4-8-2+2-8-4

A Garratt locomotive is actually two separate engines combined in a double articulated format, thereby providing multiple powered axles over which the total locomotive weight is spread. This results in a more powerful locomotive since, compared to a tender locomotive of similar total mass with tender included, a much larger percentage of the locomotive's total mass contributes to traction.[http://www.beyerpeacock.co.uk/main/Beyer%20Peacock%20Garratt%20Locomotives.html Beyer, Peacock Garratt Locomotives] {{webarchive|url=https://web.archive.org/web/20070926210855/http://www.beyerpeacock.co.uk/main/Beyer%20Peacock%20Garratt%20Locomotives.html |date=2007-09-26 }}

The {{nowrap|4-8-2+2-8-4}} Double Mountain was probably the optimal Garratt wheel arrangement, with the four-wheeled leading bogies and the two-wheeled trailing trucks on each engine unit ensuring stability at speed and with sixteen coupled wheels for traction. More coupled wheels would inhibit the locomotive on tight curves, while the only advantage of more non-coupled wheels would be to reduce the axle loading.

The largest steam locomotive built in Europe was a {{nowrap|4-8-2+2-8-4}} Garratt, built by Beyer, Peacock and Company for the Soviet Railways in 1932. The most numerous Garratt class in the world was also a Double Mountain, the Class GMA and GMAM of the South African Railways, of which 120 were built between 1954 and 1958.{{Holland-Vol 2|pages=58–62, 96–97, 103–105, 110–114}}{{Paxton-Bourne|pages=91–92, 94–96}}{{Durrant-Twilight|pages=39, 112, 115–118}}

Per definition, most Garratt locomotives are tank engines since they carry all their water and fuel in on-board water tanks and coal bunkers instead of in a separate tender. The three known exceptions were all tank-and-tender engines and were all {{nowrap|4-8-2+2-8-4}} Garratts.Espitalier, T.J.; Day, W.A.J. (1946). The Locomotive in South Africa - A Brief History of Railway Development. Chapter VII - South African Railways (Continued). South African Railways and Harbours Magazine, November 1946. pp. 894-896.

File:CFB Class 10C 4-8-2+2-8-4 no. 332.jpg

All three main railway systems in Angola used {{nowrap|4-8-2+2-8-4}} Garratt locomotives.

The {{Track gauge|Cape|allk=on}} Caminho de Ferro de Benguela (CFB) was the largest user, with 48 locomotives built by Beyer, Peacock & Company between 1927 and 1956. Six Class 10A locomotives were delivered in 1927, followed by fourteen Class 10B locomotives in 1930. In 1951 and 1952, eighteen Class 10C locomotives followed, and ten Class 10D locomotives were delivered in 1955 and 1956.

Six {{Track gauge|1000mm|allk=on}} Class 500 locomotives were built for the Caminhos de Ferro de Luanda (CFL) by Beyer, Peacock & Company in 1949. Six Class 550 locomotives, built for {{Track gauge|3ft6in|disp=1}} gauge, were delivered to the same system by Friedrich Krupp in 1954.

The third system, the Caminhos de Ferro de Moçâmedes (CFM), bought six Class 100 locomotives from Henschel & Son in 1953.

Four classes of {{nowrap|4-8-2+2-8-4}} Garratt locomotives entered service in Australia between 1929 and 1953, all on {{Track gauge|3ft6in|lk=on}} gauge.

Beyer, Peacock & Company built three locomotives for the Emu Bay Railway in Tasmania in 1929.

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The Australian Standard Garratt was developed in Australia during the Second World War, when the Commonwealth Land Transport Board (CLTB) commissioned Chief Mechanical Engineer Frederick Mills of the Western Australian Government Railways (WAGR) to design the locomotive as an emergency measure. Out of an intended 65 locomotives, 57 were built by the Midland Railway Workshops, Newport Workshops, Islington Workshops and Clyde Engineering between 1943 and 1945. The initial allocation was 23 locomotives to the Queensland Railways (QR), eight locomotives to the Tasmanian Government Railways, 25 locomotives to the WAGR and one to the Fyansford Cement Works Railway of Australian Portland Cement. Some of the locomotives later migrated from the QR and WAGR, where they were unpopular with crews, to other systems such as the South Australian Railways and the Emu Bay Railway.Gunzberg, A: A History of WAGR Steam Locomotives. ARHS WA 1984Oberg, Leon. (1975). Locomotives of Australia. Sydney, New South Wales: Reed. {{ISBN|0-589-07173-4}}

Thirty BG class locomotives were built for the Queensland Railways in 1951, ten by Beyer, Peacock & Company and twenty by Société Franco-Belge.

Franco-Belge also built ten 400 Class locomotives for the South Australian Railways in 1953.

In 1939, the Bengal Nagpur Railway introduced the Class P, weighing in at 230 tons and having a 17-ton axle load.{{cite book |last=Hughes |first=Hugh |date=1979 |title=Steam Locomotives of India, Part 3 - Broad Gauge |url=https://archive.org/details/steamlocomotives0000hugh/mode/2up |url-access=registration |location=Harrow, Middlesex |publisher=The Continental Railway Circle |page=45 |isbn=9780950346946 |access-date= |via=Internet Archive}} Indian Railways had proposals for a 4-8-2+2-8-4 design known as the Class WHG, which utimately never came to fruition due to the move towards dieselisation and electrification.{{cite book |last=Hughes |first=Hugh |date=1979 |title=Steam Locomotives of India, Part 3 - Broad Gauge |url=https://archive.org/details/steamlocomotives0000hugh/mode/2up |url-access=registration |location=Harrow, Middlesex |publisher=The Continental Railway Circle |page=23 |isbn=9780950346946 |access-date= |via=Internet Archive}}

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The East African Railways (EAR), formed in 1948 by merging the Kenya and Uganda Railways with the Tanganyika Railways to operate railways in Kenya, Tanganyika and Uganda, operated the largest and most powerful steam locomotive on {{Track gauge|1000mm|allk=on}}. This was the oil-fired EAR 59 class Garratt, of which 34 were built in two batches by Beyer, Peacock & Company in 1955. The 59 class had the reputation of being amongst the largest and most powerful steam locomotives in the world, with a {{convert|7|ft|6|in|mm|0|abbr=off}} diameter boiler and a tractive effort of {{convert|83350|lbf|kN|0|abbr=off}}. Although Garratt locomotives operated in all three territories, the 59 Class only worked in Kenya and latterly solely on the line between Nairobi and Mombasa. The last one was withdrawn from regular service in 1980.{{cite book|last1=Hollingsworth|first1=Brian|last2=Cook|first2=Arthur|title=The Great Book of Trains|year=1987|publisher=Lifetime Distributors|isbn=0-86101-919-9}}

Five classes of Double Mountain locomotives, three of which were tank-and-tender Garratts, were acquired by the South African Railways (SAR) between 1929 and 1954.

File:SAR Class GL 2351 (4-8-2+2-8-4).jpg]]

During 1929 and 1930, the SAR placed eight Class GL Garratt locomotives in service, built by Beyer, Peacock & Company to specifications prepared by Chief Mechanical Engineer (CME) Colonel F.R. Collins. Their tractive effort of {{convert|78650|lbf|kN|0|abbr=off}} at 75% boiler pressure made them the most powerful steam locomotives in service anywhere in the Southern Hemisphere at the time. They were originally employed on the Durban to Cato Ridge section of the Natal mainline, until electrification between Durban and Pietermaritzburg in 1938 saw them transferred to the gruelling coal train run between Glencoe and Vryheid. This work entailed the regular haulage of 1200 tons up gradients of 1 in 50 (2%), taxing the Class GL even more heavily than the work for which it was designed. Despite this, they maintained an effective service along this line until its electrification in 1968, after which they spent their final working years operating on the line from Stanger to Empangeni.

File:SAR Class GM 2298 (4-8-2+2-8-4).jpg]]

During 1938 and 1939, the SAR placed sixteen Class GM Garratts, built by Beyer, Peacock, in goods train service on the line from Johannesburg via Krugersdorp and Zeerust to Mafeking. After the initial designs by CME W.A.J. Day were rejected by the Chief Civil Engineer because the weight on the leading and trailing bogies exceeded the acceptable limit for {{convert|60|lb/yd|kg/m|0|abbr=off}} rail, the water capacity of the front water tank was reduced to {{convert|1600|impgal|L|abbr=off}} while the rear bunker was redesigned to carry no water and with a coal capacity of 10 tons. The meagre water supply was augmented by semi-permanently coupling a specially built {{convert|6750|impgal|L|abbr=off}} capacity Type X-17 water tender to the locomotive. In effect, since Garratt locomotives had hitherto been considered as tank engines because they carry all their water and fuel on board, this arrangement introduced the tank-and-tender Garratt. In all other respects, the design followed that of the heavy Class GL Garratt.

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During 1946 and 1947, the SAR placed fifty Class GEA Garratts in service. The order for fifty locomotives was the largest single Garratt order ever placed with Beyer, Peacock. Designed by CME Dr. M.M. Loubser as a development of the South African Class GE 2-8-2+2-8-2 locomotive, it was the first SAR Garratt to have streamlined water tanks and coal bunkers. Meant for goods traffic on light {{convert|60|lb/yd|kg/m|0|abbr=off}} rail on branch lines, the GEA was superheated and had Walschaerts valve gear. It was the only post-war SAR Garratt to be without a mechanical stoker and also one of the largest designs of Garratt to be hand-fired.

File:Class GMAM 4079 (4-8-2+2-8-4).JPG]]

Between 1954 and 1958, 120 Class GMA branch line and Class GMAM mainline Garratts entered service. This was the most numerous Garratt class in the world. A development of the Class GM, the Classes GMA and GMAM were identical and their water and coal capacities could be adjusted to suit by installing or removing plates in the coal and water spaces. They could easily be converted back and forth between the two versions, and often were. Like the Class GM, it was a tank-and-tender Garratt and the water supply was augmented by semi-permanently coupling a {{convert|6815|impgal|L|abbr=off}} capacity Type X-17 or {{convert|6790|impgal|L|abbr=off}} capacity Type X-20 water tender to the locomotive. Designed under the supervision of CME L.C. Grubb, they were built by three manufacturers, 55 by Henschel & Son, 33 by Beyer, Peacock and 32 by North British Locomotive Company, subcontracted by Beyer, Peacock.

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Also in 1954, 25 Class GO light branch line Garratts entered service. Designed under Grubb's supervision to operate on lighter rails, they were built by Henschel. In design and general appearance, the Class GO was very similar to the Class GMA, with the chief differences aimed at reducing weight, such as a smaller boiler with a reduced diameter, a smaller firebox and grate area and a half ton smaller capacity coal bunker. The one-piece cast steel frame and engine units were identical to that of the Class GMA, except that the cylinders had been lined and sleeved to reduce the bore from {{convert|20+1/2|to|18+1/2|in|mm|0|abbr=off}} to suit the smaller boiler. The Class GO was also a tank-and-tender Garratt and carried water only in its front tank while the rear bunker carried only coal, and it also ran with a semi-permanently coupled {{convert|6815|impgal|L|abbr=off}} capacity Type X-17 water tender.

A {{nowrap|4-8-2+2-8-4}} Garratt was built for the {{Track gauge|5ft|lk=on}} gauge Soviet Railways by Beyer, Peacock and Company in 1932. This was the largest steam locomotive in Europe and the largest Garratt in the world. It weighed 262.5 tons in working order and produced {{convert|90000|lbf|kN|0|abbr=off}} of tractive effort at 95% boiler pressure. It was built with {{convert|5|in|mm|0|abbr=off}} thick bar frames, was {{convert|17|ft|2|in|m|3|abbr=off}} high, and was tested in temperatures as low as {{convert|-41|C|F|0|abbr=on}}.

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{{Whyte types}}

{{Rolling stock of Russia}}

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