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FM Erie-built

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The Erie-built was the first streamlined, cab-equipped dual service diesel locomotive built by Fairbanks-Morse , introduced as direct competition to such models as the ALCO PA and FA and EMD FT . F-M lacked the space and staff to design and manufacture large road locomotives in their own plant at Beloit, Wisconsin , and was concerned that waiting to develop the necessary infrastructure would cause them to miss out on the market opportunity for large road locomotives. Engineering and assembly work was subcontracted out to General Electric , which produced the locomotives at its Erie, Pennsylvania , facility, thereby giving rise to the name "Erie-built."

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21-538: At the time, diesel road power was sold as multi-unit locomotives. The Erie-Built used the 2,000 hp (1,500 kW), ten-cylinder version of F-M's Model 38D 8-1/8 opposed piston diesel engine , which had seen success as a submarine powerplant in World War II , as its prime mover . This allowed the Erie-Built to deliver a 6,000 hp (4,500 kW) locomotive consisting of only three units, versus four units for

42-634: A curved upper contour. The Union Pacific Railroad bought the first A-B-A set, which was delivered in December 1945. Subsequent engine troubles and a nine-month strike at the Beloit plant made it difficult to get repeat orders. The largest order came in 1947, when the Pennsylvania Railroad ordered 16 three-unit A-B-A sets. Kansas City Southern Railway ordered a four-unit, 8,000 hp (6,000 kW), A-B-B-A set to run long trains at faster speed. However,

63-464: A possible crankcase explosion. F-M immediately attempted to address the problem but it was seven to eight years before a piston was developed that could stand up to railroad service. Replacement of a single power assembly (cylinder liner and its two pistons) required moving the locomotive under a crane and removing (and later reinstalling) the locomotive's roof hatch, upper crankcase, upper caps , upper connecting rod caps, and upper crankshaft, making

84-598: A welded truck that could be fabricated at the Erie plant, and was fitted to a number of units for UP, KCS, and NYC . However, most customers preferred the cast steel truck, and the engineering cost, jigs and fixtures and necessity for a second inventory meant that the fabricated truck design did not save money The Erie-Builts soon ran into problems with the OP engine that had not been experienced in Navy service. The 38D 8-1/8 engine as configured for

105-593: The Canadian Pacific Railway where they were incorporated into a quasi-portable CWR rail welding plant located at Smiths Falls, Ontario . These units were painted in a unique paint scheme almost identical to the Erie Lackawanna Railway 's but with Canadian Pacific lettering; these units having been acquired immediately prior to the CPR adopting the red and white CP Rail multi-mark paint scheme. Around 1990,

126-543: The bending moment created by the offset distance from the connecting rod to the main bearing. When describing a crankshaft design, the number of main bearings is generally quoted, as the number of crank pins is determined by the cylinder layout. For example, the Toyota VZ V6 engine is described as having a "four bearing crankshaft" and the Jaguar XK6 straight-six engine has a "seven bearing crankshaft". The lower half of

147-400: The engine block . The number of main bearings per engine varies between engines, often in accordance with the forces produced by the operation of the engine. Main bearings are usually plain bearings or journal bearings , held in place by the engine block and bearing caps . The number of main bearings is primarily determined by the overall load factor and maximum engine speed. Increasing

168-497: The 5,400 hp (4,000 kW) EMD FT and 6,000 hp (4,500 kW) ALCO FA . The Erie-Built used GE's model 746 traction motor, as used on the Great Northern Y-1 electric locomotive , making it the first diesel-electric locomotive to deliver 500 hp (370 kW) per axle. The locomotive was too heavy for a four-axle wheel arrangement, and had to be fitted with idler axles. The A1A-A1A wheel arrangement enabled

189-551: The CWR plant with the Erie-Built hulks were moved from Smiths Falls to a CP yard in the Transcona neighbourhood of Winnipeg, Manitoba in preparation for scrapping. Three sets of trucks from the Erie-Built hulks were salvaged and sent to Oregon, with two being placed under two truckless ex- D&H / ATSF Alco-GE PA-1s that were returned from Mexico, while an unused spare set was stored and eventually scrapped. One Erie-built CWR car did avoid

210-577: The Erie-Built to meet axle-load limitations while maintaining the simplicity and lower cost of a four-motor transmission, though it meant the Erie-Built was more prone to wheelslip than the FT. F-M retained the services of renowned industrial designer Raymond Loewy to create a visually impressive car body for the Erie-built. The initial windshield configuration utilized rectangular glass panes, whereas those units manufactured after March, 1947 received windshields with

231-679: The Erie-Builts Brake Mean Effective Pressure of 95.2 psi, as opposed to the 85 psi rating for Navy engines and 77 to 86.7 for the EMD 567 as used in the E7, FT and F3 . Submarines gave the engines access to cool, sea-level air, but on Western railroads like UP, the engines were operating under load at high altitude, high temperature, and low humidity, and often in the wake of waste heat from leading locomotives. Locomotives had closed-loop cooling systems while submarines drew cooling water from

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252-538: The Erie-Builts too expensive to build. 82 cab-equipped lead A units and 29 cabless booster B units were built for American railroads between December 1945 and April 1949. Afterward, F-M continued to market dual service streamlined units under its Consolidated line of locomotives, more commonly referred to as "C-liners". No FM Erie-Built units are known to survive today. After their retirement, four former Pennsylvania Railroad Erie-built B unit hulks were sent to

273-479: The Wikimedia System Administrators, please include the details below. Request from 172.68.168.226 via cp1108 cp1108, Varnish XID 755554960 Upstream caches: cp1108 int Error: 429, Too Many Requests at Fri, 29 Nov 2024 05:45:00 GMT Main bearing#Bearing capsbearing A main bearing is a bearing in a piston engine which holds the crankshaft in place and allows it to rotate within

294-513: The difficulty of building it at a profit. It was determined that even if production was moved to Beloit, the high cost of items like the GE 746 traction motor (which was more expensive than the GE 752 used by the Alco PA), the unique cast and fabricate trucks, a secondary electrical power system for radiator fans and traction motor blowers, and a secondary cooling system for the lube oil (a Navy requirement), made

315-429: The inferior reliability and higher maintenance costs, several Erie-Builts, including four of NYC's eight freight Erie-Builts and eight of KCS Erie-builts were repowered with an EMD 567 series diesel engine rated at 1,750 hp (1,300 kW). New York Central derated the OP engines in its six passenger Erie-Builts to 1,750 hp (1,300 kW) by 1957. F-M ceased production of the Erie-Built in 1949, due largely to

336-464: The initial scrapping of the plant in 1994 but was later scrapped separately in 2010.   *Note: Union Pacific cab/booster/cab set 700 / 700B / 701 was originally Fairbanks-Morse demonstrator set 50-M-1A / 50-M-3B / 50-M-2A; became 981A / 983B / 982A in 1947, then 700 / 700B / 701 in 1948. Cab/booster sets 702 / 702B and 703 / 703B delivered as 984A / 986B and 985A / 987B. Fairbanks Morse 38 8-1 Too Many Requests If you report this error to

357-476: The main bearings are typically held in place by 'bearing caps' which are secured to the engine block using bolts. The basic arrangement is for each bearing cap to have two bolts, but some engines may have four or six bolts per bearing cap (often referred to as "four-bolt mains" or "six-bolt mains" engines). The additional bolts result in increased strength, allowing the engine to withstand higher power output or RPM. The first car engine to use four-bolt main bearings

378-577: The number of bearings in an engine will generally increase the size and cost of the engine, but also reduces bending stress and deflection caused by the distance from the crank pins to the nearest bearings. Most engines have at least two main bearings— one at each end of the crankshaft. Additional bearings may be located along the crankshaft, sometimes as many as one bearing per crank pin , as used on many modern diesel engines and petrol engines designed for high RPM. Some small single-cylinder engines have only one main bearing, in which case it must withstand

399-432: The operation much more time- and resource-intensive than a power assembly change on other engine types. Fairbanks-Morse learned that in shops that maintained multiple locomotive types, where the foreman was under pressure to repair as many locomotives as possible, repair of OP engines that required extensive disassembly was often delayed in favor of other types of locomotives that could be turned around more quickly. Owing to

420-503: The resulting slack action on trains spanning several up-and-down gradients resulted in an excess of broken draft gear . KCS bought five more units to reconfigure its Erie-Builts to 6,000 hp (4,500 kW) A-B-A sets. Most units rode on conventional General Steel Castings trucks , which looked similar to those used on the Alco PA but were actually a different design. This drove up the cost as it required new foundry patterns. GE design

441-450: The sea. No FM OP powered submarines used open loop cooling systems. Open loop cooling systems were discontinued prior to WWII. They did use a heat exchanger cooled by sea water, but it was still a closed system. The OP engine had no head, and its exhaust ports were uncovered by the lower pistons. This resulted in excessive lower-piston temperatures, and under heavy load this led to piston failure, which could then cause cylinder liner damage and

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