9 DETAILS OF TE RIGID STEEL WELDED REINFORCEMENT OF THE MONOLITH REINFORCED CONCRETE FRAMES SHOWN ON PLATE 20A Source: Elektricheekiye Stantsii, 1952, #2, 0. 26 MATE 20E. - ? 4,74; ' - , Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Wel .t of Steel: for 18 in. 59 -ft : f building lep th as ? ?os boiler unit). ? ?le Steel stresses -- . .- NO. 1 ? ?-, NO. 2 Total Weight Weight of steel ' Total ' Weight 1 i? ':, Weight Of steel .f-eupporting members .1um128 Crane girders. Inter-story door-supporting members'of the feed water pump 'section Inter-story floor supporting Members of the bunker section ..ers41:3 Longitudinal frame meabers m toni m ? M t?118 ,., -87.1 137.6 .: 9.8 33.7 .. . . , 38,16 :.29.3 20,.:44 ? o.am 3t87 6,04, 10,43 1,70 . 1469 3430 . 1.27 game= '-0.240 0.374 0.0266 0.1055 0.1049 0.0805 0.0 88 , . 60.5 172.2 16;8 40.5 58.5 40:0 1.81 5.20 0.1.i. , , 1,20 1.76 1.24 1.20 0.112 -0.323 '10.0249 ,.0.0745 ? ;:0.109 0.077 10,0 4 ` ' Toi4 429.3 12.9 !,$0.800 36).0 ?. 16.3 11,o1 . . i. ram. 100/12 Z 3.94/0.472 120/16 = 4.72/0.630 120/18 = 4.72/0.709 150/10 = 5.91/0.394 300/14 = 11.8/0.551 400/16 = 15410630 480/14 = 18.9/0:551 500/12 = 19.7/0.472 500/16 *19.7/0.630 500/18 = 19.7/0.709 900/12 = 35.4/0.1472 1100/10 = 43.3/0.394 1100/12 = 43.3/0,472 Conversioectionts on Plate 21A, Fig. 3. PLATE 21B. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 A 20,08 23,930 ASO -1100.12 -.590i18 275. U2441 ri ? 33.00 IV &OM:. )?I -500.12 20,11 -3004141 22,2S Atz V Lar"4-2-11 4 /la 01 ED-90042 -418044 -.100,11 -150'10 000.12 no E-34100.12 -5.90,16 -3,00.10 1.12046 r 1.1 fpikepZ KIR e3 HomenomaR 82S 4300 /la Y-Y -1100.t0 -400!$ Mauiumnd aft ff igoo Yp v natra RI II a 22,500 /0000 23500 A 8000-0, r A Fig. 1. Transverse steel frames of the in power plant building with steel sections for a iigid4resse connection design (as per scheme 1 - fig. 2). Fig. 2. Scheme 1 - The multi- . /story four-aisle combined transverse -steel frame is rigidly connected. Fig.). Scheme 2. The steel rigi,d frames of the boiler housei of the turbine hall and the out- side wall of the bunker Option are interCeinnicted" by hinglid steel memberii. CONSTRUCTION OF THE MAIN MIR PLANT BUILDING OF TEE SECOND-TIPS DESIGN IN STEW.. Source: 110kritheeki1e SUntsii, 1948, #9. RATE 21A ?77? f. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Weight of Steel: for 1: in 591 b dg. length bol er unit (Alla:elle steel.stresses 1400 kg/cm2 - 19,900 lb/in - ) Total Weight Weight of steql in tons kgjmi luirci Boof-sugporbing members 81.3 3.10 0.1920 Columns 121.6 4.61 0.2860 Crane Girders later-story floor-supporbing members of the feed. water 8.5 0,32 0.01984 Dumm section 17.4 0.66 0.0410 Inter-story floor supporting numbers of the bunker section 65.6 1 2.49 0.1545 Bunkers 35.0 1.32 0.0820 Longitudinal frame members 29.5 i 1.10 0.0682 Total , i 359.4 i . 13.0 0.8450 1 JL 75/8 ag 2.95/0.315 150/12 = 5.91/0.472 -IL. 150/16 = 5.91/0.630 100/10 = 3.94/0.394 300/20 = 11.8/0.787 350/12 = 13.8/0.472 350/16 = 13.8/0.630 350/30 = 13.8/1.18 400/20 = 15.8/0.787 500/10 = 19.7/0.394 500/18 = 19.7/0.709 500/20 = 19.7/0.787 500/30 = 19.7/1.18 750/8 = 29.5/0.315 750/10 = 29.5/0.394 750/12 = 29.5/0.472 750/14 = 29.5/0.551 1000/10 = 39.4/0.394 1000/14 = 39.4/0.551 1000/20 = 39.4/0.787 1200/12 = 47.2/0.472 1800/14 = 70.9/0.551 Conversion figures on steel section S on Plate 22A, Fig. 1 PLATE 22B. Declassified in in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ,407", Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 in ? ? no 11-11 lb I - r 2-35001 -2-311.20 mg, AIM lwriterer 112 ? N apinajjta!' 730 nog :a) 1.f!m MVO Jr? Os IN-Of 1--0 2-350.12 -750!, II I' riII Os F3-111 * 1 2-J00?20 -750.10 ser' IS. MS 22.100 w-15012 HMV 140V ,,, VON _ ? 11 VIAOIS Mir ?M?110 ????? ? z fhwAspies Korn:limas Zr 11 1111 fir 11 II 11 JO kJ 1411.12 II /7. It-JZ 111 2-500.1.5 J 3Q0020 -1900 ? 10j2-Su2'JO -143X ? PO Ir. 11500 11 ib E-VI 2-500.00 I-500.30 -WOO .141 1000 20 *Mr 2-4900a -1200012 aa 117-1a1r 2-350.12 . ?500.111 10 550 "is 7 -1.100 ft? rifir 2-477..10 -:x0111 Fig. 1 - Transverse steel framesof the main power plant building. Fig. 2 Construction scheme of the -main building steel frame connections. 42,47, CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE FOURTH-TYPE DESIGN IN STEEL Source: Elektricheakiye stantsii, 1948, Ni). 9 (T1[4.E725). EZZalai. ? - - Declassified in in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Fig. 1 - Base of a column Fig. 2 -.Connection of a crane girder and a frame girder to a column. Do,-, 2L0008 270 Fs! 145L S 4. .4;4. 1?4?:14.1 ISO ISO 37049370 1111141M1 aik a LSO'S 12 a SPUN We:maws ISS? ?1,2 MMMMLE e) 12 21120x12 111116' It...30 ? 203 Sf 203 eces.theifttzme Fig. 3 -Connection_between truss-, members and a column. 2) Fig.- 4. Connection between -a column; a girder and a beam DETAILS OF THE PRINCIPAL JOINTS OF THE 8TEtL FRAME IN THE MAIN POWER PLANT BUILDING Source: Elektricheskiye Stanton, 1948, #9- (TK4.E725) PLATE 220. -80- t, Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ct94emilaP crema \- "22,0 :era wan, 111 111 lAtMlUtimpla XIA Scheme I The coMbined rigid steel frame of the bunker and feed-water pump section is connected with the outside walls of the turbine hall and the boiler house by hinged ,structural members The rigid frames of the boiler house and the turbine hall are con- nected by hinged structural members formin the middle hinged combined frame of the bunker ald feed-water pump stations. 15,0' Nome/Delta: ; Fig. 1 - Design scheme 1 Fig. ? - Erectiola scheme 1 Pacqemmap cram 4.c9iI SeAeM ei 33 0 20,20 mweftmw kfaususobiu , PLATE 23B-.- Fig..3.- Design scheme 2 MOHINOVICUI czema Fig. Erection scheme 2 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - Fig. 1 ? Main transverse steel frames of the building. CONSTRUCTION OF THE MAIN PMER PLANT BUILDING OF THE FOURTH?TYPE DESIGN IN STEEL Source: Elektricheskiye Stantsii, 1947, P. PLATE 2. mat., -82- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1 llada,loyNow aporw NO - :?? SOO - Pig. Connection between the steel welded skeletons of a cross girder and a . column. ION ,aodottowecto opromypa R at datou e ik)4 tceme t. Fig: 6 - Connection between: the steel welded skeleton of a girder and.a-beam. 11...",11g11,^410.1, Fig. 7 --Fastening of the concrete forids-t&the vildbd,:dteel skeletokof a girder and of a column. Pip 8 Aileibly'df--velded-Asteel reinforcing Skeleton parts for the bunker section frame by . means of a swing jib crane. pun 21134 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1c7".1 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Ballet 8oure nave:eta* Pig. 1 ? Principal transverse frames and partial plmAt,showing the bay lengths of the main power plant building: ee,pe.t. sit e ? 40.5 gepxHu0 non. . ?,e; j29' now . 0- , Zeivit, gi2t ? kt. 01176-0010:1/40:16 4 OS Oa - 4.50 Fig. 3 - Rigid steel welded skeleton of the floor supporting beam. 0/2 40.7 :Pi : ..? ?76 1 A I 4. ..... 700 4 . ? 141 .11Z% Cill rin Ci 1; V ... 0 0 0 0 0 0 l'? 1.1 L ____I ,0 1) L 754 0 0 0 goo 0 0 * j ij 0 0 1) 0 0 .1! C_J I07.4l _ e.. ..:. 4.. 11-7 I I. p. ON - -+- ? El 00 -----4 Fig. 2 ? Welded rigid steel skeleton of the monolithic frame of the bunker and feed? water tank sections. .170cralkoemos Po 1-1 12,1X:f7 oi7 Atehleemeni. 1100 Onearo04.0 Z011ar onneetAm any< !ig. 4 - Joint ofIiieladded . steel skeleton of a column. CONSTRUCTION OF THE MAIN POWER PLANT BUILDING IN MONOLITHIC REINFORCED CONCRETE WITH WELDED RIGID STEEL SKELETON REINFORCEMENT Source: Stroitellnaya promyshlennostl, 1950, 143.. 4. YLATE 211 -84 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 ? tveiga of ct Itecast eeernen? Dec 3aromeeumenomozo menemma in 1,, tons loeig4i of cti e-e. ec ten e -lee mommaatvozo .menevoto ,.? Ans Am 400 30.8' 8.9.3" 27,30 9.4O 1?50.oe ? CO ? 9 *Jr ? a 3goo qrsts.4, 0 , .1000'4 0 0 ztai 6.9.5. 18,5r VW 0.00 23,00 Rwhicenct N.mgAgftw 6/1.0,11 Ezecti'on. joint AMMO efiThIR Ye ?Boeee^c Mouse Itomentowe omileiretetre ci8,00 \-7e ecA`on eine . ..vvynmoinenoRba; eawo war- cr_4 2000 /4J' ? 27000 88.6' 11), 7500 9000 ? 9 .54 14 000 78.7' / t!! Fig. 1 - Transverse precast reinforced concrete frames or the main power plant-building. The sedtions of the principal structural members are shown. In small circles are given the weights of the prefabricate membersvand in small squares are the weights of members pre-assembled at the building site. CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE FOURTH TYPE LAYOUT DESIGNED IN PRWAST REINFORCED CONCRETE Source: Stroitellnaya Prowahlennosti 1956, #6. ZUTE,251 " ' npriacsifieri in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 55 (55 205 36S Declassified in Part- Sanitized Copy Approved forRelease2013/02/25 : CIA-RDP81-01043R001600080008:4 f 11) 40 60 v__i 148V S-.-1225 1225122f 60 60. no 2-2 5350;5550.5650, 5570 6040 60 6 ?1 1004 801103-3 110 3-3 Fig. 2 - Inter-story floor panels 1704-4 Legend Fig. 3 1. Welding of reinforcing bars 1# submerged method. 2. Stirrups 3. Concrete joint filling Legend Fig. 2 a. Geometric dimensions b. Panels resting on brackets of the cross girder. c. Panels resting on top of the cross girders.- 2 2 agrat-aillsous03:11 = I \I no 1-1 *Fig. 3 - Preassembly joint of a column CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE FOURTH...TYPE MOUT, DESIGNED IN PRECAST REINFORCED COIERETE Source: Stroitellnaya Promyshlennostt 1956, #6. BATE= Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 rn Legend Fig. 4. or.t Legend Fig. Fig. 5. Erection 'joint of a column Joint of a column with 1. Erection adjustment belt. its foundation fboting 2. Erection angles L120x10 mm. in case a basement is 3. Steel plates 300 x 200 x16 mm. built. 4.. Steel hoops placed around the column joint, 140 mm. x10 mm. 1. Pin in the column ofthe butt. 5. Side steel plates 100 x 280 x 16 mm. 2. Concrete filling. 6. Cement plaster applied around the 3. Wedges. column joint. 4. Floor covering. 7. Horizontal steel mesh set in the column (indirect reinforcing.) 5. Scupper 50 mm (2 in.) -015 -1000 ? II 11 ' II I ? 1100 -- 170 1-1 1 ? -11 00 - II II L_ 700 Legend Fig. 6. , JAht of a column withits Bmxid4tion 1. Pipe 160/10 ma (10.2/0.4 in.) filled with concrete for adjustment of the column,. 2. Insertion of reinforcing bar pieces. 3. Welding of ends of the rein- forcing bars by the submerged arc vethod. 4.. Filling with concrete. 5. Column stirrups. CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF THE FOURTH TYPE LAYOUT DESIGNED IN PRECAST REINFORCED CONCRETE Source: Stroitellnaya Promyshlennostt 1956, #6. PLATE 25C - ? -87- Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 1 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ??? Fig. 7 ? Legend "Joint of a transverse girder with a column 1. Insertion of pieces of reinforcing bars 2. Welding of ends of the reinforcing bars by the submerged arc method. 3. COnciete filling. OCb Cffibilta f ? a) +14 2naf /70.11 Z? -12 mmls ?rz flop/ flo 6-6 -Om /7044 17#2.2 024 rL?1 i ..1110d. _ wi laIla 1111111111111111 wpm. , gilat 4 . LUIti L75 'O Fig. 9 --Legend Construction of the frames of a TETs in precast concrete Fig. 8 ? Legend e- a. Geometrical dimensions. b. Details of the attaching of panels to a column. Fig. 8 CONSTRUCTION OF THE MAIN POWER PLANT BUILDING OF flit, FOURTH TYPE LAYOUT, DESIGNED IN PRECAST REINFORCED CONCRETE Source: Stroitelinaya Promyshlennosti 1956, #6 PLATE 25D. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 " ,?...e.?.--+.1.????ff ? --.?????- _ zo. ro: 15,00 8,00 0.00 Fig. 1 ? name construction in precast reiziforc-id concrete ard steel. 4(1 33,00 ijir r 11 loogrell.1111 ?". 11. 100200012OSIBP > 0 ICA IF WIMP v10,00 0 Fig. 2 ? Frame construction entirely in precast reinforced concrete. Two Alternatives in Construction. MAIN POWER PLANT BUILDING Source: Elektricheskiye Stantsii 1947, #7. KATE 25E ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ' < - VERNAL ELECTRIC POWER PLANTS IN THE U.S.S. Report No. 92 001414CG VOLUME II , I Inclosure #33 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 pap..'., Fig. 17 - Meaning of Symbols Used in Referring to Required Transverse Reinforcement Under Single Concentrated Load. Inclosure #34 to AFC1N-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 . a ...... 0 S- alL1, Si 6,10 0.40 a 47----- 0.15 pil ( IV a b m o .3 0 0.28P 0.35 a 0.20f / 2 0.3 0.23 0.35 0.15 0.40 0.10 1.5 0.3 0.21 0.35 0.13 0.40 0.05 1 0.3 0.16 0.35 0.07 0.40 0.05 5. The tables for two points of load. application are valid if P in Fig. 22 denotes reaction at support A and h the, total beam depth. The value 44/ with the loading at the third point corresponds here to the value Example. Determine the required shear reinforcement for the beam given in Fig. 23. rtep shear permissible according to concrete specifications = 6 kg/cm2 (85.3 lb/in2) -7.00 weightespecimar--L1530.57=0.5kg/cm2 (7.1 1b/in2) 3a -3.0.-4 h *See The influence lines of local reaction indicated by Fe Seewald: "Abhandlungen .Aerodyn. Instit. Technishce Hachschule," Aachen4 Vol. 7, p. 11, 1927. Inclosure #50 to AFCIN -1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 From Table 7 is obtained IA = 2 (dim s 30?6010.5 kg/cm? (149.1 ib/in?) 6 2 Z61=40.5+0.5 >1:76" for which shear reinforcement is to be provided. From Table 8i established area of shear reinforcement for //h al 2' Als ?=1- 15800 2200 -&6 Cm2 (1.4 in?). 3. Continuous Beams As the situation remains largely the same in continuous heams as in simply supported ones, the rules drawn. from the (preceding) Section 2 regarding permissible reactions at supports and the shear reinforcement ought to be applicable here. The situation between supports differs considerably from that in the simply supported beam.. Besides the fact that the oblique principal tensile stresses' change imperceptibly to horizontal bending-tensile stress above the there are portione of the beam separated by cracks (Which could be termed extended bending cracks due to shearing cracks) in a state of equilibrium, with the special rein- forcement.not necessarily producing an effect. This is under the assumption that the span and the loadings are equal in different areas. Whin-feilre occurs, the system can be characterized as-a-continUous arch where the conditioWdf equilibrium of all the portions separated by the cracks is fulfilled without the introduction of ad-adational force. This pdht is.amplified by the results presented in Figs. 24 and 25, which had been: obtained from the photoelastic investigations of a continuous beam resting on three supports. Furthermore, Fig. 25 clarifies the point that the crack first to occur brings about a relief of the area close to the support, with the result that the center of tension in bending above the supports is transferred: The shear reinforcement at the support'ought Inclosure #51 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Ar Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 iNkr iSt t ? Limo, ?11717argro' Fig. 24-a - Trajectories of Princi- pal Stress in Stage I of Photoelastic Test. Beam resting on three supports. Vh.a. ri42 DSP aop ! 4WP ? a IN II I III Fig. 24-b - Trajectories of Prin- cipal Stress in Stage II of Photoelastic Test. Beam resting on three supports. rin P 0 Pig. 25 - Contours of Principal Tensile Stress Distribution in a Beam on Three Supports, Obtained From the Photoelastic Test; ZA = 1. Fig. 24-a shows Stage I; Fig. 24-b - Stage II. Intensity of principal tensile stresses is expressed in terms of P. Thickness of specimen - 1 am. (0.39 in.) Inclosure #52 to AFCITRIAI IR ? 1804 ? 57 31 October 3.957 si? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ? ,r1-1-r? 72 to be used simultaneously as bending reinforcement, as shown in the photoelastic reproduction. As the bending reinforcement, according to the existing calculation methods, is indispensable, it follows that a certain shear reinforcement also will always be necessary. TO establish the requisite amount of shear reinforcement it is first necessary to elucidate its function. Thus it can be deduced on the basis of the foregoing statement that it [the reinforcement] serves to distribute cracks. As the first cracks bring about a radical shift in stress distribution, the solution of the problem can be achieved by studying direct tests on concrete. The test described in Chapter 4 presents the needed data. On the basis of this test, no extra shear reinforcement is required above the supports, if the entire reinforcement of the beam is designed in accordance with the recommendations given in Fig. 36. This assumption holds, however, with the prerequisite mentioned earlier that the different span areas and loadings are equal. 4. BENDING REINFORCEMENT A. Introduction The design of bending reinforcement has hitherto generally been based on stress distribution in a homogeneous beam and on a tensile force inthe reinforce- ment equal to the total tensile force in the homogeneous beam.* This method of approach obviously deviates from the method used in proportioning shallow beams, where the tensile force in the reinforcement is determined by the stress distribution prevailing at the cracking of concrete. *With the exception of the test shown in item 13 [of the Bibliography], where tbs.: analysis of the effect of crack formation refers to simply supported beams ax for the test in item 15, where a direct attempt was made to establish the tenDile forces in steel in certain loading cases of simply supported beams. Inclosure #53 to AFCIN-1A1 IR - 1804 -.57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 "??? a C5,1 Va,LAT-f-v-elmtstmliatag,..? The reason for not taking into consideration the cracking of concrete in deep beams is to be found in the imperfect knowledge of the effect of cracking. As far as is known to the author, no direct tests reaching the yield point have ever been made. With a view to elucidating the behavior of members which are loaded so heavily that crack formation exerts an influence on the stress distribution, the author has made a series of tests. In order to throw light on the interaction of the moments at the supports and between supports, so important to the problem of proportioning, the tests were made on continuous beams resting on three supports. B. The Test The shape and reinforcement of the test beams are shown in Fig. 26-a and 26-b. The reinforcement area in beam #2 was designed on the basis of stress distribution prevailing in the homogeneous =cracked beam in the photoelastic test (team II: 1-a); for instance, the reinforcement above the support was concentrated in the area where tension prevailed. The reinforcement in beam #1 was designed on the basis of a probable stress distribution after the cracks have occurred. It was assumed that the reinforcement at the center support placed at the upper edge of the beam, on account of the progressive crack formation, should be effective against the moment at the supports. To eliminate possibilities of local compresiion failure, local reinforcement was placed in the areas subjected to load and at the supports, as shown in Fig. 27. Then shear reinforcement was introduced consisting of 4 0 8 mm. (0.32 in.). The form of reinforcement mounted for casting is shown in Fig. 28. The proportioning of concrete aggreagates in dry weight was as follows: standard cement: sand: gravel(1: 3.7 : 4.7. Water-cement ratio 0.75 (8 1/2 gal./sack). Inclosure #54 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 _ 7.". Six compression cubes (each side 15 em,= 6 in) were made for each beam. for each series of two beams a control specimen was prepared consisting of: 6 compression cubes, 4 tension prisms (with a cross-section 15 x 15 en? = tensile length 64 am (25 in), 3 beams subject to bending (with cross-section 15 x Also 6 x 6 in; free 15 cm? = 6 x 6 in) The summary of results obtained from the control specimens is tabulated in Tables 9 and 10. Tested Specimen for stroWth of Cube Tested Specimen for Strength of Cube kg/cm? lb/in2 kg/cm2 lb/in2 Beam 1 a 295 4200 Beam 2 a 305 4.350 289 4.100 300 4260 278 3960 294 4.190 275 3920 254 362o 267 3800 276 3930 266 -ig- 252 358o - Av. - -. Beam 1 b , 280 ... 3980 Beam 2 b 273 3880 260 3700 271 3860 282 4000 262 3730 282 4.000 262 3730 270 3840 248 3530 276 3930 267 _18_22_ , Av. 275 3920 Ay. 264 3750 _ Table 9. Strength of Cube of Concrete Used in Test Beams Inclosure #55 to AMIN IR - 1804 - 57 - 3]. October1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Control Specimen for Strength of Cube Tensile Strength Tensile Strength (in Bending) kg/cm? 1b/in kg/cm2 lb/in2 kg/cm' , lb/in2 Beam it 1 291 292 304 270 _ZIL Av. 285 11.150 11.160 4340 3840 3930 J222_ 4050 _ 18.4 17.2 16.3 _17.&_ Av. 17.2 1 260 244 230 248 -Egg- 26.0 26.5 _11.'2_ Av. 2-7-.-8- 370 378 442 396 Beam # 2 . 257 265 276 281 267 _21i. Av. 270 3660 ? 3780 3930 11.000 3800 ..3.222_ 3850 18.0 16.6 16.4 257 236 231 26.8 31.3 28.2 382 445 402 -us- . Av. 17.0 242 , Av. 28.8 Table 10. Strength of Wipe, Tensile Strength, and Tensile Strength in Bending. Bending tensile strength is calculated on the basis of rectilinear stress distribution. Inclosure #56 to AFCIN-1A1 , IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 '1 JA - 11021 - a ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 decb'on 4-4, Soil A -A 112 Fig. 26-a - Dimensions, Reinforcement, and Points of Measurement of Test Beams of Series I 0 0 Er ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Fig. 26-1) - Dimensions, Reinforcement, and Points of Measurement of Test Beams of Series II., Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 0 0 0 70 2.7 Fig. 27-a - Local Reinforcement at Rid Support sly 20J- joop 71. 8" Fig. 27-1) - Local Reinforcement at Center Support 470 1,5..5" 1 ^ op.*, 4w41. Weld Z,3 ? $1, Sara pia. 27-0 - Local Reinforcement Below Loading Forces Inclosure #59 to AFO/N-1A1 2.7S" IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 \ 1' . f: , ; , ..... . .." ..'..,-.< ? - 1 - ' -? ' ..--:-.----.. ., _ ..":- ? I . ., --? , ..;44V#744.0 6 ? P. . . 1 0 ? 4 7 1-- Y - ? 4. 7 :.," a .,=ae...====. r .?!`"'N'4?' ..... . aai.lasIdsw.:- -. LleMa a .". Sae ' - ? ">??.4., ? ?? - - 13111ilibtr " Fig. 28 - Form with Mounted Reinforcement Before Pouring Inclosure #6o to AKIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 A control specimen vas also taken from each reinforcing bar. Data on the strength7the reinforcement used are given in Table 11. "Ref. to Steel Maui. Yield Point (laver) Ultimate Strength Ult. Z Beam Pig. 26 mn in kg/cm2 lb/in2 kg/cm2 31/in2 Along. kg/Cm2 3.o6 x ib/in2 3.06 X 1-a 11 7.9 0.33. 2740 39000 3530 50300 Average 28 percent 2.15 30.6 " 12 7.9 0.33. 2940 43.900 3950 56200 2.21 31.5 " 13 7.9 0.33. 293.0 43.500 403.0 58400 2.19 31.2 " 3.4 7.9 0.33. 3080 43900 3800 543.00 2.24 31.9 1-b 11 7.8 0.30 2970 42200 4o6o 58000 2.15 30.6 " 3.2 7.8 0.30 2920 43.500 3990 56600 2.17 30.9 " 13 8.0 0.31 3020 43000 3780 53700 2.3.4 30.4 it 3.4 7.9 0.31 3080 43900 3800 543.00 2.24 31.9 2-a 21 7.8 0.30 3040 43200 44014o 571400 2.25 32.0 " 22 7.9 0.33. 33.40 14600 3920 55700 2.28 32.4 ? 23 8.0 0.31 2700 381400 3740 53200 2.11 30.0 " 24. 7.9 0.33. 2750 39200 3860 55000 2.19 31.1 " 25 7.9 0.33. 3080 43900 3800 514.3.00 2.211. 31.9 2-1) 21 7.8 0.30 3040 43200 4040 574400 2.25 32.0 22 7.9 0.33. 3020 43000 .4020 57200 2.25 32.0 " 23 8.0 0.31 2700 38400 3740 53200 2.11 30.0 " 24 7.9 0.33. 2750 39200 3860 55000 2.19 33..1 " 25 7.9 0.33. 3080 43900 3800 543.00 2.24 31.9 Table 11, Data on the Strength of Reinforcement. Inc.losure #63. to APCIN-1A1 "."-- IR - 1804- - 57 33. October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 The steel strain in each test beam was measured, by means of tensometers located as shown in Fig. 26. The center deflection in relation to the end supports was measured by means of a "Zeiss Clock" (dial gage]. Since the jack was located below the center support, it was possible to calibrate the height of the support and to determine the center reaction. The photo in Fig. 29 gives a view of the test set-up. The jacks were calibrated for the same loading method as in the experiment. In calibrating, internal friction was taken into consideration when evaluating the results of the experiment. Data on the load at the first crack to appear, the ultimate load, and failure are tabulated in Table 12. Beam No. Load at the First Visible Crack - Load at Failure Failure Phenomena m.t. m.t? 1-a 75 , 135.0 Scaling at the center support. Widening cracks 1-b 75 123.5 Ditto 2-a / 75 121.5 Widening Cracks 2-b 50 106.5 Scaling at the center support. Widening cracks Table 12. The Load-at the First Visible Crack and at Failure. The results obtained from deformation measurements are shown in Fig. 30. The relationship between the total load and the center reactions, and between the total load and the deflection at center support relative to the end supports are given in Fig. 30-a; the measurements of steel stress for different beams in Fig. 30-b (points of measurement as in Fig. 26). Photos illustrating the crack formation in test beams 'are,to be-found,in.Fig4331. lnclosure i62 to MIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 From the results presented in Figs. 30 and 31 the following conclusions can be drawn regarding the behavior of the beams tested. 1. The center reaction in beams #1-a and #1-b due to the load at the first crack formation amounted to between 54. and 62 percent of the total load when the center support was not shifted vertically in relation to the end. supports (the load of 25 m.t. was disregarded because the reading of the load, value was uncertain). No appreciable change in the relationship between the center reaction and the total load was noticed when the load was increased. In beams #2-a and #2-b, the reading was uncertain at small load values. At loads exceeding 75 m.t. the center reaction constituted 50 to 52 percent of the total load when the upward shifting of the center support was zero. From the comparison of beams #1 and. #2 it is evident that beam #1 has a greater rigidity in bending in its center portion. This probably 'could be explained by the fact, that beam #1 is provided with reinforcement in its upper edge. 2. The steel stress diagram shows that, after the cracks began to .appear in the concrete beam, the reinforcement at the supports and between supports was on the whole subjected to equal stresses, irrespective of whether the reinforcement was designed on the basis of the stress distribution prevailing in?a homogeneous and. fully elastic beam, as in beams #2, or on the basis of the probable stress distribution in a cracked beam, as in beans #1. Deviations observed in both types of beams could, be explained by the different reactions in the tenter portion which, by causing cracks to appear, resulted also in a different stress distribution. This, for instance, could explain the high reinforcement stresses observed in beam fi-a even at a load of 75 m.t., when the center reactions had first increased, then considerably decreased. As a result wide cracks appeared above the center support, causing a lowered rigidity above the Inclosure #64. to AFCIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Lg - tost - a Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Total locreloa CenterreactionaserooFtotalload IMO MINIIIII11111111111101111111111 IgZiatOMIIIIIIMIIIIMM11111111111111111111Z 111111111111.111=111111?111111111111111111111.%1 11111111N1111111111111111111111111111111111111112111111=1 11111111111111MONEEMEEEENIINCOM 111M11111110111PW/11111111111111111MIKIIIIIII 111FINIIIIIIIIIIII/11111111E11111111111111113111111111 illaWinimiiinliM111111111111111111M1111111 IMEM1111111111111M11111111111111111111111111111111 17411111?1111111111111M111111111111111111111?11111 F/111?1111111111111111M1111111111111111111111111111111011111 Total load, rm.t. 10 sts,==l7at x.4? ..roc?/ rbc.v.L.% or, toi.a/ icaff Am/ Ai* kids arom . ? - ? Art railure 'Total load Ai, 410 bem st,. balk 2 a ? webs ?its 0 T4r JO ? Total load 177.4 Center reaction as % of total load Center reaction as% of total load /21.21frartarn4., 4.. ????? 11.. -4- $4 ? n f ri fo as = balk lb beam Ss* min -Cs ? nake=:: ? 411111111."'"'"1 ? 11,^ \_ a? berm, = balk 2 b 7 Pailure rA .00 .9 air ? 8) Fig. 30-a - Total Load, Center Reaction as Percentage of the Total Load, and the Vertical Displacement at the Center Support Observed During the Test. The abscissa indicates time elapsed from the start of the test. 4 Notation: A sa Total load; B Center Reaction as % of Total Load; C Vertical Ed. spiacement of the Center Support (+ when the displacement is downward). \ID The connection between the reaction at the center support or the vertical displacement of that support and the total load is to be found from the diagram by drawing a vertical line from the load, curve A to [intersect] the reaction and. displacement curves B end C. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - Wet - )11 /.56T aacippo t? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ?0' Total' load m.t- maw- tri , Alto LIIMNEMMEMININMEM NUMMENNUMMENO 4'1-t ? PENEWAMMEN MMFAMMMESNIIMMMN 1MNAMMONNNMEMON Immm? II II 011111111111111 logNIIIIIIIII I IS" I I Total load, b.! -1-1 -F -L- olP = Palk 1 a bearn Time,rnin. I. AP" N 4602 Failure Time, rpm. Total load) tmt 0, ? =" - A _ - -.e Total load '11,74 _.,_.... t F- JO ate = balk 1 b beam T7m4mm / " baltn7 b4 = balk 2 b Time,m1r7 Eaffure. Fig. 30-b - Total Load and Steel Stresses Observed During the Test. Abscissa indicates time elapsed fran start of the Test. Notation in Fig. b1 and b2: A = Total Load.; B = Steel Stresses in Midspan (Tensometers 1, 21 6, & 7); C = Steel Stresses in the f see Upper-edge Bar Above Support (Tens. 3 & 4); D = Steel Stresses in Bent-up Bars Above Support (Tens. 5) Fig. 26-af Notation in Fig. b3 and bo A = Total Load.; B = Steel Stresses in Midspen (Tens. 1, 2, 6, & 7); C M Steel Stresses in Upper Barssee , Above Support (Tens. 3); D = Steel Stresses in Center Bars Above Support (Tens. 4); E = Steel Stresses {Mg. 26-bj. in the Bottom Bar Above Support (Tens. 5). Declassified in Part - Sanitized Co. A. .roved for Release 2013/02/25 CIA-RDP81-01043R001600080008-4 ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 -rrczr.'? t rf-N, support, which in turn, when subjected again to an increased load, caused the span to absorb the greater part of the bending moment. As the lever arm of the tensile force acting on the steel (above the support) in beam" was more than twice that in beam #2, it is evident that the reinforcement used in the beam #1 is preferable from the point of view of load-bearing capacity. 3. In beams #1, where the reinforcement was provided for observation of the moment probably present at failure, the widths of cracks were measured throughout the test. When subjected to load equal to 60% of the ultimate load, the widths of cracks, as found in Fig. 31-a, did not exceed 0.1 =6 (0.004 in) at any point. In beams #2 no such measurementswere taken. The cracks were visible at the same or at slightly lower loads than in beams #4. It can thus be concluded that from point of view of crack formation it is permissible to provide the beam with reinforcement mainly at the upper edge if, as in the case of the test, the crack-distributing reinforcement is provided in the portions of the beam where the greatest tensile stresses are present in the uncradked homogeneous beam. The reinforcement used during the test consisted of half of the reinforcement in the upper edge of the beam above the support. 4. In connection with the matter discussed in the preceding paragraph (3) concerning crack formations, the question remains open as to the design importance of the diagonal tensile stresses above the center support. The photographs in Fig. 31 show that the cracks formed as a result Of these principal tensile stresses run from center support toward the nearest acting force. It is obvious that such cracks have no effect on the bearing capacity of the beam. As the cracks had no alarming width, as already mentioned earlier (in paragraph 3), there is evidently no need, in a beam ratio such as this !Pan ,st 1, to consider the diagonal tensile depth Incliture #67 to AFCIN-1A1 -r IR - 1804 - 57, 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 (21 NIk ? 1, Fig. 31-a - Crack Formation in Beams #1 Load values indicated. for transverse lines represent the extent of cracks at loads as in the reading, while the actual load, was equal to the reading load reduced by 3.05 m.t., which is the weight of the loading device. In places where the widths of ' cracks are given, the values for loads are given in parentheses. Inclo sure #68. to .AIN-1A1 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 0 Load values indicated for transverse lines represent the extent of cracks at loads as in the reading, while the actual load was equal to the reading load reduced by 3.05 m.t., which is the _weight of the loading device. the values in parentheses represent the center reaction. Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 stresses above the center support, if some crack distributing reinforcement is provided. C. Lever Arm of Internal Moments Under Various m? __...rt and Loadi.: Conditions As no systematic test has been made on beams for various methods of support, loading condition, and span ratio, one had to fall back on the rather rough evaluation based on the available results drawn from tests. Klingrothls test (15*) gives data on the lever arm [of internal moments] in a simply supported beam with a depth = span and, loading conditions shown in Fig. 3, namely: 1) load at center, 2) load at third points, and 3) uniformly distributed load. The lever arms for these cases as obtained by Klingroth are: 3.) /1/3..oli? 2) h/1.37 3) hA.63.. These values, however, presutpose that the bending reinforcement is distributed over an area equal to 1/4 of the beam depth, which seems to be unnecessary. If it is assumed instead that the center of tension is located at 0.05h from the lower edge, then the lever arm values, according to Klingroth, are as follows: h./0.97 2) h A.25 3) 12/1.45. Thus it could be deduced on the basis of the high values at the load4loints that the concrete absorbs tension. As this capacity depends on the concrete mix, it seems a warranted precaution to establish the lever arm at li/1.05. ' These values for the lever arm q [of internal moments] .deduced from the photoelastic test for homogeneous =reinforced beams are tabulated .in Table 13. 41[Se. Bibliogx,phy], Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ' Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 07 , 1 4. h A.50 2 h 11.54 413 h 11.53 1 h /1.51 Table 13. Values for Lever Arm of Internal Moments q Obtained from the Photoelastic,Investigations. Simply supported homogeneous beam; loads applied at third points. It is clear from the table that the lever arm in a homogeneous beam varies slightly with variation of the span-to-depth ratio. For loading cases other than the one examined the ratio ought to be similar. Therefore it can be concluded that the variation in stress distribution in varying span ratio should have no important bearing on the et-value. On the other hand, the cracking of the concrete in the tension zone has a different effect at various span ratios. In regard to the fact that the lever arm increases with a progressive crack formation, there cannot be a serious error in assuming the lever arm at the span ratio 1:3 equal to the value indicated for an ordinary beam, and for ratios between 1:1 and 1:3, that the value is to be found by straight-line interpolation. The values thus obtained are to be found in Fig. 32. The above-described test on concrete beams resting on three?supports shows that the internal lever arm is largely dependent on- crack formation. In all the beams cracks appeared at midspan higher than in the case of Klingroth's test on simply supported beams subjected to loads at the third points. Consequently, in continuous beams the lever arm in the span can be assumed equal to that in a simply supported beam and use made of the values shown in Fig. 32.' Inclosure #71 to AFOIN-1A1 IR - 1861. - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 A '-; ;-* ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - ? s-----"z"`-?"."-, ? ?T???=,,V1-,:rtt---'7 1. Uniformly Distributed. Load 2. Load Applied at Third Points 3. Load Applied in the Center 1 limn/ ArdeAold Wits1 2 kimdksier Oneofrid0- pumderno 3 fbmyllosi 1.0 7. 2 3 Span-depth ratio .Sciolo":?hdlonde Fig. 32. Lever Arm of Internal Moments for Various Conditions of loading, Span-Depth Ratios /A [and Percentage of Reinforcementp]. z/irq= h/H Inclosure 412 to APCIN-1A1 - . . IR - 1804 - 57 31 October 1957 - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 7.t:,.,-.7%;r.-71.Nr...,V5=VUMItrt-VORXWOliattepes.sesuial Mettaiaithresgremr.r.....15 The proportioning of the reinforcement above the support (as in the foregoing test) with 02 as I was designed under the assumption that- the center of compression is located at approximately 17/20 to b/25 from the lower edge of the beam and that the reinforcement at supports consists of two parts, 2/3 A1 and 1/3 Ai with 2/3 AJ located at the upper edge of the beam and 1/34 at a distance of 2.5C *from:.the'lower edge. The value of the lever arm thus obtained corresponds to Klingroth's value for a simply supported beam with load, applied at midspan. As to the other value of Vh the value found in Fig. 32 can be used in accordance with rules given in Fig. 36. D. Moment Values at Various Support and. Loading Conditions The above-described test on reinforced concrete beams supported on three points shows that the relation between the moments at supports and, at midspan is largely dependent on the manner in which the reinforcement is placed. If the reinforcement at the supports is mainly near the upper edge (as was recommended in the preceding section), then the moment at supports in a beam supported at three points is considerably greater than if the reinforcement were provided on the basis of strain distribution in a homogeneous uncracked beam. Consequently all too rigid formulas for moments are out of place, especially in regard to the design of deep beams. As the moment is highly susceptible to any displacement of points of supports, this behavior should be reflected in the design. On account of the extraordinary difficulties involved in calculating the moments acting in continuous beams with unequal spans - even in beams of ordinary depth - the following moment values are presented for general and frequently -encountered cases fundamental in the analysis of support conditions. mob sure #73 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 _ ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 doir Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Y. - a. Continuous Beams on Multiple Supports with Equal Repeated Spans In cases where the loading points are applied at midspan2 the moments at supports and at midspan are equal to IV/52 as clearly seen from Fig. 33. These moments are independent of the span-depth ratio 02. In cases of uniformly distributed loads2 shown in Fig. 342 Lischinger's calculations of the moment above the supports and at midspan (9*) were based on the assumption derived from the theory of, elasticity. The summary of results drawn from Dischinger's calculations is presented in Table 14. At/ /1 Moment at Support Moment at Nidspan 1 0.071 7/2 0.041 7/2 3/4 0.072 0.041 1/2 0.073 0.014.3. Table 14. Moment at Support and Midnen Moment in Continuous Beams on Multiple Supports and Subjected. to Uniformly Distributed Load Ecpkg/m or lb/ft] (Cii = 1/10)2 According to Dischinger. The deviation of the sum of moment values at supports and in midspan from clIA/8 depends on the spread of the support. ' Consequently v even in this loading case the moment is practically independent of the ratio . Therefore there is reason to assume that the distribution of the. moment under other loading conditions for continuous beams resting on multiple supports with a uniform load and with equal repeated spans will also be independent of the ratio At./// . b. Beam Resting on Three Supports with ?pans of Equal Value The loading case examined in the test is shown in Fig. 35: the load was applied at the 'third points; the moment at support is approximately 80 to 90 percent *(See Bibliography] Idelosure i74 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 - , I a ? ? - ,-14 ? ? Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 - .Ddit_tmakara....artrerric....1,74.--20 Fig. 33 - Continuous Beam Resting on Multiple Supports. Point of Load in Midapan Fig. 34 - Continuous Beam Resting on Multiple Supports. Uniformly Distributed Load Fig. 35 - Continuous Beam on Three Supports as in the Concrete Test Inclosure #75 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 41f4', Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 of the center moment in the span. (The moment at support = -0.20/D/ ; the midspan moment = +0.23P1 ). In beams of ordinary depth, the moment at supports -0.33 P1 and the midspanimament = +0.17F1 In the photoelastic test, the value for the moment at supports was very low for the homogeneous uncradked beams, while the cracked and reinforced beams gave almost the same distribution of moments as in the concrete test. The spread of the support is an important factor in local compression above the support, and consequently in the moment distribution. This is spread of support evident from the fact that when the ratio span 1/10 and 12// = 1, the compressive stress above the center support is of the same magnitude as the midspan deflection in a simply supported beam. It is also obvious that the bending resistance of a supporting column is an important factor in distributing the moment. There is no Justification for analyz- ing the effect of the spread of supports and the elastic deflection for every case that comes up in practice.* Instead, the design should. be made on the basis of safe values for span and support moments and on estimates of the effects of support displacements which can be both of an elastic and of a constant nature. The midspan moment in a beam on three supports with a ratio 12/Z = 1 is taken as equal to the midspan moment in a simply supported beam, and the moment at supports equal to the support moment in a fixed beam of ordinary depth. The midspan moment . ? fA4 varies in a straight line from a value at k/7 = 1 to that at /3,/i= 1/3, which is valid for a beam of ordinary depth, *One should, however, take into account the effect of the spread of the support in .levelling off the peak 'support moments. Inclosure #16 to AFCIN-1A1 IR,- 1804 - 57 ? 31 October 1957 - Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ???????????????? The recommendations previously referred to for the design and area of rein- forcement required under typical conditions of loading are to be found in Fig. 36. It gives the reinforcement in a continuous beam (Fig. 36-a and b), including shear reinforcement. At the supports where the beam is simply supported (for end supports 'see Fig.- 36-c and d) the shear reinforcement is not shown. In these portions the reinforcement should be provided in accordance with recommendations given in Section 2B. The formulas have a validity for the ordinary values of the ratio 1 where CA '?-? 0.2. Inclosure #77 to APVIN _ IR =- 1804 57 31 October 1957 dc 4 npriacsified in Part- Sanitized Copy Approved forRelease2013/02/25 : CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 -4' b-Ase b?cesh \4sha 1 1- 011 2?C 10.45c ? 414 &baulk' Ap Ahe e0-i9 ,(42b) #(- en1f432 prepungllod "%len Fig. 36-a - Point of Load Applied in Midspan of a Continuous Beam on Multiple Supports 11111111111111111111111111111111111111 0,5h bb 0.25 b uJ %A ? 754_ 45 411.1. Air 12 A /117 6;?117/ h A ? - 13 6-744 (;)2b) K - en/ fig 32 fir loiffs1 fircielod km/ - ent /432 fir pun'/los/ /* Fig. 36-h -Uniformly Distributed Load in a Continuous Beam on Multiple Supports Inclo sure #78 to AFCIN-1A1 e IR - 1804 - 57 di tin . All e in steel K- as in Fig. 32 for center load Allowed, unit stress in steel K- as in Fig. 32 .for uniformly distributed load - as in Fig. 32 for center load 31 October 1957 11 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 ?46.. ? .41 Apts4 54_92MW )4A, 45) - 14 1.1.41101 A . P(if 44 ^/1 6A1(f.# # az 4) K - Cod fif 32 firpwrdier.il A . .truwen 4:04,4 # 42 bj) - Fig. 36-c - Point of load Applied in Midspen of a Beam on Three Supports A ? = t24) 61 (f.4 0. 0,2z) A gqiyo,ms- 4 or7529 If M- enkq/ itiq 32 fJrpunH//Gs/ g -col* lig 32 firfirmt/ firers/ad /as/ Fig. 36-d. - Uniformly Distributed Load, in a Beam on Three Supports ?,,Agesre...1.41\RARSzaw. I;?nag Allowed unit stress in steel as in Fig. 32 for center load dine Allowed, unit strees in steel K - as in Fig. 32 for center load tc!. as in Fig. 32 for uniformly distributed load. FIG. 36 - REQUIRED REEENFORCEMENT AND AREA UNDER SEVERAL TYPICAL CONDITIONS OF LOADING. RANGE OF VALIDITY: 3 >1/h )1 Inclo sure #79 to AFOIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part. Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 BIBLIOGRAPHY The most outstanding works on the theory of elasticity: 1. H. Craemer: "Spannungen in hohen, wandarti en Ti,-ern under besonderer BeraCksichtigss des Eisenbeton - Bunkerbauer. - Stresses in wall-like (deep narrow) supporting beam with special emphasis on RC bunker construction). Bericht fter die II. Internationale Tagung fur Br(Ickenbau und Hochbau, S. 706. Julius Springers Verlag, Wien, 1929. 2. H. Craemer: "SpannungtEla_wandartigen Tr ern bei feldweise wechselnder Belastuu." --(Stresses in wall-like deep narrowl?ETIFFR-Eg beams with varying loading in different spans). Zeitschrift gdr angewandte Mathematik und Mechnnik? 1930, Bd. 10, H. 3. 3. H. Craemer: " ?annun en in durchlaufenden Scheiben bei Vollbelastung sAmtlicher Felder." Stresses in continuous slabs wit all spans fully loaded). Beton und Eisen, 1933, S. 233. 4. F. Bleich: "Der gerade Stab mit Rechteckquerschnitt als etenes Problem." Straight bar with rectangular cross section considered as a two-dimensional problem). Der Bauingenieur, 1923, S. 255. 5. L.N.G. .lon: "On the Approximate Solution of the BendiN of a rje.alf ectarross-sectio_nz_z_UnderanSstemofLoad.' Phil. Transactions of the Royal Society, London, 1903. Vol. 201, Series AL, p. 63. 6. Th. v. Karman: "&er die Grundlagen der Balken-Theorie." (The principles of the theory of beams . Abh..ans dem Aerodynamischen Inst. der Techn. Hochschule, Aachen: H. 7, 1927. 7. F. R. Seewald: "Die Spannungen und FormAnderungen von Balken mit rechteckigems Querschnitt." (Stresses and deformations in beams with rectangular cross-section). Ahh. aus d. Aerodyn. Inst. der Technischen.Hochschule, Aachen, 1927. Works concerning rules for proportioning RC deep beams: 8. H. Bay: "Veber den iannun szustand in hohen ern und die Bewehrung von EisenbetontragwAnden." On stress conditions in deep supporting teams and the reinforcement of RC load-bearing walls). Konrad' Wittwers Verlag, Stuttgart, 1931. 9. F. rischingern: "Die Ermittlung der Eisenanl en in- wandarti en TrAgern" 1Calcu1ation of reinforcement in wall-like(deep narrow) supporting beams). Beton and. Eisen, h. 15, 1933, S. 267 Inclosure 480 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4 Declassified in Part - Sanitized Copy Approved for Release 2013/02/25 : CIA-RDP81-01043R001600080008-4 44:71" , Valuable abstracts: 10. W. Petry: U. P. Nemenyi: 12. H. Creemer: "Scheiben und Schalen im Eisenbetonbau." (Slabs and shells in RC construction). Int. Ver. f. Bruckenbau und Hochbau, Vorbericht 1932, S. 267. "Schalenaund Scheibenkonstrdktionen." (Shell and slab construction). Byggningstatiske Meddelelser, Nov. 1934. "Der beutige Stand der Theorie der Scheiben-Trand Faltwerke. in Eisenbeton.a- (Present state of the theory- of RC slab-beams and folded slab construction). Beton und Eisen, 1937, h. 16. 13. H. Bay: "nDerfgjlufK_j=121g2Et/adaKgmge_TF_4ger_iqStadium II." (Simply SUPPOrtii?ilid'aillik6-a64,-iiii6i)-Eii-ITETTO-I1). Der Bauingenieur, 1939, S. 375. 14. O. Graf, E. Brenner, and H. Bay: "Versuche mit einem wandarti en Tr r aus Stahlbeton." (pests on a wall-like deep narrow beam of RC). Deutsdher Augschuss f?r Stahibeton H. 99, Wilhelm Ernst & Sohns Verlag, Berlin 1943. 15.. H. Klingroth: "Versuche an StsMbetontraganden und deren Auswertung." (pests on RC load-bearing walls and their calculation). -Beton und Eisen, 1942, S. 91. ,\ Inclosure i81 to AFCIN-1A1 IR - 1804 - 57 31 October 1957 neclassified in Part - Sanitized Copy Approved for Release 2013/02/25: CIA-RDP81-01043R001600080008-4