Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIUENTIAI Titlo s FINNISH STATE RAILROADS 1912-1937 Souroet Portiona oZ Finnieh book, Valtionrautatiet 19124937 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 50X1 -HUM  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL s_sx, sa`LnES The following ore selected translations fos the dooutent Volticnreytot et 1912.1Q17 (pinntsh State Nsilroods, Vol XI) , pub" 1ish.d 1937 in Relsinki. p67 1 June 1918 the Pinaish Senate authorised the Highway mad Waterways Qonstruotion Administration to initiate studies, with all possible haste, for the oonstruotion of railroad lines between braes and Miealabti, which would also pit extend to Oulu via Vosla, and from Mieslshti to Ka3uuai. Surveying operations were begun in June 1918 and were acupieted before the end of the year. The length of the main line from Only to Nuraes was to be 271.3 kiloasten. The construction of a branch line of 25.8 kilometers and a terminal station at Kontioauki was also recommended. The Diet decision for the construotion of a standard gauge line from Nurmes to Mieslabti vie Vula and to extend the Savo line from Kajaani to Mieslahti, as well as the decision to follow the south bank of the Oulu oki in the construction o! the Vaala?Oulu line, was approved by the existing head of the Finnish govermoent on b September 1918. The Diet deoisioa for the construction of the Vu1a?Oa1u line had been made already daring the second session of the Diet in 1909 and according to these plans this line would have been oonatruoted on the north bank of the Oulujoki. The decision for the building of the Nurmes-Hieslohti?Vaala line was made during the session of 1917. The Highway and waterways Ooristruotion Administration de'eed on 24 October 1918 that oonstruotic operations would begin first ,.. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL  CONFIDENTIAL an the Nuus$.Miea1abti.Kl3m.fti lino with the Oulu^Y cola suction in next order, work wan oonsoquent~r be in Novo n sour at Murmos, sotkaro, and Ka jaani, but o3 proli~i r .rats oA ons of warobouso oonstrtuotion and procurement of oooetruotioa t ~ was oo'pleted by 4he cud of the yar+ p 68 The final sur i vey ng of the lin e war ooo~leted during 1939, a change in the course of tho lino at Sotkajkri in Ota a jarvi parish was eff.oted, and plans aide for the Jaalsnks and the Xioh isl harbor lines CD the shore of Oa1rvi. Part of thi surveying operations whieh were be at the end of 1918 were teroinated in -f part during 1919 for lack of turd. This work was continued only at Kajaani and dotkamo !1 ~ while the projects 0 is Nurses and Va1timo riches were ~ ~~ dropped. Sinai the budget reoommendation for 1950 was reduced to 1,000 000 mar kr;with a view to terminate the entire project by degreestwork was halted also at Sotkamo at the end of 1919 and operations continued then only on the ta~aani.Xontiojki portion of the line. Fork oompleted in the Nurmee and the 9altimo parishes included the clearing of 12 kilometers of line, procurement of building stone and gravel at the sites of bridges and oulverts and the Daring 1920 work was in progress only on the Ka3aani-Kontiomaki Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 south of the Satkamo lakes near Kajaeni to produce lumber for the on the Xalaeni-Kontioatki portion and a sawmill had been constructed wayside station, Most of the oulverts and ditches were completed at Sotkamo, plus ? work on an extensive out near the Puokatti sites and to streams for floating, similar work had been oo leted mP cutting and hauling of timber from state forests to oonstruotio railroad project. building culverts, and bridge construction. Construction of the portion. This consisted principally of making outs and fills  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL y bridge ferroaeoaorete Petaiseako,1ci/st Ka3u i by a private ooatraotaar Ws also oooleted that year. In 1922, work eontinued, as below, on7 Z the portion between KaJaani and gonticm ki. Cutti filling operations pr ued, o the 8irimi~3oki bridge was completed, and en onderp&U was oonatrid w.vNd4 Iwfi1Nfor the higbwa7 leading to the Pet4isensiska lam, 1 tbree~aaib and an eight-unit rultiple lawoiiy dwelling$ were built at the fajaani station. The work progressed to the stage during 1922 that it was pos? sibie to lay the rails as far as the Kontios&ki station. An e~ooa? eating machine was prooured for making outs and fills, whioh was also used to iced gravel on rail oars for the roadbed, applied 1 January 1923? The unoompleted fills of the Xsjaani?Kntiomaki line, located mostly at Kontiomiki end d~- Jormua, were finished during 1923 and additional gravel was applied to the roadbed. Construction of No residential construction was done during the year and teoporary housing feoilities were therefore provided far the operating per- sonnel. The section of line was opened tea~crsrily for traffic and direotlr from the oars to the road as the laying of tracks progressed. special oulverts and bridges still continued and the required hou- sing was built. The line was tied to the network at the end of 1923. The Diet decision of 1924 regarding the continuation of work on the Koatiomaki?Nurmee branob, made in oonjunotioo with the annual budget report, was that operations would be resumed if the ooamranes concerned, or private individuals, were willing to ueume arising frog the damage or lose of value of land or water aruu responsibility for that amount of monetary compensation olaias resulting from the construction of the railroad which was in, excess Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL of the aoostat deemed reasoaable by the govsrnmeat. The rate pro pored for the Use by the Rdlroad ?dainistratio~a o0 9 Jsnaary 1925 Qsbinet a 26 Msroh 1925 as omitted. 1 siaul? was apprornd b7 the 00 of the Cabinet decreed that those portio $ at the tuneonr deoisi laM or the re-tlrood which were cwn.d by the stets would squired ! State !erred without cap.uUtion to the/Railro.d. be tr.u- of the Koatiom ki?ilho1C tti portion were oompleted A pert of the assts and work was begun on the reuining ants. 0n37 the during 1926 ditohes were aompleted and a limited .mount of work most essential its and bridges. The Xajuni station was expanded was done on calve ins stall was built at YontiomIiki. and an eng Muoh out and lilt work reaained 4' to be done on the Roatioalki? puokatti portion at the beginning of 1925, but this was virtually the summer as far as the site of the Tenetia'irta oornpleted during bridge. Most of the !ills between the bridges were also corn- small bridges were built, as well as the abutaeat$ plated. Tour for the bridges over the Tenetinvirta, and rails were laid as far a. Rousing units were constructed at several stations. as Tenetinvirt oonstruotion of the Kontioraki4iehia The Cabinet authorized portion on 28 May 1925 and approved the route on 10 June 1925 and bone were began the same year. Moat of the !ills were oorn? were constructed, the foundations for the Mies j oki plated, oulverEs were laid and 5 kilometers of rails were laid that year. bridge we entered The oonstruatio cperation$/XSi* a new phase in 1926 through an not of the Diet which specified k the extent of these activities during the period 1926-30? The provisions of the act oalled for ontiornaki$0tkami and the Kontiomaki? the ooa~letion in 1926 of the K u portions , and that after 1926 work mould be carried on Kiehirna on the Oulu4urrne8 , Oulu-gontiomeki, and the Kontio simultaneously ions. Uncertainty regarding the availabiltiy of maki-Nurmes port - -b. CONIDNT!Ai. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  CONFIDNT1AL lends was thus removed ad oastruotioa oa a oo. crdiat N plan beoua possible. A oonditioa epeoilfed for the oonst ruatioo of th. 9otkuou'mss line was that the oaemunes sons mast iske arraageantm in advaooe for ooapen.ation loo' the land and rater area ooooeroed. Fills, culverts, bridges, pad laying of traoks vas o omplsted oa the XoatiooAlci-Xiehim~l section in 1926. The erat ~ ions on the Xootiom1Lki-Vuokatti (9otkamo) seotion rash ed as far as the gravel hill of XuikkaharJu and to the 8otkamo which the Cabinet had authorised for oonatrnotioa on 30 April 1925 at the request of the 9otkaao commune. Roadbed filling erations oP rose completed oa both of these lines, the rails hid, and final appli cation of gravel on the roadbed was made during the year. ~ Rowing for personnel was built along the line virtually as far as Vuokatti. Operations were extended to the Vuokatti-Nurmes section where little work had been done thua far, in March 1926, obisf to r ly the portion of line 23.5 kilometers in extent between Vuokatti and 9aviaho, and in lesser degree to the sections between 9aviaho and Maanselkii and at the end of the er to the ~ section between Maaruelk~ and Puukari. The latter two eeotione have a combined length of 26.5 kilometers. Ditching and cutting operations were ccmPleted on the Vuokatti$aviaho section with the exception of the extensive out at Laa~am~ki 5^.~e ,, between Vuokatti and Juuri kkalahti, from which 45,000 cubic meters o! earth, or a oximat pPr sly one-half of the required amount, were removed. Culverts were constructed and work progressed on the foundation and masonry abutments of five bridges. Dwellings were oonetruated at several stations. The unoompleted fills and bridges between Vuokatti and 8aviaho were put in order during 1927. The eatting and filling operations of the 9aviaho~Rumo-xokko~oki section progressed rapidly, and while all of the outs were completed during the year, only a minimum Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  CONPIDE11 amountOroadbed fill wos applied, espeois117 between Savisho and A YaanrelkI. All of the tricks of this projeot were also laid that 7$?. p 71 Since the funds had been used somewhat is ish1y esr].7 in the leer on the 9avisho-Maen$e1kI section a reduction of the nuaber of workers would have become ueoeseary during the latter part of the par. In order to forestall suoh in eventuslity the Osbinet sppro- v.d additions] funds which were used to extend the roadbed filling operations to the Kokkojoki-Puuksri section and to carry out preli- minary work on the section between Puukari and Nurmsa toward the end of the yeer. Six bridges were built during the year and abutmente were oonetruoted for several others, numerous oulverts were built, and dwellings were oonetruoted as far as Puukari along the line. During the winter the main labor force was concentrated in the section between Nurmee and Valtimo to make lake fills sinoe these would have been difficult and ooetlyAduring the summer months of the 1928 work program. Cutting and tilling operations were oarried to such a stage! during the winter that it was possible to he 1 the tracks on/Kokkoj oki-Nurmee section in the autumn. Hauling and to the riIl from the Poroky111 gravel pit in Nwhnssi of gravel from the gravel hill of Maaneelk~ to the Saviaho- Maaneelk& and the Maanselka^Rumo sections was begun in April 1928, P and ..!'rW'Ito the Polvij&rvi fill from Valtimo. More than .are built two wooden overpasses were erected. Some housing vas constructed and the Va1timo~oki wI!I and a number of other smaller rivers and 50 oulverte were built. Bridgee/aver the Kokkoj oki, Verkkoj oki, un on the Msaneelk&-Karhunpaa section. was aonstruoted. Operations were iapedid by exton!ive housing the favorable weather oonlditione of 1929 and the neofAsar7 during All of the fills of the Kiehiml-Ntnrafle$ section were completed Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part-Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFWEHT1 sinking of the roadbed whioh necessitated the gang of traok in two places a total of 1,700 raters of traok. of liae beW.ea O z1u and Kiohiai ? p 72 Conet1totioa of the porti of the oagu4a line was nndestakna in 1926 under the provisions the the riod 19~6~30 off sot oorertng oonstruatioa of railroads du~'ing Coeaetruotion of the Oulw?Vsala^giehi1I seotion wee underbsken on oondition that the ooawunos involved would assume in advaaoe res? onsibilit for obtaining the right of wsy. The route surveyed p ~ iihe for the 0u1u?KiehimL in 191849 was approved by the Cabinet on 25 Februs 71926. Cabinet authorisation to begin the work was not given until 21 May 1926 owing to the delay of some of the communos in fulfilling the stipulated oonditions. However, the Cabinet granted permission before this date to begin certain neoessary operations which of ne? oeseity had to be done during the winter, snob as the procurement of gravel for roadbed, building stone, and lunber. This type of work was aooordingly begun on 1 March on the 8aeristonkatu under- es and the xaupungino5a bridge in the city of . Oulu and sub? Pa se9uently on the 0u12-MuhO$ section of line. Delay was also brought about a petition to use Kempele rather than Oulu as the ter- minus whioh however, was re3eoted by the Cabinet. The route eur? ve- in 1918-19 was followed with only minor deviations. The 1926 construction program called for operations on 44 kilo- meters of the line to a point between *the Oulu station and the switch of the Hyrkkd spur. Most of the roadbed fills of the Oulu-Muha$~oki section were completed, numerous oulverte were constructed, foundations laid and aeonry work wais oompleted on three brides, and work on the foundations of the Muhoejoki bridge was begun during the year. Cutting of 120,000 cubic meters of earth and rook between the Muhos and HyrkkU stations got under tracks were laid on the section between Oulu end lithos. CONfIDEItT!A1m Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  !ctensions of the 8aaristonlcatu underpass and the ginoja Sine praotioally all of the objeatives for the year were ohed already in October, the plan for the fear was inoreased to rea provide amp1o-finent for the labor fora.. The additioaal !wads obtained for this purpose were used ohief if for bridge and housing truotion. The most important and dif f iault of the bridge buil- ooas ding operations undertaken during the year was the oonstruotion of the abutments for the Muhoejoki bridge. Thefoundatione for the supports for the Vaelensallmi bridge were laid and three to relieve the housing shortage. The 1927 work progra inoludid the gravelling of the roadbed of the Oulu?Muhos section and of preparing the track forservioe. Fork was to begin on the aeotion to the Uts jiarvi station and traoka were to be laid on the Muhos^Otajkvi aeotion, a distanoe of 22 kilometers. Tilts and culverts of the 34-kilometer nta3ila vi?9ula seation Here to be built to the stage where traokr oould be laid the following winter as far as Qu31s to permit work to begin on the Vaalansalmi bridges during 1927. Esnsion of the Oulu station was to be finished and dwellings were to be oonstruoted in Vula bridge at the On1u station were limbed. The new oaurse was on the south side of the Oulu?Kajaani highway aala in order to by-pass a number of crossroads 1' and ravines. and v line on 4 March 1927 slang a length of 8.5 kilometers between Nuojua Railroad Administration ohanged the proposed course of the The laying of traok was begun at the eud of the year. switching point and resulted also in the moving of the Nuojua one kilometer nearer Oulu. 3urve7e were made during the summer and fall to determine the most iuitable looation for the line in respect to grades on the portion near Niveawaarw on the north side of Ou1ujarvi. The prograni for 1928 inoluded the completion of the poi' CONFIDT1AL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Uts L'vi seotiod and budding the Uta jwrvi.Taaia seotion to the stage that it oonld be used for temporary service. The abut. eenta of the vials bridge were to be ooapl.ted and tha t heel struoturu of both the vials and the Mahosjoki bridges were to be .rooted. Housing was to be ooutruat.d as far as vula and a sew freight offioe with oonneoting track was to be built at the Oulu station. Most of the plan was oo 1sted before the end of the year and a large number of workers beosme uusmployed after the gravel was applied on the roadbed of the Muhos-Uta3itrvi section. The Diet, therefore, on 13 September 1928 approved additional funds in the supplementary budget appropriation for 1928 to permit extension of oonstraotion operations to the entire length of the vaala-KiehiaL seotion where no work had yet been done. 9urPVe75 had been oonduoted during the previous year to deter- mine 'lmc the mat suitabi. change in the proposed route of the line in the vicinity of Kiveevaara. The survey was now ooleted and the Cabinet approved the seleot.d route on 30 Ootober 1928. The ciliated route departed from the course proposed earlier along a length of 30.5 kilometers beginning at the switch of the 1i&o: Jaalanka spur toward Kiehimi, following the south aide of Kiveevaara, the proposed course having been on the north side of 'rh the mountain (Kiveevaara) . The line thus became 2,820 meters ? p 74 longer, but the total grade was reduced by 31.5 meters and a more advantageous course in respeot to proximity of waterways and pop- ulated areas was obtained. Considerable cutting and filling work and proourement of gravel and stone for oulverts and bridges was done on the portion between Tails and Kieflim~ during the final quarter of the year. Cutting and filling operations were oontinued b.tw.en Tula and. Kiehimt during 1929 and this work was extended to the portion Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  between QtsJirvi and Vssla, where it Us owried to oaipletioa. Appo'oxiaately 150,000 aubio asters of rill Dare removed from the Atari sad IMokatti gravel pits for this purpose. Tho sbutassti for several bridges were completed, including those for the bridge aver the KiehiaLa joki having a length of 84.0 stars. Rails were laid frog Paula to a point between Limimpuro sad Kives jLrvi and 215,000 oabio meters of fill from the xsakari gavel pit were applied S on the Ota3irvi4ankart section of line. The spars to the harbors at Kives j rvi and Kiehiid were ooaipleted and ereotion of the spans ewa in Ootober 1926/rne oospleted in of the 9aa1sara1mi bridges bg April 1929? Housing oonrtraotion at Vials was finished and this work war extended to the Vials-Kiehiml notion. During 1930, the final year of construction sotivities on this line , outtiag and filling operatioar were done on, the Vida-Kiehim~ . section and eves more extensivel7 as wiatei~ eperstioas between Kives jL vi and Melalahti. Extra fill was transported by train from Kanksz'i and Vuokatti mainly to the sinking fills on the bogs between a either end Limiapuro and KivesjIrvi and also to the large filhs/ on the remainder of the line. A total of 500,000 cubic asters of of the bridge over the Kiehiminj old,. The steel members of the bridge over the Xiehiminj oki were erected is the spring sad traoks were laid fill and roadbed gravel was transported to the Vasia-Kiehim~ section from the Kaakari and Vuokatti pits. All of the housing for the Kankari-Kiehim& section was constructed and a switchyard was built at the Oulu station. Numerous bridges were oonetruod on this line, some of which Kntiomiki section is a three-pier, concrete arch bridge, 50 meters merit special mention. The Petaisenkoski bridge of the Ka j sani- in length. The Teaetinsalmi osntilever and panel bridges with spans on the Kiehim~-mammas seotion. The bridge over the, Muhojd. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 of 60.0 and 22.2 meters at 8otkamo are the moot notabi of those  Declassified in Part- Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 OONflEN1t1 otion with pans and o*tievez $pUS of 16.0 the Og1n4(iehlma ~e and 64.0 aMetero r.quiz ed au.oh work for the 1qiflg of the f ounda- . tione artag to the nsfarozable terrain ? Ti hYaa1a~ua3ai bridge oki with spats of 21.0, 60.0, 60.0, and 21.0 netere, over the Oalu~ sx4 the oantilrrer bridge of d6.0 meters over the xiehia oki are aaeong the largot bridge struoture$ in the oountr7. The single i and the Kiehialnj oki bridges are also lane;f the Oaa aced to carry the traffic of the 0u usga jaani highway so that ferries are no longer necessary. buildings was necessary along a line of Construction apany this length. In addsLion to the stations, way stations, and freight warehouses construoted at traffic points, 46 housing structures, d watchman' s shelters , 2 arei6ht lodging hooves, one restaurant (at nonctiomki) , 3 engine houses (a total of 7 stalls), 9 water ~ were built, and taners Oulu and l~~s engine hoaxes were both ,~ ~ t the ate two more locomotives eaoh. The expansion expanded to aooorirod operations at the Oulu station included the construction also of a freight warehouse and an administrative building. new a line p 75 The tracks of the Ka~aani?Kontiomaki/ were laid during 1922, as aenticed earlier, and the/ta* was placed into temporary of 1923. work on the KiehimI?Nnrme$ line a - use at the beginning 1925 to permit the laying of 5 kilometer$ vanoed suflioiently rinsing tiomiki to Ko tioml~ki t Ric s o f r of trao tinvirta. Tracks were laid during the following year aastazsaac the Tens on the remainder of the line between Kontiomki and Kiehi4i, and irta onward to a point beycsad Vuokatti, as well from the Tenetinv otkamo harbor spur. Tracks were laid during 1927 as as on the S far as the Kokko oki and in the autumn of 1928 tracks were laid ~ on the remainder of the seotion from Kokko j oki to Nurmes was begun on the Oalu?Kiehima section on 15 Le,ying of track September 1926 from Oulu and reached the Mhos station on 1 December Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 entire line was opened for traffic on 1 December 1930. The coutruoted lengths of the seotiona of the Oulu-Nurmos and the Ks~sani?Kontiomr~ki line are as follows, CONfIDEN TM L CONHD!NT1A~ 1926. Trrao]cs were laid in 1927 to the BotkA wsj static and 40 kilareters roe of track were laid daring 1928 fror this point onward without inlarrwption ( to the Va4ansalri whioh no resobed on 24 February 1928. Liter the oaflotion of the Vu1anss1j bridge early in 1929, lazing elf troek wu rest at the bog of April to the Yule station and fraa that point onward to the Kankari gravil pit and wq station. This work was continued on 23 October, reaching to a point between Liwinpuro and Xivesjirri at the end of 1929. The work was carried on during 1930 as the fills were oam- plated along the route and ended lac on 4 June at the Heim oki bridge located between Melalahti and Kiehi r' ate track 1qing operations begun from Xiehim~i in May toward Vaal.. The xiehiml-V'uokatti siotith irrt on/ of tho action of 1i p ne between Kiehimi~ and Nurmos to be placed into to ora servio mA s7 e, on 16 Ooto. p 76 bar 1926, followed by the Vuokatti$aviaho section on 23 January 1928, the 8aviaho-Rtmo seotion on 1 February 1929, and finally by the Rumo-Nurses section on 1 M roh 1929? The Oulu-Muhos section of the Oulu end of the line was pat into temporary service on 1 November 1927. The final application of gravel was completed on the i~uha-Uta~'irvi section, which was put into teorary service on 1 December 1928 and after the final inspection was connected to the completed sections between Oulu and UtaJurvi on 3 December. The Utajarvi-Vaala section, 34 kilometero in 1e b was o0 n, mpleted and opened to traffic on 16 October 1929 and joined to the network. Most of the construction operations of the Vaa1a-giehime section were completed early in October 1930 and the final inspection took place on 10 October. Completion of the construction of the Oulu. Nurmes line was observed with a celebration on 29 November and the Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Oulu?Kiehii& section 150.407 kiloaeterr Kiehi1R.'Nunes notion V4.107 kiloaetera KonttoaIki-Ks jUX i branoh 25.296 9otkuo branch ..t3 -- Total 305.115 kiloaeters radii of the Kiveejervi and Kiehima harbor spurs are 300 meters. at Vuokatti has a radius of 300 metere) . The smallest curvature to addition to the above, the fofawing ride traoks and spurs were builtt Xives3l1'vi harbor spur, 0.635 kiloaeter$s Kiehiml harbor spur, 1.658 kiloaeterr l Joraua harbor spur, 0.960 kilometers i other side traoks and ` borrow pit spurs is0 meters on The smallest radius of ou rvature on itlat open traoks the Ouln- Kiehiml seotion (radii of 400 meters and 500 asters exist at the Oulu rd and the approach ourve at Kiehim~- is 500 meters) j the smallest radius Cu the Xiehiml~-Nurmer section is 600 meters (the approach owrvee of the Tenetinvirta bridge and the Nurmes station are 500 meters) ; the smallest on the Ka~aani-Kontiam~ki section is 700 meters (the approach curve of the Pedirenkoski bridge is 500 meters) j the smallest on the 9 otikamo branch line is 400 meters (the initial curve The largest gradient on the Oulu-Nurmee section it 0.010 and the largest on the Kajaani-Kontiomlki section is 0.012. The Kiveovaara harbor spur has a gradient of 0.015 on a 300-meter curve. The rail weights used on the main traoks are as follows $ Oulu-Muhor section 22.343 kilograms per meter 34.9 kilometers Muhos-Meteli section 30.0 115.5 klometere Meteli-Pnukari section 22.343 89.5 Pnukari-Nuraee seotion 30.0 34.2 Kaj aani-Kontiomlki section 22.343 25 3 NT1AI 155.4 149.7 ' Declassified in Part - Sanitized Copy Approved for Felease 2012/04/05 : ClA-FDP52-OOO39FOOO1OOO9OO57-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENT I The 22.343 kilograa per mater weight wee wed on the harbor spun ud rails of bath wrighta were used on the aide tracks. A total of 270,365,452.86 marks were emended in the oasatruo? tion of the Ou1u?Xa3sani?Nurnee liAs, of which 129 210 87 3.16 mark. wee used ooa the Ou1u?Kiehiaeotion sz d 141,154,579.7o marks on p 77 the other seotiaru. The oat of oocratruotioa per kilaaNter of track of the Oa1u?Kiehiai section was 859,075 parks and 912,394 parka per kilometer on the Kiebimw?~mani.,X atk~mo?8arnes portion, averaging 886,110 perks per kilometer coy the satire Liza. The enrage number of workers employed each year on wages and on contract basis is revealed in the following tablet Rage Laborers Contract Workers Total Iu~ )1j a (Kiehima?Kajaani-tea asotiozr) 1919 57 3 242 30 332 1920 30 2 217 33 282 1921 38 1 223 36 8 29 1922 47 1 331 58 437 1923 102 1 251 28 382 2924 11 1 261 51 324 1925 39 652 195 886 1926 88~ 2 658 116 864 1927 168 2 476 117 763 1928 222 2 470 177 87]. 1929 164 1 221 12 8 39 C Oulu-Kiehima section) 1926 116 3 339 87 545 1927 298 10 523 82 913 1928 256 8 539 46 849 1929 240 8 203 1,168 1930 152 5 451 46 654 CONFIDENTIAL  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 Thickness of gravel ballast at center line in sand oats 0.50 0,50 Thickness of gravel ballast at center line in clay oats 0.80 0.50 Far rook cute width of out at grade level 5,70 5.36 Width of out at cater edge of ditch bottcs 5.51 5.20 Width of cut at inner edge of ditch bottom 4.91 4.40 Width of bottoa of out ditch 0.30 0.40 Depth of out ditch below grade level 0.47 0.40 Slope of out ditch walls 111/5 1 t 1/5 Slope of crown at bottom of out 2.t20 116.5 p 168 ,?~l o! Ae~d~d~ Orate and fills have been aide to oonfora to the oross?seotions speoif ied in 1909 end 1924 for standard gauge railroads and to the aaeadaentr adopted ii 1936 (pig. 103.lOs) . The dimensions of the oroes?seotione specified in 1909 and 1924 are given as folloert P % q Par earth oats Width of out at grade level (asters) 9,00 8.70 Width of oat at outer edge of ditch bottom 7.60 7,30 1!idth of out at inner edge of ditch bottom 6.40 6.30 Width of bottomitah 0.60 0.50 Depth of cut ditch below grade level 0.47 0.47 Slope of ant ditoh walls 1 t 1.5 1s1.5 Slope of orown at bottom of out 1t20 1116 ballast Width of gravel/shoulder at upper surface of tie 3.50 3.40 Distance between outer surfaces of ballast- retaining aurbetonea 4.70 4,40 aapp Height of/ballast-retain ing curbstone= above grade level 0.50 0.50 Thiclaieee of gravel ballast at center line 0.50 0.50 For roadbed fills CONFIDENTIAL -15- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONPIDENTIAL width of fit1 at grids 1rve1 Slope of kxua sides of fill of fill Slope of ororo- tlidth of ballast at upper surf ace of tie Thickness of ballast at oeater line 5.70 lsl.5 5.40 1x19 1116 3.50 3.40 0.50 0.50 For ditches Average depth of ditches 0.60 0.60 Width of bottom 0.50 0.60 of ditch gall li 1.5 111.5 Slope istanoe between ditch and fill or out 1.50 lust be oom? D puted in each case The depth of earth outs in clay roil was increased by 0.3 meters f ication$ of 1909, the thickness of the gravel ballast in the speoi being increased b the same amount. This feature was not observed -' in the speoificationa of 1924, but the following preoaution$ sere adopted in 1928 to minimise the if heaving effects of ground frosts p 170 (1) all anderlying surface stones must be removed from the sites of roadbed fills 1.3 meters or less in thickness, to a width of the of the f ill, ( 2) where different types of earth fill are em- bottom ployed in a roadbed , these must be spread in uniform layers and not allowed to resin in heaps as forinerly, (3) stones at the bottom of removed and their cavities must be filled with earth outs must be from the out, (4) outs and their ditches, with the exoep- material tion of those made in gravel soils, must begin 10 centimeters below must rise in a distance of 30 meters to the normal grade level and rise must be made in !ills whioh do not consist levels; a similar are not laid on a ravel base, when progressing to a of gravel and bottoms of outs and tap surfaces of !ills must be higher fill, (5) levelled to the specified cross-section with material taken from out before application of gravel ballast; any depressions made by , ties must be similarly tilled, (6) gravel With olq aixtre, or . Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  ravel oafl'OaaUia4sd with oly during op.rstioa~, must ao0 bs aisd u ba33sit, (7) ?xoept ie tvnn.la , t6. travel ballet tut bi ap? plied to s ebiolQU.a of 60 e.ntim.t., msasnr~d from the vtppsr Snr!'aa. of tiis. Idiunr~i taken to overooaa~ ain1dg +wd rprsadizg of radb.d in untira terrain inalnd. diorsasina/ o! fill, looatin~ ditohis farther than normal from rcsdb.d, oopatruotion of oouriters~ighE liii.i real by bluting of ?o!'E mat.rial, driviag Pile, laying a Md of brush, and rsloation of routs. CONFIDEN 114 L Declassified in Part - Sanitized Copy Approved for Release 2012/04/05: CIA-RDP82-00039R000100090087-7 long, and 3.0 meters high is located at the center of the tunnel in employed in the Halikko tunnel, A chamber 2Ameters deep, 4ometers Three tunnel. have been built since 1912: the P ' 8nttc~ori tun. nil measuring 1,223 meters on the ~ amaalci line betrnen the Metsolahti and Lepp~lahti statione, the M u 7]q-nmaki tunnel measur- ing 360 meters located to the east of the Ves antra station on the fiaapamiki-j~n-u1~9l1 i line, and the Ralikko tunnel measuring iio meters located :net of the Halikko station on the Kar jaa~urku line. The prose-seotion illustrated in Figure 106 was empl d in "! ~ the P8ntto vuori and Yo7Ignmki tunnels end that illustrated in Figure 107 was addition to the rece$.es out as refugee for track w orke 50 meters apart on alternate sides of the tunnel and measuri 0.5 meters in depth, 0.7 meter. long, and 2.0 meters in height. The tunnels are out into solid rook and therefore do not require rei noforcig arohe. , p 171 Few tunnels h ave been oonattd ruoe on the Finnish railroads since the terrain seldom requires tunnelling, Among tunnels planned Hasp ki line to Virrol, and that on the Verkau5- Viini3vi line to Leppavirta. The first of these was abandoned when it was discovered but not out two are worthy of mention here: that ~h the Poorl,M that more fill was needed on the line than could have been obtained in cutting the tunnel.  ONFIDENTIAI p172 Ihilii Railroad ties ere to be out either tram health' growing piee trees or tram bmrkless standing dead pine which show so indication of rot or blue stain. Trees for ties must be felled daring the period 1 Noverber - 1 March. The regulationp of 1913 specified two types of railroad ties, one for heavy traoks and the other for light tracks. The heavy tie had the following specifications, length, 2.73 meters; disaster at thinner end, 250 millimeters; thickness between hewed sur- faces, 160 millimeters; minimum width of hewed surfaces, 140 millimeters. The specifications for the light tie wens length, 2.50 asters; dia- meter at thinner end, 225 millimeters; thicknua between hewed sur- faces, 15o millimeters; minimum width of hewed surfaces, 130 milli- meters. Only one type of tie has bean employed sinoe 1925, whioh has the following specifications, length, 2.70 meters; minimum diameter at thinner end, 225 millimeters; thioknees between hewed eurfaces, 160 millimeters; minimum width of hewed surfaces, 150 millimeters. Purchase of undereise ties with diameters less then 225 millimeters at thinner end, but not less than 200 millimeters, was authorised up to 10 percent of total procurement. p 174 Three grades of railroad ties were approved for use in the pro- ourement regulations adopted in June 1936. These have thin end dia- meters of 250, 220, and 200 millimeters; procurement of the emsllest grade may not exceed 10 percent of total procurement. Thickness be- tween squared surfaces iii 160 millimeters in all grades and the mi- nimum width of squared surface in the first two grades is 150 milli- meters and 120 millimeters in the third grade. Unidirectional our- nature up to 15 centimeters is permitted. These regulations speoi? f7 that the trees must be felled between 1 October and 1 April (1 Ma in the area north of Oulu). Placement of ties and other data are given in the table on page ?A 'k r;a`Ar Declassified in Part Sanitized Copy Approved for_Release 2012!04/05_ CIA-RDP82 00039R000100090087 7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL total The/value of all railroad bridgee was appraised at 397,604,935.00 ten) and ohs Ouneskaki bridge it Rvvwi.mi (340 metsrs), each of Finnish bridges, however, are the Jyrnko bridge at Heinola (360 me- distanae between abutments is taken as the length. The longest bridge spans in Finland are 125 meters in the cantilever bridges over the Isohaara of the Kymi~ Oki and the Kyronsalmi at 8avonlinna. The longest and concrete bridges, sinae,%kiritu'rwgjrk of steel bridges Ss takea the Uncertainty also exists in the measureient of the length of masorirr in the ease as that of steel oonstruoticn, but the number o! span crossings is considerably greater since these bridges often carry several traoka. man and Iaint.nancs of Bridna The Finnish State Railroad network of approximatel~- 5, 500 kilo- crossings uteri contains over 2,000 bridge4 containing 1,990 steel spans, of which 215 are of oantilever construction with a combined length of 7, 500 deters and 1,773 panel spans with a oorbined length of 11,100 raters . The amount of railroad line that is tkmtiv laid on bridges is therefore 18,600 raters, or 0.36 percent of, the total network. The number of rasonry and concrete bridges is approximately the same whioh have several spans. marks as of 31 December 1935 and the turntables, which atsxsftre in oonetruotion oosts have been exoeptionallg high on those lines which one-fifth of the total malt construction cost of the line. Bridge marks. The cost of bridge construction on the newer lines approaches many oases are thought of as bridges, were appraised at 25, 541,762.00 p 265 cross waterways, such as the Rovaniemi-Kemijarvi 1in~ where this bridge construction on the Lahti-Heinola line was 25.2 percent of the item accounted for 25.8 percent of the coat. The expenditure for total cost. The lowest bridge construction expenditure was on the tisalmi-fiviesko line where it rras 10.5 percent of the total oat. The total aa~ tired property valuation of bridges amounts to Declassified in Part _ Sanitized Copy Approved for Release 2012/04/05: CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 p286 CONFIDENTIAL fixed praperty valuation of the rai1xoadr 9.8 percent of the ureic/ A espital invortMnt of this asgnnude neoersitateo ? oentralieod of oonstruotion and iaintenande' A rpeoial and controlled prrogr?x dopartment for t. d?siping. planning, ooartruotion, and aaainten?noe - rtreet, and pedestri*A bridges war lord from of railroad, highways offioes in the riarganiaation of the Adaai5$t2'a the carious railrad Railroads , which took plane after Pinnirh indepen? Lion of the State - denoe . In the oourse of its operations this office (kaaoran as the , the Teohniaal Aail Office since 1933) Bridge Oonstruotion Section of ar, in additioaa to its regulir duties, drain up neoessary regulations b for its own use as well as for general railroad operation. The load- ing and computation regu1atio1 adopted for bridges in 1926 and the new actin, assembly, and proourement of rteol standards set for the buildings , also adopted in 1926, are r?sultr members for bridges and adopted of the efforts of this office. These regulations bane alto boe as general direotiver by the angineerr of the oonntry in all fields. The maintenance and rpu envision of bridges had been dependent otionr until these regulations were issued in upon irregular inrpe 1927. There regulations specify annual inspection of all bridges b7 the chief of each fine, the results of which must be recorded in a nbridge book." A general or main inspection of all the bridges of a line must be carried out approximately every seven years by the chief with a bridge engineer of the Bridge Cons- of the lice together truotion Section and ? complete record and report must be prepared. The main inspections have revealed that painting of bridges has Lack of fuude, low quality of paints, and frequently beev deficient. etanae were the chief reasons for the short- inadequate teohnio?1 uses e i for the painting of bridges and other steel coming rtruat$rer of the railroads as well as quality a*d proouriment stan- issued in 1934? Replacement of bridges dards for .paints.: here Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  dan.ral pu?R of Yard The futility of attempting to meet the growing traffic demsid$ of large stations t.mporarily by~~M s1~sllation of use expensive facilities became appar.nb even in Finland at the olas of the 50 year period of ruiirad hi.tasy of the owntry. A program of long" time planning *si$i1NailUS in the reconstruction of/s~+d~a Res therefore begun early' in 1900. Faoilities of the ourrent period bear evidenoe of the planning and construction program undertaken at that ~l~oc time. Both the regular And the wayside station4of the netrork~t have, almost without exception, fairly modest beginnings. Experience gained during earlier decades of growth of smaller railroad yards has fur- niehed the basis for a standard plan (Figure 208) for small yards which provides possibilities for future expansion. Observation of worldwide developments in yard technology has been necessary, on the other hand in redesigning the larger railroad dQ yards. The i ortanoe of the railroad network as a medium of transpor- to the oountry is demonstrated by the extent of the system tation ortanoe of the stations is indioated by the total length and the imp of branch lines. 1 knowledge of these two faotore and their rela- tionship to one another is therefore necessary in order to gain en .4 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL as a result of rusting has never been neoessary on Finnish railroads, however. Frequent reAlaoement of bridges has been necessary owing ~'~ to the rediotabl7 rapid inoreare in the weight of trains. if etime of the spans of large bridges is dependent upon the The 1 amount of aaintenanoe, and more apecifially, upon the extent to whiob rusting can be prevented. 287 P  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 GONFLDETIAL understanding of the development of the railroad systea throughaat the ye. Daring the period 190.30 the percentage of branob lines of the Swedish state railroads varied from 25.04 percent to 37.20 percent and 3 x.66 percent, the corresponding figurer !rte in Finland being 27.O percent, 36.00 peroent, and 34.00 peroent. The objective in the planning of railroad yards is the satiefso- tion of the aameon requirements of both oaemunity and railroad. Funduentally only one best solution therefore edsta for eaoh pro jeot, though in individual oases several alternatives nearly as good may be present. The plan of a large railroad yard generally includes three dif? ferent types of seotiona; a pusenger station with servioe yard, a freight station, and a classification yard. The fundamental problem of the plan is to solve all three phases, at least in regard to their p 288 locations in relation to each other. If, however, some of the tit details may be left for future solution, the overall plan may then be considered all the more euooesstul. Passenger etatione are generally permitted to remain in their original locations in the redesign plane and additional space require- menta are met by utilising former warehouse and freight station areae. The freight station must then be relocated at the outskirts of the community where space is more readily available. Since the etaticn building has a decisive influence on the future development of the oommunity, these are located as near as poeaible to the original buil? ding. Another arrangement may be neceseary in larger cities, as experience in other countries indicates, where new stations have in several instances been oonetruoted as far ac a kilometer from the original station building. The new station in Viipuri was built 200 meters to the north of the old building. The proposed site for the new Helsinki etation has been the subject of much controversy during CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL the pub 20 years p 290 Plant hr new passenger stations at t also tike into aooauat the need for numerous loading platforu of sufficient length and widbh and pedestrian underpasses or the more usual overpasses . The plans in of the stations us aade with this/view by planing the aystsm of traoks either above or below street level. This also serves as a solution to the problem of stints *hioh oross the yards. Transfer of baggage, express goods, and mail to the proper plate fors generally oocurs on the same level aoross the traoaar. When required, depending on the bas is type of passenger station, the vol. uae of traffic, end the level of the tracks, special tunnels and elevators are built for this purpose. The service yards (Figure 209) of large volume passenger to trage f io terminal stations or branch stations where trains are made up, offioe are quite extensive. The express goode/k?u is located in the station itself or nearby (Figure 210). Since most of the business and income of the railroad system CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 for more rapid and economical service as well as the competition mint of these facilities. The greater demands of the business world is derived from the transportation of goods ankh attention has been given in railroad technology during the part 25 years to the develop- offered by other modes of transportation have encouraged this develop- mint. The yard facilities required for goods transportation are of two typesi goods (freight) stations and classifications yards. The freight station is that part of the i freight yard facilities in which the sender and the consignee come into contact (Figure 212). The warehouses, office, loading and unloading tracks, and other fae oilitier are of simple construction and may vary with requirements of the volume and quality of goods and local conditions.  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL Partially I. I result at increased oonp.tition transportation of goods by rail is undergoing new develapaent with such innovations as refrigerated oars and pickup and delivery service. Much roan for inproveaent still lies in this respeot since the handling and lading of parcel goods still takes 57 peroent of the oat of this type of servioe j asking of traiw, 15 peroent, and line transportation costs 28 peroent. Fortunately, paroe1 servioe accounts for only a nail portion of the goods transportation aotivity, approximat. y 10 per- oent. Freight transportation by the osr~,osd, which amounts to 90 peroent of the volume, does not require muoh by the wqr of handling facilities at stations. In addition to the tracks provided for the loading and unloading of freight by the oariosd at freight garde, special siding. are built at harbors, industrial locations and elsewhere in larger towns for this purpose. Construction of similar faoilities for the handling of parcel freight at various points in a oity only increases the cost ~c of parcel transportation, but saoh facilities are not even neces- sary since the railroads are increasing their pick-up and delivery service by the use of other itnc mans of transport. Little attention rru given is lormex tree to the organization of trains and ttisss were made up of oars Rithaut regard to any order. of This method required little by way/added tracks for the king of trains sine. the trains were made up on the main track by the use of sidings. Much time was lost, however, at intermediate stations and as the volume of traffic increased and for considerations of safety, it became neoessary to separate freight and passenger facilities at stations. The systematio formation of trains was recognized a1 the most expeditious and economical method of handling freight and the problem became that of designing systematic and mechanized classifi- cation yards. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIDflITIAL p 292 The two main faoton in s olusifioation yard ore the trriok systea and the active power. The first development in o1ueilioatioa yards was extensiod of existing traake and the oonstruotion of tracks parallel to this. Use of the main line as the asseably track was the next to pus and assembly tracks were built at either or both ends of yards. Per? forasnoe of several funotionr on one grog of tnoks soon beosae difficult with a oonrequent division of funotions between separate groups of trooks. The olusifioation yard thus developed inoludes lour groups of tracks, i.e. the approach group (Figure 211), the di? reotionai or separation group, the station group, and the departure group. In addition, traoks are required for traotion, oolleotion, shifting, transfer loading, standing, empty oars, spare oars, fail, warehouses, and other uses. The smaller olassifioation yards do not include all of the !t above tracks and groups. fihen the oonatruotion of a olaaeifioatioa '*rd is inaluded in the redesigning of a traffic center the selection of type and site must be suoh that it becomes part of the general soheme. The seleotion of the locations of eaab group of traoss in respect to their relative elevations and grades in such a center is one of the moat difficult problems which lace the planner. 1 well-designed classification yard must be able to handle a large volwee of traffic, and must have loin costs for the assembling of trains, and must have ample provision for expansion. Groups of tracks are designed to fan out at various p 294 angles (118.5, 1s8, 1:7.5, and I t 7) . Separation of tracks in a classification yard is standardised at 4.8 meters, or may follow the smaller pattern of 4.5 meters separation, in which case the separation of the fifth to seventh tracks may be 9.6, 9.0, or 6.0 meters. Even in yards employing the standard aepa? ration where there are numerous tracks frequent use of a 9.6?meter separation is made in order to facilitate removal of snow and to ?25. CONFE~9EflT9~l. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 tic in a station xtk* from the lines is mainly of two types or of differing volume, some arrangement of a two-sided type of yard may be or the same reaeon a one-sided yard may have two eeo- appropriate. F Lions , in which case it may have two parallel trunks operating in the aecifioation. The Pasila olauifioation yard is same direction for of provide space for telegraph and telephone poles ? it least a few of the tracks of an approaob graap must exoesd in le~agth the lest trains, and those of the separatioa group vary frci 254 to 700 asters, of the tracks meet be lover if trains are to de? but even here some Dead sad tr~care sanotimoe ompl~-!d pert directly from this graxp in station groups, but the through type of 200 meters or lees is sore coaunonlY used . approaoh, separation, and departure traoks are always The number of traoks in eaoh group depends on of the through type the volume and type of traffic and the method of assembling train. The olassilioation yard say be basioally either one-sided or two- sided depending on whether it has one or two trualce formed from track groups . Only one main type of olassif ication activity can be performed one direction on the first type, while the latter at a tine and only in rooessee simultaneously and in opposite directions. can ?ooommodate two p The one-sided type is the moat oommon and suitable to small-volume i olassifioation yard is of the one-side, single traf f io. The niipur section type where both inooming and oatgoing trains are handled over a single dorm grade . In larger olassifioation yards or when the tref- of this type with two do --gl'adee (Figure 213) . One of these is used The first has two tracks of differing heights, of incoming trains. for the formation of departing trains and the other for the separation one for use during summer and one for winter use. * of !actor in a alaesifioation yard is the motive The second chi though manpower, horsepower, and motor parer are emplcyed to sane power. Locomotive power continues to be the moat common form, el- Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONHDENTIAL extent fox' the eider operations, espeoially is ersU installations. Shifting of oars by locomotive frequaAtly results in' daaage by jarring both to thA oars and their cargoes. In earlier tins wben oars wbere equipped one,' with maaaal brakes, if any, this oould be avoided by a brakeman oa each err during shifting, but this method roquired large orewr. Carr not equipped with manual brakes were slowed down by p 295 means of wooden levers and other methods. A brake ehaducmiv to devised w cberated satisfaotorlly oA be placed on the rail was soon in the hands of as experienced brakeman. Use of gravity as the motive power began quite early in olassi- tiostion yards end was fully developed by 1870. The amount and effeot of gravity power employed is aced as a basis in dividing o1aseifioation yards into either level or graded yards. Either gravity or looomotivee may be used to furnish the ini- 296 tial motive force in level garde, while only gravity is used in the P graded yards, in whioh all four groups of tracks follow one another at the same grade. In this type of yard the oars coast from the ef- fect of gravity all the way from the approach group to the outgoing group of tracks. Favorable terrain is required for the construction of graded yards so that the neoeeoary difference of elevation of 20 to 25 meters between the ends of the yard may be obtained with a mi- timua of cutting and filling. The graded yard makes full use of gravity, but because of their extreme length and otheb disadvantages they are suitable only large volume traffic ? The level yards can be made to fit terrain and space requirements much more easily and are suited to kk traffic of either large or small volume. Claesifi- cation yards may also be a combination of the two types. The most important part of a classification yard is the descent grade section between the approach and the separation groups (Figure 214) ? A train of 60 oars can be separated in six to seven minutes in a modern classification yard. Control of the coasting movement -2 I - CONFIDEP1TIh1 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 In the redesigning of olassifiastion .ysrds the yards are relooated to Derr sites outside of the oommunities, and in the asse of large railroad hubs, they may be located doyens of kilometers array in the direction of the approaohing lines. The various liner must be so arranged that freight trains may enter the approaoh trsoke simulta- neously, therefore a suffioient number of trsoks must be built at different levels. CONIOEt11IaI p 2917 of oars has led to the development of meohanised, remote controlled, and eleotrioally operated brakes. Two para11e1 eloping tracks of different down grades n for cum- mar and 'winter use were built in classification yards during earlier times, but with the a improved rodern system of braking csra two slopes are seldom employed. p30? A shorter, four-hole type of fishplate was adapted in 1919 to 30 kg/m rail being to replace them on the Teri~oki?Koivisto line. were removed in 1920 and installed on the Hel$inki-Riihimeki line, emplc ed on the Teri1o1ci4Coivisto line. The greater portion of these The 43.567 kg/m rail and point ere illustrated in Figure 220 as States. cones for the rails weighing 33.48 1cB/m were obtained from the United isb 1 es the war and some of the base plate.i/~ Ella &&nd other aooes the Hiitola-Raaeuli lines. Procurement of rails wee difficult during II 1$ It Koivisto line and the second in 1916 on the Jyvaskyla-Piekeamaki and Both are Russian types; the first was adopted in 1915 on the Terijoki- rails which weigh 43.567 kilograms and 33.48 kilograms per meter. Railroads since the time of the first 50-year report; these are the RAILS AND RAIL ACCESSORIES Two new types of r~-ils have been adopted on the Finnish State - Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 2g-CONFIDENTIAL  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL replace the six-hole typo owing to the cost element and the debatable eftioienoy p of the end bolts The new fishplate is illustrated in p 308 Figure 221. This type was standard until 1935 when the straight fish- plate 'used with the wedge-shaped bearing plate was introduaed The otandard length of the 43.567 kg/m rail was originally 12 meters, but was inoreased in 1933 to 18 meters. Longitudinal move- ment of the shorter rails was prevented only by the edges of the fish- plates bent downwardm age inet the bearing plates, "traveling" of the longer rails oould not thus be prevented and rail slippage brakes were introduced (Figures 222 and 223) . Even these have not been fully satisfactory since th.y tend to k sink into the wooden ties and to loosen. The wedge-shaped bearing plates were therefore adopted in 1935, produoed in Belgium by the Ougree-Marihaye factory (Figure 224). During the short time they have been n in use they have proved fully satisfactory under all conditions, permitting the use of smaller joint spaoee and floc of longer raiis~C(30 to 40 meters). Another type of rail introduced from Russia, the 33.48 kg/m rail, is illustrated in Figure 225 with its bearing plate, t#k fishplate, p 309 bolts and spikes. This rail was not generally adopted and gk none have been procured since the completion of the Jyvesky-l~--Piekee~miki line was oompleted owing to the fact that the joint assembly is ex- pensive and the weight is too near that of the 30 kg/m rail, which continues to remain as the main type in use in the country. Only two changes have been made in the joint assembly of this reil.In 1916 (Figure 226)'4 the spacing of the holes of the fishplate were changed from the 150 x 150 x 150 millimeter pattern to 170 x 110 x 170 milli- meters, but this proved unsatisfactory. Consequently, a new broad base fishplate was adapted in 1924 (Figure 227) having the same spa- cing of holes as the 1916 fishplate, but much heavier. The resistive me moment of the 1924 fishplate is represented by its volume of 36.4 cubic centimeters as compared to the volume of 29.81 cubic centimeters -29- CONFiDENT9A I. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL . of the former type. The new sire of plate has proved eatiafaotor~. Other' changes in the aaoees oriea of the 30 kg/r rail include a larger bearing plate (Figure 227) and a.tnor ohangeo in tha bolts and p 310 spikes. Spikes now in use are illustrated in Figure 228. lsgtar, Eoonomio development hay lid to the we o!/iarg.r,and bsavisr trains and looaoaEivee which in turn demand hedviir rails. The lighter Finaieh rails weighing 22.343 kg/rn and 29 kg/rn uc ateadiiy giving way to the 30 kgJm rails and these to the 43.567 kg/rn rails. The of br~sok of each typo of rail r~ a~oat'ea the trend during the perioa i2s-1935 Steel Rails 22i 3 2 3 3? 4.6? Other Iron m m m m Typic Raile Total _ 1925 1,615 731 3,049 301 355 17 52 6,120 1930 1,371 727 3,929 362 547 14 33 6,983 1931 1,333 727 3,945 362 588 15 27 6,997 1932 1,273. 704 4,164 362 572 18 20 7,111 1933 1,267 735 4,214 361 621 16 20 7,234 1934 1,216 734 4,430 360 641 16 18 7,415 1935 1,187 733 4,509 359 674 16 18 7,496 Replacement of the 22,343 kg/m mile of the Vaaea line with 30 kg/m mile was completed in 1910. The light rails were still in use at that time on the Pori, 0alu, and Savo lines and the greater potion of the Karelia line. Replacement of ui&t the light roils with 30 kg/m rails was then already in progress on the Karelia a.ine and was con- tinued slowly even during World War I and reached as far as Joenauu by the end of 1932. Light rails of 25 kg/m are still in use on the Joensuu-Nurmes portion of the line. Replacement of the rails of the Oulu line with 30 kg/m rails was begun t in 1923 and has progressed as far as Oula. The rails north -30. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 iE  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 c0NcIDENTIAL of Oulu are 25 k,g/m, except for a portion of the Tornio-Keuliranta lire whiah haw mixed types, and the Ro~raieai-Kemijirvi line which has, as do many of the lines built after Nord War I, 30 kg/a rails. Replacement of rails on the Savo line was begun in 1923 and had reaohed the 494-kilometer port near P ,lJi at the en4 of 1935? The Iisulmi-Ylivieska, Kajaani-KiehiaL.Puukari, and the Oulu-Mhos lines p 311 are still equipped with 22 343 h / . g m rails which removed from older lines and installed on these lines. The 43.567 kg/m rail has been used since 1920 on Finnish rail- roads to replaoe lighter rails. Replacement of the Helsinki?Ra ja joki line was begun that year and is completed ac far as yiipuri with the exception of the other track of the line between Uusikylii and Koria which still has 33.45 kg/r rails. The Helsinki-Turku line has been in process of conversion to the 43.567 kg/m rails since 1927,2 the distanoe between Paeila and Taihtelii being completed by the end of 1935. Short sections beyond TAhte J have also been converted. Portions of the Riihim ki-Tampere line were converted from the 30 kg/m rails al- ready during or1d War I, and a systematic reconversion to 43.567 kg/m rails was begun in 1929. At the end of 1935 only 5 kilometers of the line remained f unconverted, the remainder to be completed during 1936? The specifications of 1935 for steel rails require a minimum ten- ails strength of 75 kilograms per square millimeter of arose-section with a distortion of 11 percent. The quality factor (tensile strength multiplied by distortion) must be at least 900. In the hardness test (in which a steel ball with a diameter of 19 millimeters is pressed with a force of 50 tons for one minute against the end of a rail) the depression must not exceed 4 millimeters. In the impact test the rail must be able to withstand the blow of a freely falling 1,000-ki1ogram as the bend in a rail reaches 100 millimeters. The blows are applied CONFIDENTiAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONHDENTIAL to a pieoe of rail 1.2 a.ters long resting ova supports a meter apaz'4. p 312 The height of fall of the first blow must be at least 3 meters and 1.5 meters in t!a suooeuive blows for the 43.567 kg/m rail and 1.2 meters for the 30 kg/a railm. A uew tut is that of the transverse beading of the foot of the nil (Figure 229) in which bending before failure must be at least 2.17 millimeters for the 30 kg/a rail between supports 85 millimetera apart under the foot, and at least 3.0 milli- metera for the 43.567 kg/m rail between supports 100 millimeters apart. The manufaoturer must furnish a complete ohemioa1 analysis of each but to the inspector of the State Railroads. At leant one im- pact and steel ball test must be made of .soh heat and any number of tensile strength and transverse testa that the inspector may require. The phosphor content of the steel need for fishplates and bear- ing piatee muet not exceed 0.06 peroent (same as for raffle) and the tensile etrength of the fishplatee must be at least 44 kjaq milli- meter and of the bearing platee it 42 to 52 icg/sq millimeter. The fiehplate must witbetand a bend of 90 degrees before failure, the bear degreec likewise. ng~ ing 60 p 313 SWITCHES AND CRCSS INCS The Model A curved tongue ewitch made from 30 kg/m rails was adopted by the Finnish State Railroads in 1912. In addition to the simple switches, both "half British" and "full British" as well as double tongue (duplex) switches have been made. To date only double type tongue double switches which are generally used in yards, as are the British types, have been produced. The crossing, or frog, is fastened either with rivets or with bolts and clamp plates to a long base (switch) plate, 12 millimetere thick. The flangeway between wing rail and point of frog has been Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFUi roillimetera to 50 millimeters ? Guard rails were increased from 49 d e former3.7 made from a section of rail 2.7 asters long, are now ma meters long sad 20 mi11i*eters thick and 40 from an angle iron 3 3 than the rail sad is attaohed to the rail by means millimeters higher of tillers and bolts. l switob is spproxiaately ?? meters long and The simple Model bas a radius of ouryature of 236 meters. The Model B switch was adopted in 1914. The design of these is the same as is of those used prior to 1912 but having the flangeways The crossing is hao the same design as the of the Model A switch. Model Abut is riveted to four frog plates. The guard rail is 3 me- standard rail. ?he slide plates were made taro long and is made of at first of oast iron, but since 1925 they have been made of oast to that has brought the cost of produotion nearly steel. This /actor of the Model A switch and production of Model B switches was there- Pore discontinued. Nor are new switches made any longer from the 25 since they do not withstand modern traffic 1 kg/m and 22.343 kg/m rails p34 and all are gradually being replaced by the Model A switch. The crossing angle of switches is 6 degrees. Since an angle of useful length of tracks in a large yard a oro$s- this size reduces the sing ration of 1:7, equivalent to an angle of $??' 1,g, was adopted in 1925 Various types of Model C switches have been made using this switoh employ's the tongue assemblY of the angle. The simple Model C 6-degree Model A. The crossing, homeverr, departs from the standard type in that one side iq curved since the ourve of the switoh passes throught the crossing. The radius of curvature of the switch is 185 meters and the total length is about 26 meters. During World War 1 when procurement of rails was difficult, rails wit es ? l ~ e ~n g Mo de~ Ia uss~a. uss and complete switches were obtained froa~ " rails and Model II1a 4kski* were imported in 1915 which bad orossing re- tics of lsll and 1t9? E nough of the Model lila rails and switches . CONPIOENTIAI Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFITIAL were imported to Baia furnish the traoka of the Jyvkk71~i-Piekdmbi lime mnd for use elsewhere. Production of simple, British, and doublet twin switohes of Model ?2 with crossing angles of 6 de- grees and 8?' P48" was begun at the Viipur~. aaohine shop in 1922 fran rails similar to the Russian Model Is weighing 43.567 kg/m which are imported annually from France and Belgium. They ore similar in struc- ture to those made from the 30 kg/is rails except that the tcngues are made longer (Figure 231), 6.14 meters in tho simple switch and 5.5 cetera in the British type. The guard rail is 4 meters long and is made Prom 20-millimeter angle iron which is 20 millimeters higher than the rails. The radius of ourvature of the simple awitoh is 231 meters and the total length of switoh is about 29 meters. Owing to the rapid wear of the wing rails and the switch points themselves, switohes are now being made with the point oast fm of manganese steel and manganese steel inserts are attached with bolts to those parts of the wing rail whioh support the wheels. Experi- ments in the hardening of wing rails and points by tempering have also been oonduoted, but results based on ix experience are still moon- elusive. Production of simple switches of the spring tongue construction from rails of 43.567 kg/m weight was begun in 1934. The tongue is longer than that of the standard type by half a length and is rigidly fastened at the base end to a long tie plate, the base being made narrower of near the point of attachment to permit the tongue to bend p 315 during switching, thus obviating the use of the common turnpin assem- bly (Figure 32 and 233) . The crossing angle is 304$' 52" (1,15) and the radius of switch curvature is 530 meters. The total length of the switch (Figure 232) is approximately 43 meters. The orouing is 9 meters long and of straight design and is attached by means of bolts and clamping plates to a frog plate 5 meters long. The point -34- F' .~ aN n ..-~ '~~ ~ Ui~ Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDEHT1 ~l is of manganese steel and the wing rails have manganese steel inserts. The guard rail,~t 6.3 meters 2on8, io mode from 20?millimeter angle stock. The large radius of ourvature and headier oonstruotion of these switches permit traiu to pies over them at 65 ki1ci.tern per hour, whioh is the maximum permissible speed of uon?stopping trains through one. Production costs of switches have varied oonsiderably with the p 316 cost. of ceteris/.. The following table gives an indioation of the installed oostsfaofkModel A and Model A2 switches in 1925' Made of 43.567 Made of 30 m rails k /m rails Simple switoh 26,000 17,500 Simple crossing switch "half British") 53,000 37,500 Double oroseing switch ( "full British) 70, 500 50, 500 Double twin switch 51,000 33,500 The production costs were considerably greater in 1934= cost of the spring tongue switoh was approximately 55,000 marks. Various types of switch stands are in use on the Finnish State Railroads. The type in which the weight is attached to the throwing lever is such manner that it may be shifted has been in use since 1911. The switch etend known as the Norwegian type is used in addi- tion to the oldest, the Bender stand, in stations handling a small amount of traffic. The switch stand .pmt illustrated in Figure 234 has been em- ployed since 1922, in which the connecting rod may be moved a distance of 250 millimeters and is therefore especially suitable for use with a switch looking device. A eliding bolt look plate may be attached to the base of the stand to which the safety look on the throwing lever is fastened, permitting 'der positive looking of the switch in the desired position. CONHDiTJL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDEUAL. SIQNMA AND 8APBTY DBVIa!8 Approved methods and signaling deviaes bars been employed for system. guiding railroad tz'af f is since the beginning of the State Railroad Signal regulations iuued in 1870, 1885, 1896, and 1903 have south approach of the Ssin~ijoki station. double-arm type and one with three arms made of eteel (boated at the and operated by a single control rod, but there were about ten of the been in force on the Finnish railroads at various times. The 1903 regulations with minor changes and additions, and although already somewhat antiquated, is still in force; a new set of regulations is ll 4"! F1 * in process of preparation. The signals and signaling devioes oovered in this discussion are of the type specified in the 1903 regulations as modified by laic directives of the Railroad Administration dated 18 February 1908 and with/double icrossing y May 1912. The :first directive was concerned switches (full British type) and the second specified that the arm of the semaphore must point upward at 45 degrees ("at 10 b' olock") , rather than downward as heretofore, to signal clear passage. The signal regulations of 1903 and imported safety systems provided a new basis for the development of signals and safety devicea. The de4e1? opment reached in the period to 1913 is indicated in the semaphores illustrated in Figures 235, 236, and 237. The semaphores (total of generally 60 in use) of that year were/of the one-arm type conetruoted of wood The prerequisite for the use of semaphores with several arms was l ohanisme m e con ro t the integration of a11/?k1I3c1t~ into a standard system, or other- wise stated, that the station must be equipped with a signaling and at that time. In all, four lever type interlocking machines with the crank type and the lever type (Figures 238 and 239) ,were in use switching safety system. Two mechanical types of interlocking machines, CONFIUEPv'r Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL oentraltsed ewitohing were in uae, two at Pasila and two at Viipuri. centralised In aU, six of the onnk type maohiuee for the/interlocking of awit- p 318 ohu wore in use, naael7 at Helsinki south, 9einIjoki south and north, Pita j ki, Xauniainen (Onnkulla) , and Espoo. The following turn- bridges were equipped with signaling and interlocking machines t three flea? Xuopio, the Xirkkoaaari bridge in Viipuri, the 8rkin1mi, Puflkasa1mi, Tuununsalmi, and the Xyr4nealmi bridges on the 9avonlinna- E1isenvaaro line, and the Joenauu, Vimaharju, and Liekag bridge' on the Joensuu-Nurrnes line. Eleotrioal blooking eyetems were put into use on 17 February 1913 between all station of the Helsinki-Eepoo line and station safety p 319 devices were installed at Helsinki and Pasila. These safety devioee prevent the routing of train head-on or in the same direotion on one block section. Eleotrioal blocking devices were ii!tailed between all of the stations near Viipuri in 1915. Only gates, either guarded or unguarded by a watohman, were gen- erally provided as safety features at highway crossings at that tide. Only 12 barriers of the boom type were in use, the largest aoroes the Linnakatu in Turku which formed a barrier 69 meters long over this street. A few eleotrioally operated bells for the warning of gate watchmen of approaching trains were in use. SEI IAPHORES Visible or Ontioal SiInle The use of semaphores of wood construction as principal semaphores increased considerably in the period 1914-1918 as the result of the great volume of through~traffio of the wartime years (see ourves of graph, Figure 240) . A portion of these became superfluous with the return of normal conditions and were removed. The number of wooden semaphores continued to decrease with the installation of safety ewit.. ohing and signaling equipment with steel semaphores at stations. The COPdffDEPd I i;al Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL wooden semaphores (Figure 241), o!' whioh there are approximately 30 still in use, wero similar to those of steel oonatruotio~a in that the semaphare arm is aotuated by a wheel at ground level, whioh in turn is aotuated by the semaphore orank and a pair of oabies. The greatest distanoo from which these semaphores oould be operated was only about 500 meters and a very simple suspension tightener without a support pole (or rod) was employed. The graph (Figure 240) depioting the employment of the various use of types of semaphores indicates that/the two-arm type has increased more rapidly than of the three-arm type sire 1930. This development re- preoents the adoption of a new system. The two-arm approach semaphore is now used when the service tracks all separate to the same side from the main track and the tree-arm type (Figure 242) is used only p 320 when the service tracks separate to both sides of the main track and in other speoial oases. The tree-arm approach semaphores are t?aigot replaced by the two-arm type whenever safety systems are being re- plaoed, especially when the ohange results in a simpler and more eoo- nomical installation. There are currently in use 145 of the one-arm type, 207 of the two-arm type, and 61 of the three-arm type steel sema- phores. The use of light signals as principal semaphores has increased considerably during recent years, eapecially in installations of eleo- trical interlocking and automatic blocking devices, to replace the arm type of /w*i~w(t.ii!a semaphore. A single two-light signal and a single three- light departure signal, whioh give light indications during night and day of tug signals corresponding to those of the two and three-arm types, xrmt installed in 1921 at Riihim ki, were the first of this type used in Finland. At the end of 1936 there were 40 light signals is use as principal semaphores (Figure 243) , of whioh about 20 were of the one-light type, i.e. which give the "go ahead? signal with one ?gkk green light only. Since the light signals currently in use -3g- CONfIDEPJTIAI Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFID!tT1AL ided with rear lights, it is generally neaeassry to indi- are not pray p gel sate their positions (aapeats) at the point of control. The same is now generally true for the seasphares when the semsphore is not visi? ble frog the point of control or the obser!ation point. I The rapid inoreaee in the speed off' trsine soon neoeasitated thn of distant signals s sutf ioient braking diatanoe from the main use or home signal, espeoially where the visibility of semsphores was aatisfaotory. The first distant signal was installed in 1904 and un was of the oil-burning diak type. The nnmber of distant signals in- oreseed rapidly in the installation of ewitohing and signaling eya- tems during world filar I, but the growth has been somewhat slower there- after (see curves of graph, Figure 240)? p 322 The first AGA distant signal izKk* of the disk type and equip- pad with a blinker light was put into use in 1912? When the effioienoy, safety, and visibility of the AOA signal beoame a demonstrated fact, it that all of the most important disk type aignals would was decided ins be eventually equipped with blinker lights`t (Figure 244) . Blinker lights were installed in 34 distant disk signals in 1917, and in 1934, when there were 193 distant signals, all were equipped with the blinkers. The maximum diatanoe from which a matte signal may be operated echanically', i.e., by oables, is 1,200 meters. The speeds of trains m that the distant signal be boated at least 700 meters require, however, and up to 1,200 meters beyond the home signal, which in itself may be ble diatanoe from the interlooking plant. The prob- located a cane idera lem was solved completely by the AGA-designed light 1di!J!U1J'ns and mechanical methods of operation are now ~mc used only in semi- controls e 3-volt oirouit which operates the distant signal light at electrical ewitoh attached to the arm of the semaphore Whores . An the required distance to give the light signals (without rear lights) of all signals (aspects) approved for the distant signals during -39- Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA RDP82 000398000100090087 7 +ssiww~a~s~~w~~~sa~s?sw~~wsw~++ecwne ~.mT.+ wean w~ awe. ~~~e CONHDEUTIAL was installed 15 April 1924 on the north approach Of the Ou1un,yli both daytime and darkness. The first distant signal of this tpe station. This one was replaced b' a newer type in 1932. Since these distant signal lights have also been proved eoonomioal and positive in action (Figure 245) wider application is being made of them. A visibility of the light during daytime woo adopted in 1936. A total of 86 distant signal lights are ourrently in use. e Yard track signals equipped with the AGA?type of light have been employed in Finland, but their number has steadily deoreased since 1913, being replaced in mans instances by semaphores. None remained model in which the disk ii inclined forward (Figure 246) to improve in use after 1937. * p 223 The installation of large switching plants brought the need for signals to indicate when trains are not permitted to switoh. The disk type signal (Figure 247) , a few equipped with the AOA blinker, where used for this purpose, but these have proved somewhat uneatis- factory owing the oonfueion created by additional red light signals. A new "no-switching" signal has therefore been approved, but 65 of the disk type, 12 of which are equipped with AGA blinkere, are still in use. p 324 The tea ' new, improved mechanically operated "no-switching" signals were first installed in 1929 (Figurer 248) at the Kouvola yards. These consist of a mast 10-12 meters high with a rectangular cross-arm painted white which is illuminated by white light during darkness. !hen the arm is in the normal or vertical position traffic and switch- ing movements are permitted; the horizontal position prohibits move- ments which may endanger arriving or departing trains. Only ten of there signals (semaphores) designed and constructed in Finland and which have proved efficient are tzcq currently in use. CONFIDEtTiL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087 -7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONHDNTIA~ A light sigma, his been designed for this purpose also. The "no-switching" indication is gives with three sisber oolored light points in horizontal line; the clear indioatiou is given with the lights in vertical line. Conditions p.riaitting at the bump. of the in whioh the lights olassifioation yards at Pasila and Viipuri,light signal. are extinguished when in the olear position, have been installed for this purpose. Track signals are intended to replace the disk type signal in locations where trains are not to prooeed beyond the signal when to displaying the halt aspect. These are of two types the track signal lamp (Figure 249) a* xtksxt cstpiketIgktzIfguizU1) which is operated meohanioally, and the track signal light (Figure 250) whioh is similar in design to the conventional signal. These signals arde p 325 are used at large to speed traffic. A third type of light signal is required o~n separated tracks to give the proceed oautioualy indication by means of two oolorlese lights inclined at 45 degrees above the horizontal toward the left (at "10 0' olook") . The first track signal lamp was put into service in 1930 at the Hovinmaa station and the first track signal light the same year at the Viipuri station. Only two of the first type and 14 of the seoor-d are ourrently in use. A classification signal device of the semaphore type was adopted at in 1916/i the hump of the Viipuri yard, the first Finnish railroad yard to employ the hump method of olassifioation. This semaphore enables the olaesifier to give such indications as "halt", "push slowly", and "push fast" to the engineer. p 326 When the olaeeifioation hump of the Pasila yard was completed in 1927, a signal light (Figure 251) was designed for this purpose. The .41. COR14TIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFiEJNTIAL signal proved so effective that whoa e a a p r~rllel alarsifioation hump was built at P.eila in 1929, a similar si Baal tray inutalled oa the aew traokr, aM the old olassifioati ova semaphore at the Yiipuri yard was replaoed with this typo in 1930. * Because of the difficulty of dispatohi and traus3'erriAg of of laoamotiver where visibility is limited C curves in outs, adverse wea- ther) by Dual and whistle signals, , unfficial use of light signals hI$Xb*U.g. for this purpose was made at a nuanbor of /coal stations such as Kir jokivi and Rilloeensalmi whioh we re later removed The first offioial engine dirpatchi and t ~ raneferring sigma (Figure 252) was installed a eriment ~P ally in 1931 rutYicssncuclt~ at the Kouvola station where the Savo line de , parts on a curve ? This rig. na1 has three lamp., the uppermost green ih co for and the two lower lamp. Colorless , mounted on a equate backboard p 327 Breen signal light. were used unoffi oially as wayAide station eig- nale on several liner including the KarJaa-Turku lin e as far bank as 1907, but these were removed in 1921 to avoid o0 nfusion with the green distant signals, The need for official w 4Yside at n atio .ignals increased with the increase in the number of unattended stati one and an experi? mental model was installed in 1932 (Figure 253 at th ~ e Yli-Vekkoski p 32g atop of the Porvoo line. Thta< eema phorn re ~ generaljyr stated b ap y the passengers themselves at unattended stations ands also ue ed at other stations by regular personnel. * The old type Bender lamp (Figures 255 and 256 and ~ the lamp ap- proved by the State Railroads (Figures 257 and 25S) we re both employed as switch signals in simple switches before the enl ~ ng of the period under discussion. Both are still in use. Sw itch signal lamps currently installed are similar to a Germaan trpe manufact 3 used to .42. C0 FI V'1' Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDEt4T1a~ ?innish spsoifiostiou adopted in 1922. These .igaala may also be eaployed at water columns, turntable., and track blocks without ohanging the signal indication. A semaphore type or switoh signal in has also been employed since 1926/, yards whore the erberior illu- mination permits their use. The windmill type of lamp has been used since 1923 (Figure 259) U the switch signal in double switohes in which the points are parallel, t o replaoe the old four-lampype . Apprroxiaately 160 of these switohes are ourrently in uae j they haive been produced to Finnish apeoifioations at the Viipuri aohine shop ainoe 1934. Another type specified in the signal regulations of 1903 for orossing switches in which the four pairs of points are controlled simultaneoualy at one throw~'are also in use. p 330 The track block signal (Figure 254) lamp is in uses the regular closed track signal was approved in 1933 for this purpose at unattended stations. The signals on water columns are still as specified in the regula- tions of 1903. These give a red light indication when the spout is extended over the track and a colorless light when the spout is pare- 11e1 to the track. The regulations of 1903 make no mention of signals for track scales and various types of semaphores which are part of the scale itself are in use. The arm of the semaphore is at right angles to the track when the scale is in position for weighing, and parallel to the track at other times. The new regulations will specify a V-shaped indication (V is for "vaaka", a scale). Various types of indications have been used for railroad turn -43- COidfIcNi'iul Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 ONFIDEN1IAL bridge. specified in each inetanoe by the ..note is earlier time. sad later by the Cabiut. These varied with local conditions end with the nature of the bridge.. The Railroad Administration and the Kighwsy and waterways Construction Adaainistration aonterred in 1931 to draw up regulatiou for standardised indioations, which here been and on all new installations since that time. * Signals for turntables were not mentioned in the regulations of 1903. A light signal which giver a red indication in the orosewise position to bar entry of engine upon table and a white light indioa- tion when in position parallel to track to permit entry of engine has been employed. * A number of fixed signals are in use. The following types have been officially approvedt 1. The halt sign (Figure 260) is used where the approach track ends, beyond which point trains may not proceed; 11 are in use. 2. The speed signal (Figure 261) indicates the maximum speed for a section of track; U are in use, all on bridges. p 331 3. The whistle sign (Figure 262) is used to indicate when the engineer must give a whistle warning at grade crossings to highway traffic! 4. The obstruction sign ( "penalty pole") is a poet of steel or wood construction used to indicate the point beyond which rolling stock may not proceed in order its not to obetraot movement on ad~oin- iag tracks. * p 332 Portable aidoaidc circular semaphores are used in track maintenance operations. These have a green disk for the caution indication and a red disk for the halt indication. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDEIITIAL Manuil signals as epeoitied in tha regulations of 1903 ere rtiT in use with several amendments. The msnasi signal far sirbreke test- ing war amended in 1918; the method of indioating the signal for pass- ?z11 at dispetohing stations was speoified in 1925; and the method for signaling is switohing operstions was modified in 1936. N Identification signs on rolling stook have likewise remained practioally unohanged during the past 25 ,ears. Signs used to indi- oate the passage of special trains are now considered superfluous and have been eliminated. The Railroad Administration approved front end signs for motorised coaches (Figure 372, page 455) in 1931. The original form of illumination for fixed signs was the oil lamp which has a number of shortcomings. Introduction of the acety- lene lamp which poodbaa * generates the gas from carbide therefore re- presented a considerable advancement; these lamps are produoed in the p 333 viipuri machine shop. The electric lamp is even more efficient and its use has increased greatly in fixed signals. Practically all light-type hone signals are eleotrioally lighted. At the end of 1936 electric lighting was employed in 166 fixed signs, 31 switches, 6 turn bridges, 20 highway crossing gates, and 10 highway crossing warning lamps. Use of electric hand lamps has not increased materially. Employment of sound and acoustic signals such as whistles, steam whistles, warning bells, and explosive warnings is still governed chief- ly by the regulations of 1903. SAFL'cY RQUIP1V~NT The control look ( or safety lock) is the simplest and most -45- Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTiAL oo monl7 used sat,ty device in the amallest atstiona. This look is so designed that the kwy mq be reaoved only when the device is pro- perly looked. They were, however, adopted only quite recently. 8ig? aali*g mnd switching safety devioes were 1ener3117 inatsiled at the largoat atatione, vhioh off' Qoorse s,re attended by personnel. The p 334 unattended line switoh points received lean attention. Since the safety of trains is largely dependent, however, on the positive looking of switohea the Railroad Administration issued a speoial directive in 1922 regarding traffic at line switohea and the use of ufety and oon- trot looks at those points. Severs] main line switahes have subsequently been provided with switch point looks which securely look the fixed point to the support rail. Coasting of rolling atook from side tracks to the main track or beyond the esfety point is prevented at the most important places by oar stops, which are also provided with safety looks. In addition, eleotrioal apparatus to verity the operation of safety locks remotely in the dispatcher' e office has been installed at several stations. Safety looks are also employed in switch safety devices and in semaphores. Approximately 500 safety looks were in use at the end of 1936, of which 313 were in main track switches (181 switch point looks and 132 installed in switch stanch). * Regular switching and semaphore installations are so designed that the switches and semaphores are dependent upon one another in their operation. This is accomplished by means of the safety look whioh secures the fixed point of the switch to the support rail. Un- lees this looking is positive none of the other safety devices of the track will operate to give the clear track indication. The moat common t e of switch look in use in Finland is the toggle (or "knuckle") type (Figure 263) and only a small number of the hook type (Figure 264) are in use. The wedge type (Figure 265) recently developed -46- CONfiDENTIAI Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIEt!T!A abroad hse been suooessfu11y tested in ?inland end the Railroad Administration laic therefore obtained manutaoturing rights in 1935 from the V p1 firm for this type of switoh. Domestio production should begin shortly. * The first meohanioal awitohing plants were installed in 1903 St HyvinlcMa and Paaila. The centralization of switohee at Viipuri begun early in the period under diaousaion progressed to the point that two manually operated adds k interlooking plants (Noe I and II) oould be put into operation at the beginning of 1915. T Roth of these were of the Max Jikel type. A total of 6 manually operated interlocking plants were in operation in Finland at that time, 4 at Viipuri and 2 in Paaila, the Nyvinka t installation having been dis- mantled. They contained a total of 116 ewitchee controlled from centralized plants. Installation of mechanical interlocking plants ceased for the time, however, owing to icctttttldq~xoT procurement diffioultiea during world war I of special aooeseoriee manufactured in Germany. The two additional manual interlocking plants ordered for the Viipuri yard thus were not installed. The adverse eoonomio conditions fol- lowing the war did not favor the centralizing of ewitohgear. The p 336 number of such inatallationa has continued to increase slowly, however, in the expansion of yards and where aafety devices have been installed. The meohanioal interlooking plant at Paaila was replaced in 1926 and installed at the east end of the Kar~aa yard to centralize the control of 16 switohea (Figure 283) and the mechanical interlocking plant at Viipuri was replaced in 1936 and installed at Lahti (Figures 267 and 268) to centralize the oontrola of 29 switches. The centralized ewit- ching planta installed at the Oulunkyls yard at Villhd+ in 1923 (Figure 269) and that installed at the north end of the Paaila yard in 1926 may alao be mentioned here. At the end of 1936 there were -47ii. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDEN TM t 219 switches oontrolled frc oeotraliad plants. g1eotr1Qa1 intor- looking plants to control s total of approximately 80 switches are being installed st RiihimIki end Tampere. p 337 i meohanioal type of approach switoh looking deeigned to pre- vest switching while a train was paaaing over the switch frequently employed wero the switch is not visible from the point of control was formerly used/t*c in oon~unotion with centralised switohing plants. Owing to their high ooet of maintenance and uncertain operation, all of these have been replaced with electric types (Figure 270) which olose the look when a pair of wheels enters an insulated section of track in frost of the look. p 338 The progress in centralised looking of swito1,es has been far more rapid in Finland than in the centralisation of switching meoha- niame since looking devices are more economical to inetell, especially at smalher stations, and because they operate with lee. attention under winter conditions. The lever type of mechanism has been employ- ed moat extensive in Finland at places where a greater number of ewLtchea and semaphores are concentrated and the switch stand type (Figures 266 and 271) is employed where only one or two controls are required. The mechanical interlocking plant with centralised looking gen- erally funotionn in the following manners ~fhen the device is in the basic position with the approach semaphores in the halt aspect all switches are unlocked and may be switched, which condition is usually indicated k xt)OCpLItk4k at the interlocking plant by the *m* crank position indicators (Figure 238, p 318). The internal design of the crank type interlocking machines (Figure 269) is generally such that only one track may be switched at a time, unless the tracks are independent of one another or are protected by safety look switches. -48. CONFIflETi4L Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CUNFIOENTIAL The route is prepared by the train dispataher or his assistant by setting the looking crank. indioated on tb. panels into the prescribed positions (either to right or left) and beaome looked when the appro- priate route lever is set in the position required for the direction of the route. The route lever in turn looks when the oruk of the home signal is turued, having beoomo unlooked by the previous steps. The looking devices of the route cannot then be op.Ld until the bome signal is returned to the halt aspeot. p 339 The oentralized looking of a switch is accomplished with the a looking bolt into an opening on appropriate crank b the orank oable whioh turns /s semioirby oulir oem on the looking wheel (Figure 272) located at the switoh, simultaneously aotuating the tongue of the ewitoh. As many as two or three switches may be oontrolled by a single cable depending on loom conditions. Sinoe the ara~#ktigoc*t operation of meohanioel safety devices is dependent upon the use with which the meohanioal elements controlled by the cables turn on their shafts, approximately 6,500 ball bearings and roller bearings have been installed in these devices. Only 13 stations were equipped with looking devices at the be- ginning of 1915? An appropriation of 1,119,200 marks granted by the Senate in 1915 to equip all of the stations of the Valkeasaari- Riihimeki-Tampere line with looking devices gave an impetus to this development, although progress was slow in the postwar period. The most important of the centralized looking installations in switching and signal interlocking plants built in recent years are those at Kouvola, Kuopio, and Malmi which have, in addition, route diagrams (Figures 273, 274, and 276) in the dispatbher'e office to indicate the operation of the s switching mechanisms. Installation of an electrical interlooking plant, the first of in Finland its kind/and designed ix by the Railroad Administration, was completed at the Kauniainen station in 1936. The approach signals, including -44- CONFIDEIITIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL emergency starting device to provide/power during power network failure. In 1936 there were 135 stations with safety switching and sig- naling installation equipped with looking systems with a total of 928 ewitahee with centralized looking facilities; 87 crank-operated ewitohing mechanisms and 209 switch etande of the same type were in use, 70 of which were not equipped looking devioea. the distant signals, and the eleotrioal looking devices on the route (Figure 277) are all oontrolled by setting two buttoms in the dispat- ohwrIs offico. The eleotrioal looking devices, which operate on 24 volts direct ourrent, look the ewituhee when they beoome de~atgised. Pilot switches indicate the position of the switch points ; the pilot switches are controlled by the point indicator devices in the looking system. The dispatcher determines from the mote diagram (Figure 276) when the switches at the individual looations have been turned for the required route and then turns the appropriate rwitoh knob for the deoired direction of travel This action looks all of the switches concerned and when the switch knob it rotated to the final position turns to the the approach signal of the route/gun the proceed aspect. When/first wheels of the approaching train pars over an electrical contact in the track the approach signal turn. to the halt aspect. The electric looking installation is equipped with a rectifier, a set of storage batteries, and a motor-generator unit with automatic e The first electrical switching machine in Finland was put into . Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 operation in the dispatcher's office at Pasila in 19261 (Figure 279). The switching machine, the automatic blocking aobaci?k system of the Helsinki?Parila line, and the Paula yard blocking system looa- ted at the top of the, control installation, are all integrated elec- trically. The dispatcher clears, or gives the permission to prepare block sections of the mechanical swit- weetern approaches by means of the  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CON;IDENTIAI station blocking oontrol. The switching maob-ine proper, which was built by the L. M. triossani Lb, has plaasc for 12 switch oontrols. enable Sheoe controls/the dispatoher ti ? to set the following oomponents which are equipped with aaotorised throwing eoha- nisms s 2 single-arm approaah semaphores, one doubls?arm approach somaAhare, 3 single arm departure semaphores (Figure 280) , 2 switches, and actuates the safety looks of 3 switohes and one !?k oar stop. of the 7 routes on the switching machine, 4 are completely equipped with automatic route looking devioes whioh open when the last pair or wheels of the train pass over u insulated eleotrioal oontaot p 342 (Figure 281) in the traoks. The throwing mechanisms of the semaphorea are powered by an electric motor with a rating of 0.25 Kw and the neoessary gear drives and friction ooupling, one each for each at arm p 343 of the semaphores, and is provided with ooatrol and indicator replaced in 1936 by metallic types. The motors operate on 127 volts, direct current, and the indicator devices on 36 volts, direct current. The lamps whioh illuminate semaphores and switches also operate on current of 127 volta, and may thus be supplied during emergencies e with power from the batteries which normally furnish current for operating the motors. Additional indicators were installed in 1932 to enable the switches. The switch throwing mechanisms are powered by Q electric motors rated at 0.5 KW (Figure 282) with gear and worm drives and friction couplings and control and indicator switches. The switch mates are equipped with devices known as switch point adjusters which indicator prevent the eleotrio/~ma k contacts from closing unless the points of the db~c switch are fully in the correct position. Alternating current from the regular power source of the station is passed throng two mercury vapor rectifiers to supply the operating per and to 22 ampere hour maintain the charge in the/nickel-iron storage battery which is used as a source of emergency power. The mercury vapor rectifiers were ?51- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONfIDENJg4I dispatoher to observe the movements of trains on the block sections between Helsinki and Pasila and the operation of the Alppils block signals. Explanation of symbols, Figure 278, p 342 Figure 278. Distribution of Switching and Signaling Safety Equip- ment in the Finnish Railroad Network, 1937 1. Station equipped with safety switching and signaling ins? tallation. Continuous black line indicates suoh installations exist at all stations of line. 2. Station equipped with home signals which are independent of switch looks ( one, or number indicated by numeral) . 3. Turntable with home signal. 4. Bridge which has a single passage common to railroad track.. and highway and is equipped with home signals. The second oldest electric switching machine in Finland is the p 344 one installed in 1930 to replace the mechanical switching machine at the western end of the Viipuri yards near the Eirkkoaaari turntable in a three-etory building with central heating (Figure 285) and which affords an excellent view of the area controlled. This machine (Figure 287) controls 17 regular routes and 11 alternate routes, sets 31 awit- hose ohes, 9 *gr~kz; light signals, and 5 track light signals, and gives the "permit" signals to 6 routes and also looks the Kirkkoaaari turntable (or turnbridge?). Illustrations, page 345: Figure 284. The eleotrio station blooking machine in the office of the Viipuri train dispatcher. The handles of the switches by means of which mechanical dependence between blocking sections is attained to reduce their number rack may be aeon in the lower part of the photo- graph. Figure 285. Building which houses the interlocking plant at Viipuri. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL p 3"6 p 347 Oulunkarla lines were completed in 1927 and 1928. The n4ntg The line blocking eystema of the Paeila-Huopalahti and the Paaila- Figure 286. Poeeilant of the eleotrio interlooking machine at Viipuri. Figure 267. Tho eleotrio int~erlooking plont at Viipuri. e Elootriaal blocking oontrolr by mean of which the track reotionr and their switoh gear arc made depondent upon one another, either lac manually or automatically, are among the moot essential of the various types of safety equipment. The oontrols manulaotured in Finland are generally bared on the same system as those of Germany and Sweden. Manual blocking controls (Figures 288 and 284) have been em- ployed in Finland ainoe 1913 for etation blooking and for line blook- ing The controls are employed in the following manners the crank of a mapeto is turned 6 or 8 revolutions while depressing the appropriate blooking control button to effeot integration between blooking seotiona, either meohanioaily or ii by electrical means, for looking, clearing, and transmitting signals. The first station and line blocking systems in Finland were put into use in 1913 on;the Helsinki-Eepoo line. The line blocking eyetem was later removed from that eeotion of the line between Paula and Eepoo which waa converted into a double track line. The four interlocking plants of the Viipuri yards and the etatione nearby at Tienhaara, Seinio, and Tammisuo, as well ae the line switches at Hiekka and Teuraetamo were equipped with blocking controls in 1915? Traffic between Viipuri and Tienhaara had inoreaeed in volume by 1916 that the inatallation of an intermediate blocking station at Linnaneeari became neceueary, which however, was removed to the new wayeide etation at Sorvali in 1920 (Figurer 288 and 289). A manually operated intermediate blocking station wee installed in 1923 at Aippila on the double track blocking line between Helsinki and Paella. CONfIDENTiAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIDENTIM. inter1ooking plants (Kwubera II, III, and IV) or the Kouvols yards both or were integrated with station blooking system in 1929, as were those at Joensuu, which are situated at either end or the tarn bridge. when the Kyr8nailmi bridge was adapted in 1934 to aooommodate highway integrated trarrio also,/blooking sy.tens were inatailed in the oontro1 booths at either end to control railway, highway, and waterway trarrio. A total or 93 station blocking sections and 41 line blocking section were in operation in Finland it the end or 1936. The manually operated Alppile intermediate blocking station built in 1923 was removed in 1925 in the ocuree or the ohsnges which automatio were made in the yards. The first Finnish/intermediate blocking sta- tion was inetelled on the new passenger train tracks parallel to the original tracks and was put into servioe immediately after removal or the manual eyetem. Since the distance of 3.1 kilometers which as. parate? Helsinki and Pasila includes approximately 1.3 kilometera or the Helsinki yard and a seotion or about 1.4 kilometers having an upgrade or 0.010, it woe necessary to locate the intermediate blocking station in such manner that three trains traveling in each direction simultaneously between Helsinki and Paula oould be aooommodated with a minimum time interval separation or five minutes. The block signal lights (Figure 290) of both tracks of the intermediate blocking sta- tion were placed side by side in such manner that they divide the line leading from Helsinki to Pasila (exclusive of the portions within the Helsinki and Pasila yards) into blocking sections or 725 meters and 775 meters and the line leading from Pasila to Helsinki into block sections of 730 meters and 600 meters. p 349 The automaatio operation of the blocking system is based upon use or the isolated track section. This is accomplished by joining electrically all or the rails of a aeotion of z the track to form a pair of conductors, the ends of which are insulated from adjoining seotiona by means of special rail conneotore. A source of electric .,54. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFlDEJ4j. current is aonneeted to one end of .oh vuoh aeotion and a sensitive relay is aonneoted to the other end. The points of the rile, make the proper contact st the moment the energising current is out orf from the solenoid of the relay by the short circuit produced by the first pair of t* axles of the train ao it enterr the section of traok. 11~c wooden fishplates of oak were originally employed to in- sulate the track sections from one another, but currently only fiber insu1sting pieoes are used to separate standard ut cck tx**z fittings and rails. Sinai ties are mode of wood, inaulation of the rails them- vclves is not necessary. Two steel wiree tightly wedged to the ndc webs of the rails were used to obtain eleotriosl continuity between mile on the track sections between Helsinki and Pasila, but only oopper oonduotors are ourrently employed whioh are attached to the rails by oxy-aoetylene welding. ? Edison storage batteries with a ra- ting of 500 ampere-hours,** housed separately nt*mct in raoke out- doors, supply the ourrent to the traoka. The operating drain of the track relaye is 0.1 ampere and the reeietanoe is 4 ohme. The inter- mediate blocking signals use 12-volt, 40-watt signal lamps which have been produced in Finland since 1930. The required transformers are located in the cast iron boxes of the signals. The system hae been in continuoua operation resulting in ooneiderable economy annually in operating cost. The automatic line blooking eystem put into use on the Viipuri- Liimatta line in 1928 is pimilar in techn oLl respeote to the system described above. The intermediate blocking station situated on the Susisaari bridge divides the double-track line of 3.5 kilometers be- tween Viipuri and Liimatta into two blocking sections of which the Viipuri section is 1,600 meters long and the Liimatta section 1,900 meters long. The blocking system of the Liimatta portion is of a tem- porary nature and is completely independent of the departure s.gnale. Blocking section indicator lights have been installed, however, in the .55. CONFiDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  CONFIDENTiAL atfioe of the Liimotta train dispatcher. * p 357 DEVELOPMENT SIGNAL EQOINT AND TRAFFIC SAFETY DEVICES Installation Operations A new phase iA inatallation operation. was reached during the period under disauasion. The switohing and signaling safety gear used in Finland prior to 1916 was manufaotured to foreign design, principally to the deaigns developed by the Max J~del and the S8dertelge Verkatiider firms, and were installRd under supervision of their tech- nioiane, sinoe the State Railroads did not have the neceesary trained pereonnel. A training program for domeatio installation personnel p 358 was undertaken as a result of the large order for equipment placed in 1915 and the installation of this gear begun after the war. Two track superintendents who had worked under direction of the foreign instal- , lation experts were aeleoted in 1920 for an educational tour in Sweden where they had an opportunity to learn the meohanioal aspects of ine- tallation operations while working as signalmen. A telegraph teohni- cian who had worked on the installation of electrical safety gear was similarly dispatched in 1924 to learn intallation procedure in Sweden and Germany. A supply of capable installation personnel lea v has gradually been developed under the direction of the nucleus trained abroad as far as this has been possible within the available funds and extent of operations. The Safety Equipment Division proposed in 1921 that the system of installation and maintenance of safety equipment then in use be reorganised. In line with the proposal the Railroad Administration appointed a committee in 1929 which drew up the "Regulations for Sig- nal Officials" which was adopted in 1931. The committee reoommended, among other things, that the installation and maintenance functions be delegated to specially trained officials to be known as signal eu- perintendente and signal installation men. The various railroad lines -56- CONFiDENTIpI. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL were to be independent of one another as far as possible in regard to these funotions and personnel. The responsibility for the main- tenance of e1eotrioa1 gear was to be transferred from the telegraph oagineer, who is under the supervision of the geuhsniosl Divisioa, to the Track Equipment Division. This ~cigit reoommendation was adopted by the Railroad Administration in 1931, in regard to the meohanical phueo only, aino~ even the committee did not nonsider the eleotrioal phase urgent at that time (the t~aoataai*t capital investment ratio of electrical to mechanical equipment was 1t10 at that time). The qua- lificationa of the technical personnel were also specified. The committee also recommended the procurement of 1; signal superintendents and 19 signal installers for the maintenance and inspection of the meohanioai signal equipment on existing lines; two working crews, each headed by a signal superintendent were to be recruited for work on lines under construction. A total of 25 signal officials was there- fore to be employed. Owing to the lack of qualified appiioents only a third of the reoommended procurement program has been achieved to date. For the time being the railroad network 1uc is divided into three signal super- intendent districts in respect to maintenance of mechanical signal equipment. Each of the districts are in turn divided sections super- vised by the installers, although only five installers have thus far been appointed from those considered most capable to take the lead in training additional personnel. Five railroad watohmen are currently in training as apprentice signal installers. One installation crew railroad is available for work on new lines under direction of a/adpzt super- intendent. This work section is currently stationed at the Riihim~ki repair shop. The railroad network is temporarily divided into two districts for the installation and maintenance of electrical safety equipment. Each district is supervised by a telegraph engineer who has had -y7- co~FOOFNriAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL Aoctal training for thie work. Three workir g parties are maintained e to do the o1ectrioa1 work, all of which are under the administration of the te1egvaph instrument workshop at Riihimiki. gaoh working per- tY has, in addition to the aeoesenry tools and instruments, a rail? road or for use as a workshop and mobile living quarters . The track p 359 maintenance division haw at its disposal a total of 9 oars, of whioh only three t~oc are combination workshop and living quarters care otter- in overnight faoilitie$ for only two signal superintendents and four skilled workers. The ~gmdt~t eleotrioal signal working per- ties of the telegraph instrument repair ehop have three mobile shops for their use. The signal superintendents and installers are eubordinate to i ans technic the chiefs of each railroad line and the telegraph/* $tZUXt and installers who work on electric signaling devices are subordinate to the telegraph engineer, but follow the technical directives of the safety equipment division in their work on signal devioeo. A necessary prerequisite to the systematic construction and maintenance of safety equipment is a body of trained personnel. Since neither the Technical Institute, the trade schools, nor the industrial schools of Finland have not yet undertaken the training of signal technicians, and since no private enterpriaea in Finland are engaged in this work, the responsibility for the training of personnel there- fore falls upon the railroads themselves by the organisation of epeoialized courses according to a program soon to be approved. * P. 460 Table 1. Number of Passenger Cars at the End of 1912, 1919, 1927, 1932, and 1935. 2f (r3 Co &e a b T9Y a b a b e b r$95) 7 1 15 -- g 5 8 5 8 6 Official oars A let class day coaches B 24 3 18 ?" ?- ?- -- -- ?? s a Number of 2- and 3-axle oars; (b) Number of 4-axle oar CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 N -2L ji_m _Lt 19L 21L Typ,g C e (a) (b) (Lt) (b) (a) (b) (a) (b) (~) (b) lit and 24 olaee eleepere Cie ?- 37 ?- 47 -- 43 -w 33 -- 48 let and 2d aloes day aoachea C 29 ?- 59 -? ?- ^- ^? -w ..w 1st and 24 alaaa day ooaahee Ci ?- 23 ?~ -? -- 16 -- 20 -- 20 2d aloes day ooaohoa D 171 ?- 163 ?- 103 -- 136 116 -? 24 olaea day ooaahee Di ?- -- -- .. 29 -- 33 -- -- let, 2d, 3d olaee eleopere (Em -- 12 -- 7 -- 23 -- 35 -- 38 2d and 3d olaei day- ooaohea DE 49 -- 58 -. 36 -- 34 .. 40 -- 2d and 3d olaes day ooaohes DEi -- 6 -- -? -- 43, -- 81 -- 89 3d alais day ooaohoa E 419 -- 487 -- 317 ?- 340 -- 329 .. 3d olase sleepers Em -- 9 -- 11 -. 21 -- 26 .- .. 3d class day ooaoheo Ei -- 43 -- -- 108 -- 145 -- 155 3d class and trainmen's oars EF 14 ?. 13 -- 8 -- 8 -- 6 -- 3d class and mail oars DP -~ .,.. .- -- -- -- -- 1 ^^ 3d olaae and mail oars EP 13 -- 15 -- 5 .. 5 -- I. Hospital oars Ee -- -- -- -- 1 -- 1 -- 1 -- Workmen ' a okra T -- -- 27 -- 28 49 20 33 19 10 Conduotor'a (trainmen's) oars F 244 -- 292 -- 359 -- 392 -- 389 -- Conduotor'a (trainmen's) oars Fo -- -- -- -- -- 5 -- 30 -- 30 Prison cars Prison oars Total Totals by Years Temporary dwelling oars Auxiliary engine oars Dwelling and repair cars CONFIDENTIAL 24 -- 994 ],36 __1--174-- -65 893 342 970 466 939 460 Telegraph instrument repair shop dwelling oars Total miscellaneous types 27 1, 239 1,__5_ 3 1,46 1,399 26 9 26 -- 26 3 3 3 1 3__ _-- 11 -- 17 3 U.- -59- COtffIOEN TM L 12 17 -- 22 7 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIDENTI%1. p 461 Table 2. Number nt Froight Care at the gad of 1912, 1919, 1927, 1932, and 193 (a) Number of 2-ax1e and 3-i x1e ors; (b) Number off' 4-ax1e oars 1912 1919 1927 1932 195 Tvoe Codg ?a Y (bj a ) b (a) (Y r b a b a b) 2L Ili Old style oars 0 - 7,14#- 300 - 262 - 239 - Old style osrs as 5,272 - - - 2,842 - 2,691 - 2,766 - Norse "Pullmana" Gow 1 - 1 - - - - - ? - New style oars Gb - - - - 815 - 1,900 - 2,290 - New style care ror truneit freight Gd - ? - - 2,915 - 2,916 - 2,913 - Old style ogre for truneit freight Gay - - - - 437 - 382 - 322 - Traneit atylA oars Gkk - - - - - 2 . 2 . 2 Through-Freight card Of 4 - 4 - 4 - - - - . Larger oapaoity ogre Gdk - - - - 214 - 137 - - - Baggage oars Ge 66 - 91 - 73 - 72 78 - Heated and refrigerated oars Gg 213 - 210 - 312 - 459 - 422 - Yeaat transporting oars Ggkk - - - - - 1 - 1 - 1 Mortuary care Gi 5- 5.' 3- 4- 3 - Gunponder oars Gk 8 - 8 - 4 - 4 - - - Lime oara Gt 30 - 30 - 614 - 766 - 741 - Meat oara Gli - - - - 20 - 18 - 17 - Meat oars (Gg model) Ggi - - -- -- -- 55 - Manture oara Gpl - - - - 46- 43 - 34 - Milk oars Gina - - - - 57 - 28 - 24 - Cara for small, animals Gak - - - - 8 - 12 - 21 - Heated oars Gga - - - - - - - - 57 - Tank oars, oil Go - - 202/- 16 - 13 - 11 - 1/ Total for G, Ga, and Gb models 2/ "Tank oara" -60- coNFmENriaL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part_- Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONWIDEnTlui Tank oars, gasoline Ste+~m boiler oaro Oh Totala by axle types by years Totalo by yeara High wall Ha 9 - 8 Low will, old otyle H 5,023 - 5,187 - 3,83? - 2,590 ? 2,128 9,712 10,029 191 '912 4g35 Tng g.,g ? b ? b a bj (5 a (b) a b) New style Hdk Short, with low walHb 235 - 200 - 1, 616 - 5,400 - 6,202 Traneit tre,ftio type lid - - - - 54? - 568 - 570 Caa with walls of o.8 meters height Hh Short oars with low walla, for tire- wood transport HL Old style for tran- sit traf fio Hv - - - - 49 - 28 - 24 Timber ears I 74 - 72 - 59 - - - 290 Care without side walls K 469 - 402 - 223 - 120 - 38 Cars with rack walls for firewood L 63 - 56 - 8 - - Timber and plank transporting oara Ik 603 - 601 - 471 - 486 Timber and plank transporting oars HI 20 - 20 - 20+1 - - Gravel oars M 2,054 - 2,215 - 610 - 1,187 - 1,412 Gravel oars with high end walls -61- Gravel oars, dump- ing type Mao CONFIDNTIAL 16 - 432 - 299 - 453 - 17 Cars with side walls 0 - 114 - 486 - 147 - 78 - 74 Nip - - - - 1,105 - 519 - 216 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 5,599 - 7,513 ? 8,682 3 9,709 3 10,026  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIOE4j. are Oars Okay ------ '.-----'" Totals by axle typed 8,554114 8,777 486 8,987 1,629 12197 637 11,333 1,650 Totals by ear? 8,668 9,2(3 10,616 12,834 12,983 9 Transit traf 'le time 0v ? - ? ? 4 - 4 Artillery care, 8-ax1A type Os Large-capacity oars, 8-ax1e type Osk 2 - 1 1 - 1 2 - 2 2 .-...-~..r.? ..~ s Artillery oars, 12-axle type Os s Total freight care, box and open types 14,267 16,781 19,305 22,550 23,016 p 463 grh?q r_use4 bvthe 1 ads Box oars XG Disirnfeoting oars XGdf Trash cars XGp Watertank oars XGv Equipment care XGd Gas tank care XGe Oil Tank oars XGo Equipment oars XGav Emergency dynamo ears XGsm s b a b a (b) 932 a b s (bY - 1,461 - 1,538 - 1,509 75 3 101 3 105 11 1 - 1 - 2 - 45 - 55 - 60 - 2 - 1 - - ? ? - 2 ? 2 - ? ^ 18 - 20 - 24 - 24 - - - - - 44 - 47 - 40 1 Total box-car type 20 - 190 3 231 Open care with low walls XH Ice grader cars XHr -62- 17 4 COIF1DFNTIAL 231 12 Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 Firewood aars XL - - - 83 - 76 - 76 Artillery oars XOt - - - - 1 - 1 - Total opea typo Tp . . . - - - 7 - 7 . . R.bit.h: ~.*nd .. : ~$ 1912 1919 1927 1932 1935 g.lft (a) (b) (a) (b) (4) (b) (a) (b) (a) (b) Maii oars P 22 22 22 28 22 41 23 55 22 59 Duelling oars for postal worker' Total? by axle type Totals by years 22 22 CONfIoFpi TIAL 3,05 . 95 . 89 22 28 22 41 30 55 29 59 44 50 63 85 88 l 1* Teble 3. Dimensions and Weiphte of Newer-type Fuseenger Care Interior Dimensions Wheel- Length xidth Sidewall Weight No of C odQ &ndo i LnL LmtiL HeightJ-tm) Ltons) .. Cm, let and 2d class sleepers 14,920 19,540 2,920 2,250 37.59 20 17,120 CFm, let, 2d, and 3d olaee 14,920 19,540 2,920 2,250 36.90 10418 sleepers 17,120 Em, 3d class sleeper 14,920 19,540 2,920 2,250 36.60 39 17,120 Ci, let and 2d olaee with 14,920 19,540 2,920 2,250 37.55 6'33 day oompartments 17,120 Di, 2d olaaa day ooaoh with- 12,E00 17,420 2,920 2,250 33.20 56 out compartments 15,000 DEi, 2d and 3d class day 14,920 19,540 2,920 2,250 33.72 32+49 coaches 17,120 Ei, 3d olaee day coaches 14,920 19,540 2,920 2,250 33.60 100 17,120 D, 2d olaee day coach (2-axle) 9,000 13,020 2,970 2,250 18.07 46 DE, 2d end 3d olasa day coaches (2-axle) 6,400 10,740 2,980 2,250 16.75 16~r25 E, 3d class day coach (2-axle) 9,000 13,020 2,970 2,250 17.60 61 COF1F~~filTilsi. Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONrIOEN Jut L p464 Table 4? D1mons1ons, Capaaitiea and ~VotBhts oD Most Gomnon Types of F'eight Ox'e Interior Dimen,aioxie Pfhool- Length Width Sidewell Oapaoity Weight Load bode and Tvoa pnea fminJ (nu?~ _(mm) Mei8jyt..jmj) (a,ybia..~. (toq) (t,91iL) QII Os 3,660 6,480 2,450 2,100 32 7.40 10.12 G b 4,O0 7,928 2,642 2,200 46 10.00 15.0 Gd 3,810 6,400 2,644 2,220 36 8.85 16.5 o~ 4,500 7,780 2,800 2, 363 34 14.75 10.0 Gli 3,660 6,480 2,450 2,100 32 8.50 10-12 G81 Open Tnei 4,500 7,780 2,800 2,363 34 15.10 10.0 H 4,120 7,556 2,640 1,500 28 6,30 10.0 Hdk, short 4,120 7,556 2,640 2,000 40 7.60 16.5 Hdk, standard 4,500 7,900 2,790 2,000 44 8.65 16.5 Hd and Hv, formerly Hb 5,500 9,104 2,840 2,000 52 8.80 16.5 M, with ateel ohassia 2,800 5,166 2,696 448 6 6.65 12.0 M, all wood oor-etruotion 2,440 4,800 2,440 485 6 4.50 9.0 0 9,200 13,900 2,650 1,570 56 14.60 20.0 Ok 8,200 12,900 2,650 2,000 68 13.85 30.0 1,570 52 Os 19,500 15,300 2,360 - - 30.00 35.0 15,000 Oak 20,000 11.36 2,535 - - 31.95 5o.o 15,500 Oss 16,400 16.85 2,320 - - 60.00 105.0 25,600 -64- Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONHOENTIA!. p478 box ours oP the Ga type with wooden ahuauia end with the walla constructed oP vartioal boards were built until the and off' the first Oyer period Af the Finnish railrQade~ Alth h eetisfaetory, and in many reapeats more advantageous from the manut'aotur1ng aspect, this type of construction was terI~inatE1 in 1913 when the production of the Gd type (Figure 391) for transit traffic was begun. These oars have a steel chassis and the walls are boarded horizontally upon the inside eurfaoes of vortioal supporta. In the period fro: 1913 to 1920 private machine ehopa built a total of 2,083 of the Gd-type oars and the Paeilu shop built 2,145 in the period from 1914 to 1923, for a total of 4,228 oars. The 2,083 cars built by private ehope were apportioned tie followui Karhula machine shop, 116; Turku or factory, 1,398; Kone- ja Silt Oy, 210; Kiete1ahden Laivatelakka, 115; Tampereen Konetehdus, 164; and the Pori machine shop, 50. The old Ga-type cars, already in bad oondition, were converted in- to lime cars and finally into manure cars. Then as they reached the stage where reconstruction was necessary the old bodies were replaced with bodies of the Gd type, with a view toward standardization of oar sizes. The Gd bodiea' axIc are readily adaptable to the Ga chassis, since the Gd chassis is only 76 millimeters longer than the Ga chaebis, which measures 6.53 meters. * The Gd-type of box car is being replaced as the standard type, ow- ing to its small capacity. A new atandard type for box cars, the Gb type (Figure 393) built on the 8-meter chassis used also for flat cars and following the structural fQtures of the Gd type, was therefore p 479 designed in 1924. The frames for the bodies of the first order of the Gb care were of structural steel, but all bodies have been constructed entirely of wood since 1926. The aide doors were also widened to two -65- COfJFIflEidTlAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONFIDENTIAL meters . The well thiokneaa of the original Gb oars was 22 mi111metera, but this thiakneoa praved to bA of lnsutrioient strength to withstand shift- ing loads whioh damaged the rabbet joirtt? in the boards of the walls, eapeoially at the ends of thQ oars, permitting atlas entry of the elements into the oars. ThQ thickness of thn boards of the end walla was there- fore increased to 36 millimeters and Eki of the side wal3 ? to 24 milli- meters, and that of the floor planks to 56 millimeters. The and walls and side walls of the oars are reinforcod with dia- gonal steel braces ettwohed to the chassis of the oars the braces on the aide walls are equipped with turnbuoklea. Thn cornor poste are equipped with Z-brtacketu at the roof level to furnish anohorape for the intermediate poets of the end walla. A total of 2,293 Gb oars were built in 1935? The weight of the Gb oars equipped with ~lir brakes and manual brakes is approximately 10 tons and the specified loud wee 15 tone, which was increased in 1936 to 16.5 tons. All of the Gb oars f811 within the aerial numbere 29 36,001 - 46,160 and the former Russian Gay oars are numbered from 29,501 to 29,950? nent With the continued increase in the size of trains it has also been necessary to change periodically the dimensions of couplings, draft gear, and of buffer equipment. For example, when a heavier type of oar was adopted in 1897 in addition to the 2' axle oars then in use, it became neeeeaeary to increase the diameter of the turnbuckle aorer, of couplings from 30 millimeters to 33 millimeters. The turnbuokle screws of screw oouplings (Figure 106) made sinoe 1920 have a diameter of 45 millimeters, measured from the bottom of the thread. Stronger material is also employed in the construction of these couplings. -66~ CONIUENTIAL Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIDENTIAL p 493 similar increases in the dimensions of other oomponents of the oouplinga, as well ae in the draw-hook (o)evis) and drawbar, have been neoepsary. The diameter of the drawbar crap inoreaped from 98 millimeters to 42 millimeters in 1897 and to ~2 millimeters in 1919. Drawbars of the latter dimension are now installed on all oars during rnaj or repair operationa. The wedge oonneotione (f riotior~ j ointr) of drawbare are a oona- tent source of trouble in that they gradually loosen and upon breaking often csusa much damage to the under oarriagee of oars. A great im- provement was effected in this reapeot by thn adoption of the tubular or sleeve typo of drawbar bix392 joint in 1926. The extension type of thrust buffer is moot commonly used for onre, but greater numbrs of pistoYi typo buffers have boon manufactured recently ae these are stronger in all respects. The stoma of exten- sion type buffers frequently bend nut of ?hape or may oven braak off as a result of non-linear thruets,ainoe the buffers of all cars are not at the same height. Repeated attempts to overcome this source of 11 trouble have been made by increasing the diameter of the stem exten- sion rod) from 60 millimeters to 75 millimeters and finally to 85 millimeters (Figure 407 The piston type buffers first used in Germany were first impor- ted into Finland in 1928 in oonsiderable quantity. These were made in presses (Figure 408), but domestic production waa soon undertaken by welding from steel plate which type is ieee expensive and lighter. p 494 A relatively large number of buffers have been constructed in Finland ~i in which the internal tubular piston ie welded to the plate of the extension rod of the older type (Figure 409) ? Buffera of this type must, however, be considered only ao a temporary expedient until a more satisfactory type is developed. -67- coNFear~jriai Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 GONfIDEj TM I. p 503 Man actors and Re air of Cara The f iret pasaengcr aars anti freight ora used in ?inland an the Helsinki-Hthmeenlinng line were imported from England end these were then used ee models in the construotion of addition/ ogre at the rgilarood machine ehop in Helsinki ae needed for this line. When p 501 more ogre were needed for the Riihirllki-St. Petersburg line, the order we plaoed in the Pori machine shop in 1870, but when the Pori ehop was destroyed by fire a ome time later, the major ehgre of eubee- quent orders was transferred to Germany, a ?ouroe thereafter for se- veral order. of puaenger osre. A oonsiderable number of oars wu alao ordered in 188 for the Vaaeg line from the Atlas factory in StookholmWith the exception of one oftioial (state) oar ordered from Prague, all other final wa? ordere of foreign paaeengert ogre have been from Riga and St. Petersburg, the figures being 20 of the 2-axie type in 1698 from Riga and 50 of the aeme type from the St. Petersburg oar factory in 1900. The last Finnish order~f.or foreign freight care oonaieted of 180 box oara of the as code from Riga and 100 timber care from Belgium in 1899. In addition to the Pori machine shop mentioned above, the Osberg & Baden factory in Helsinki produced its first 50 freight care as early as 1872, but the Helaingin Laivetel~tkka (Helsinki Shipyard) did not begin production of railroad oara until 1889. Among the private enter- prisea which later entered the field the following are moat notable: Kone ja Silta Oy, Porin Konepaja (Pori Machine Shop), and the Kx??x Veljekaet Friie 0y, all in Kokkola; Turku Rautateolliauus Oy (Turku Iron Worka Corporation) in Karhule; Jckobasonin Konepa~a (Jecobsaon's Machine Shop) in Pori; Sommers, of M 1latr6m & Waldenaa factory in Tampere; and the Tampereen Pellavatehdae (now a part of Tampella) in Tampere. After the car-building activities of the State Railroada waa i$ 190 shop at Paeila tranaferredAfrom Helsinki to the large modern machine op -b8- COPdFIDEPJTIAI Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7  Declassified in Part- Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7 CONcIDEN hAL whioh had taoilitieo for the oonstruotion or fei~ht oars on a large oaa1e and also produces paoeen~er ors, thA number of ordera plaoed with private builders sradually decraasod until the tinal order of ittaj err proportion. for traight oars was placed is 1920 at the Turku oar f otory, After that time the yearly demand t'or new ogre has bccn much smaller owing to the burineee depreseion. -69- roFdFOaFPJ hA L Declassified in Part - Sanitized Copy Approved for Release 2012/04/05 : CIA-RDP82-00039R000100090087-7