On July 11, 1989,
Saab-Scania A.B. selected the GMA 2100 to power its new
Saab 2000, a 50-seat stretch of the
Saab 340 turboprop, in a US$500 million deal.[2] In July 1990, Industri Pesawat Terbang Nusantara (IPTN) of Indonesia picked the GMA 2100 as the engine for the twin-engine
N-250 regional airliner.[3]Flight testing with a 13 ft 6 in diameter (4.11 m) Dowty R373 propeller on a
Lockheed P-3 Oriontestbed aircraft began on August 23, 1990, and finished after over 50 hours of flight and ground testing.[4]
The GMA 2100D3 became the powerplant for the
Lockheed Martin C-130J Super Hercules. It made its first
test flight on March 19, 1994,[5] which was conducted by Marshall Aerospace on a
Lockheed C-130K Hercules testbed leased from the
Royal Air Force. Testing ended in June 1994 after 47 flight hours.[6] The engine powered the initial flight of the C-130J aircraft on April 5, 1996.[7] By April 1997, the D3 variant had received
Federal Aviation Administration (FAA) type certification.[8] 2,000 of the D3 variants have been delivered as of 2018.[9]
The engine's C variant was certified on December 20, 1993.[10] It powered the N-250 prototype's first flight on August 10, 1995,[11] but the N-250 aircraft program was postponed indefinitely in the late 1990s due to the
Asian financial crisis.[12]
In June 1997, the AE 2100 was selected by
Lockheed Martin and
Alenia to power the
C-27J Spartantactical airlifter.[13] In October 2015, Alenia announced plans to use a 5,100-horsepower (3,800-kilowatt) uprated version of the AE 2100 as the baseline engine by 2017.[14]
Design
A derivative of the Allison AE 1107C-Liberty (
Rolls-Royce T406)
turboshaft engine, the AE 2100 shares the same high-pressure core as that engine, as does the
Rolls-Royce AE 3007turbofan. This core is capable of powering turboprops of up to 10,000 shp (7,500 kW).[15] The AE 2100 is a two-shaft design,[16]: 83–84 and it was the first[when?] to use dual
FADECs (full authority digital engine control) to control both engine and
propeller,[17] allowing both to be adjusted with a single lever.[16]: 83–84 There are four production variants of the engine: the civil AE 2100A, and the military variants which include the AE 2100D2/D2A, AE 2100D3, AE 2100J and AE 2100P.
The AE 2100 inherited the
Allison T56's 14-stage
axial compressor design, but the inlet and the
stator for the first five stages have variable blades. The
annular combustor has 16 air-blast fuel injection nozzles. The turbine that drives the compressor has two stages, with the first stage using single-crystal blades. A
free power turbine with two stages drives the propeller through an inner shaft and a gearbox.[16]: 83–84 The engine has replaceable steel blades and vanes, which are more reliable but heavier than
titanium.[15]
The AE 2100 engine and
gearbox are rated at 6,000 shaft horsepower (4,500 kilowatts), but was derated to 4,200, 4,590, and 3,600 shp (3,130, 3,420, and 2,680 kW) for the
Saab 2000,
Lockheed Martin C-130J Super Hercules, and
IPTN N-250, respectively.[18] The engine uses six-bladed, all-composite blade
Dowty propellers, including the model R381 on the Saab 2000, R414 on the
ShinMaywa US-2,[17] R384 on the IPTN N-250,[19] and R391 on the C-130J military transport[20] and the
LM-100J civil-certified version of the C-130J.[21] The gearbox has a reduction ratio of about 14 and a mean time before unscheduled removal (MTBUR) of over 35,000 hours.[22]
A variant proposed in 1995 and paired with Dowty R394 propellers to retrofit the
Allison T56-powered
Lockheed C-130 models E through H and
Lockheed L-100-30, at a price after engine/propeller trade-in of USD$11 million per aircraft.[23]
AE 2100G
A variant offered in 1994 for the proposed
ATR 82, a twin-turboprop airliner seating up to 86 passengers and requiring about 5,000 hp (3,700 kW) of power.[24]
A hybrid of the AE 2100A and AE 2100D3, sporting the torque-meter and interconnecting struts from the AE 2100A and the gearbox-mounted accessory gearbox from the AE 2100D3; also uses a stronger reduction gearbox, a Dowty six-bladed propeller for higher loads, and modified inlet and bypass section positioning to mitigate seawater ingestion;[26] powers the
ShinMaywa US-2.
A variant proposed in 1994 for the European
Future Large Aircraft[27] (which eventually became the
Airbus A400M), with the required power increase from 6,000 to 10,000 shp (4,500 to 7,500 kW) estimated to cost USD$600 million.[28]
Specifications (AE 2100D3)
Data fromFAA type certificate data sheet no. TE1CH.[29]
^
abPremo, David J. (November 1991). "Allison flies solo into the new commuter aircraft market". Commuter Air International. Vol. 13, no. 11. pp. 19+.
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abcdConiglio, Sergio (February 2010). "Military aircraft propulsion: Jets vs. props". Military Technology (MILTECH). Vol. 34, no. 2. Mönch Publishing Group. pp. 77–84.
ISSN0722-3226.
OCLC527912380.
^Sweetman, Bill (October 1994). "New power for regionals". Finance, markets & industry. Interavia. Vol. 49, no. 583. Minneapolis, Minnesota, U.S.A. pp. 16–18.
ISSN1423-3215.
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^"IPTN rolls out with 188 orders; Gulfstream Air signs LOI for 4". Commuter Regional Airline News. Vol. 12, no. 45. 14 November 1994. p. 3.
ISSN1040-5402.
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^Woolley, David (November 1991). "Powering up the next generation of turboprop aircraft". Commuter Air International. Vol. 13, no. 11. pp. 12+.
ISSN0199-2686.
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