Allison T56 variants

The Allison T56 turboprop engine has been developed extensively throughout its production run, the many variants are described by the manufacturer as belonging to four main series groups.
Initial civil variants were designed and produced by the Allison Engine Company as the 501-D and powered the Lockheed C-130 Hercules. Later variants gave increased performance through design refinements.
Further derivatives of the 501-D/T56 were produced as turboshafts for helicopters including a variant with a United States military aircraft engine designation of T701, which was developed for the canceled Boeing Vertol XCH-62 project.

Commercial variants (501-D)

;501-D10: The initial civil variant, which was proposed in 1955 with of power at a brake specific fuel consumption of, a two-stage gearbox with a reduction ratio of 12.5:1, a 14-stage axial flow compressor with a compression ratio over 9:1, a four-stage turbine, and a, three-blade Aeroproducts A6341FN-215 propeller.
;501-D13: Commercial version of the T56-A-1 used on the Lockheed L-188 Electra, but using kerosene as the primary fuel and JP4 as the alternate, and with the gearbox reduction ratio increased to 13.54 from 12.5, which lowers the propeller blade tip speed by 8 percent to for the Aeroproducts 606 propeller; power rating at sea level takeoff, 14-stage axial compressor, 6 cannular combustion chambers, and 4-stage turbine; 13,820 rpm shaft and turbine inlet temperature; certified on September 12, 1957.
;501-D13A: Similar to the 501-D13 but using a Hamilton Standard propeller; certified on April 15, 1958.
;501-D13D: Similar to the 501-D13 except for the location of the rear mount and using D.C. generator drive; certified on December 18, 1959; used on the Convair CV-580 passenger aircraft.
;501-D13E: Similar to the 501-D13 except for the location of the rear mount; certified on December 18, 1959.
;501-D13H: Similar to the 501-D13D but with water-methanol injection; certified on February 20, 1964; used on the USAF's General Dynamics NC-131H Samaritan. and the Convair CV-580.
;501-D15: A engine under development for the Lockheed Electra.
;501-D22: Similar to the 501-D13A but with power rating at sea level takeoff, a shroud turbine, gearbox offset up, and no auto-feathering; certified on October 28, 1964. Used on the Lockheed L-100 Hercules.
;501-D22A: ; Similar to the 501-D22 but with power rating at sea level takeoff and air-cooled first-stage turbine blades, vanes, and stalk blades in all four turbine stages; certified on January 23, 1968.
;501-D22C: Similar to the 501-D22A but with gearbox offset down, integral mount pads, and water-methanol injection; certified on December 27, 1968; powered the Aero Spacelines Super Guppy.
;501-D22D: A derivative to power the proposed Lockheed L-400, a twin-engine version of the L-100.
;501-D22E: Offered in 1979 as the initial engine for Lockheed's proposed L-100-60.
;501-D22G: Similar to the 501-D22C but with power rating at sea level takeoff, a three-mount system, auto-feathering, and no water-methanol injection; certified on March 23, 1984. Used on the Convair CV-580
;501-D36: Re-engined powerplant for the Royal Canadian Air Force CC-109 Cosmopolitan in 1966.
;501-D39: Offered for the Lockheed L-100 civil aircraft, starting in 1979 for the proposed L-100-60 as the successor engine to the 501-D22E, producing with propellers; was the commercial version of the 501-M71.
;501-H2: Engine for the proposed Vanguard Model 30 lift fan aircraft that was entered in a 1961 vertical takeoff and landing transport competition; powered two fans within the wings and two propellers; used a modified compressor for handling larger air flows.
;501-M1: Modified engine with new turbine blades that were hollow and air-cooled; on an experimental engine combining features of the 501-M1 with the 501-H2, ran at for nearly 2.5 hours at a turbine inlet temperature of in January 1962 under a program funded by the Air Force and Navy.
;501-M7B: Replaces the T56-A-7 on an experimental short takeoff and landing version of the Lockheed C-130E targeted in 1963 for the U.S. Army; power increased by 20% over the T56-A-7 due to lowering of the gear reduction ratio from 13.54 to 12.49, propeller blade changes to take advantage of the higher resulting propeller rotational speed, and a new turbine with air-cooled first and second-stage vanes and first-stage blades, so the turbine inlet temperature can be increased from for the T56-A-7 to ; a rate engine that is restricted to and about of static thrust on the STOL C-130E, but is capable of thrust at full power and with a larger, propeller.
;501-M22: Internal designation for the T56-A-18; submitted for FAA certification under a new type certificate.
;501-M23: Submitted for FAA certification under an amended type certificate.
;501-M24: A demonstrator engine started in 1964 that was later used to derive the 501-M62B engine developed for the XCH-62 helicopter.
;501-M25: A four-stage fixed turbine engine similar to the T56-A-15, but with a increase from the T56-A-15's maximum turbine inlet temperature rating of, and a variable geometry compressor for the inlet vane and the first five stator vanes; investigated in 1965 to power helicopters with a maximum takeoff weight.
;501-M26: A similar to the 501-M25 but with a free turbine instead of a fixed turbine, and a two-stage gas producer turbine; based on the T56-A-18 engine.
;501-M34: A turboshaft engine targeted for a 60-70 seat commuter helicopter proposal from Lockheed-California in 1966.
;501-M56: Engine candidate for the turboprop version of the Air Force A-X close air support aircraft, requiring of engine power.
;501-M62B: An internal designation for the engine that became the T701-AD-700 turboshaft, which weighed and was intended to power the Boeing Vertol XCH-62 heavy-lift helicopter; 15 engines built, 700 hours of component testing, and almost 2,500 hours of engine development testing completed before the helicopter project's cancellation.
;501-M69: Engine proposed for transport-type offensive anti-air aircraft versions of the P-3 Orion and C-130 Hercules; rated power of, equivalent installed thrust-specific fuel consumption at cruise of.
;501-M71: A derivative of the T56-A-14 evaluated by NAVAIR in 1982 to achieve 10% lower fuel consumption, 24% more horsepower, smokeless exhaust, and greater reliability.
;501-M71K: A engine using a larger propeller to power the Lockheed L-100-20 High Technology Test Bed for short takeoff and landing starting in 1989, but was destroyed when the HTTB became airborne during a ground test on February 3, 1993.
;501-M78: A demonstrator engine for NASA's Propfan Test Assessment program. It had a modified reduction gearbox that reversed the direction of rotation and increased the output speed from 1,020 rpm to 1,698 rpm. The engine was attached to an eight-bladed,, single-rotation Hamilton Standard SR-7L propeller. Shown as an engine at the 1983 Dayton Air Show, the 501-M78 was flight-tested on a Gulfstream II aircraft beginning in May 1987. Various flight and ground testing programs were carried out on the engine testbed through June 1989.
;501-M80C: Also known as the T406-AD-400, a turboshaft engine. primarily based on the T56-A-427, but with a free-turbine turboshaft added to the single-spool engine; used on the V-22 Osprey tiltrotor assault transport.
;PW–Allison 501-M80E: A contra-rotating geared propfan engine derived from the 501-M80C/T406 turboshaft engine and intended for use on a 92-seat version of the proposed MPC 75 regional aircraft; developed jointly with Pratt & Whitney.
;501-M80R3: A turboprop engine offered as an equal partnership between Allison and Pratt & Whitney to power Lockheed's proposed successor to the P-3 Orion, which was developed for the U.S. Navy's long-range air antisubmarine warfare capable aircraft program.
;501-M80R33: A propfan engine studied for the MPC 75 that was based on the T406 core and rated at.

Industrial and Marine variants (501-K)

;501-KF: Allison's first marine gas turbine, it was used for electrical generation on Spruance-class destroyers, with each of the three turbogenerators producing 2,000 kW. A version with a new AC generator producing 2,500 kW was used on Kidd-class destroyers and Ticonderoga-class cruisers. A substantially altered and incompatible version was used on Arleigh Burke-class destroyers, generating 2,500 kW on Flight I and II ships as the AG9130 generator set and 3,000 kW on Flight IIA ships as the AG9140 generator set. Commercial variants have also been used on the Boeing 929 Jetfoil and Israeli Shimrit-class missile boats.
;570-KF: Part of a new series of engines introducing technology used in Allison's T701, introduced in 1983 and capable of producing. This engine has been used on Stockholm-class corvettes, Iroquois-class destroyers, and several private yachts.
;571-KF: Part of the same series as 570-KF, introduced in 1986. Largely identical to the 570-KF, but with an additional stage on the power turbine and higher compression ratio for greater power generation, at.
;572-KF: Introduced in 1996, the 572-K series are further derivatives of 571-K incorporating an entirely new compressor along with three dry low emissions combustors taken directly from the Rolls-Royce RB211 to reduce the engine's emissions footprint. It is capable of generating between and
;MT5S: A replacement for the venerable 501-KF in military vessels, MT5S was developed for use aboard the Zumwalt-class destroyers as part of the RR4500 generator set, producing 3,800 kW. An uprated version known as MT5S-HE+ has since been developed for use in the AG6190 generator sets fitted to Flight III Arleigh Burke-class destroyers where it produces 4,000 kW.

Military variants (T56)

;T56-A-1: A engine delivering and residual jet thrust, which is equal to ; single-shaft 14-stage axial flow compressor, cannular combustion chamber with 6-cylindrical through-flow combustion liners, 4-stage axial flow turbine; 13,800-rpm shaft connected to a 2-stage reduction gear with a 12.5-to-1 ratio, consisting of a 3.125-to-1 spur set followed by a 4.0-to-1 planet set.
;T56-A-1A: A engine used on the Lockheed C-130A Hercules.
;T56-A-2: Proposed gas generator engines for the McDonnell XHCH-1 helicopter.
;T56-A-3: A engine that was paired with an Aeroproducts propeller and test flown by the Military Air Transport Service on a pair of Convair YC-131C twin-turboprop aircraft between January and December 1955.
;T56-A-4: A engine for the C-131D executive transport/VC-131H VIP transport; also the proposed engines for the McDonnell XHRH-1 helicopter, with propeller drive and gas generator bleed for rotor-tip pressure jets.
;T56-A-5: A turboshaft version for the Piasecki YH-16B Transporter helicopter.
;T56-A-6: Gas generator engines for the NC-130B boundary layer control demonstrator.
;T56-A-7: A engine flight-tested on a U.S. Air Force Allison Boeing B-17 flying testbed aircraft, intended for the Lockheed C-130B; also used on the C-130E; produces about of static thrust.
;T56-A-7A: Lockheed C-130B Hercules Starting May 1959.
;T56-A-7B: Used on the U.S. Air Force C/HC/NC-130B, MC-130E, and WC-130F; similar to -A-7A.
;T56-A-8: Entered production in 1959; the original engine on the Grumman E-2C, using the Aeroproducts A6441FN-248 propeller.
;T56-A-9: Used on the U.S. Air Force C/AC/DC/GC/NC/RC-130A and the C-130D.
;T56-A-9D: Lockheed C-130A Hercules starting December 1956 and on all Grumman E-2A Hawkeyes from 1960.
;T56-A-9E: Similar to -A-9D.
;T56-A-10W: Water injection model that entered production in 1960.
;T56-A-10WA: Used on the P-3A, EP-3A, and RP-3A.
;T56-A-11: Ordered for 12 Royal Australian Air Force C-130s in 1958.
;T56-A-13: Enhancements that improve SFC by 7.9%, increase maximum engine torque limit operation from, and increase turbine life; tested on a C-130H testbed aircraft in 2012.
;T56-A-14: Lockheed P-3/EP-3/WP-3/AP-3/CP-140 Aurora from August 1962; entered production in 1964.
;T56-A-14A: Fuel efficiency and reliability upgrade, Lockheed WP-3D Orion from May 2015.
;T56-A-15: Lockheed C-130H Hercules USAF from June 1974.
;T56-A-15A: Upgrade of the T56-A-15 on the Air Force LC-130H.
;T56-A-16: Used on the KC-130F, KC-130R, LC-130F, and LC-130R.
;T56-A-16A:.
;T56-A-18: A, variant that was designed and first run in 1965; Navy-funded development with air-cooled blades and vanes in the first two stages; 50-hour preliminary flight rating test completed in 1968; turbine inlet temperature of ; introduced major gearbox update after 4,000 hours of back-to-back testing, featuring a double helical first gear stage, a planetary helical gear for the second stage, and fewer parts for the accessory gearing ; used an eight-bladed Hamilton Standard variable-camber propeller.
;T56-A-20: Proposed in 1968 to be funded within the 1969 fiscal year component improvement program.
;T56-A-100: U.S. Air Force EMDP demonstrator
;T56-A-101: Offered for the Lockheed C-130 Hercules.
;T56-A-422: Used on U.S. Navy Northrop Grumman E-2C Hawkeye aircraft.
;T56-A-423: Used on U.S. Navy Lockheed EC-130G and EC-130Q aircraft.
;T56-A-425: Replaced the T56-A-8 on the Grumman E-2C, using the Hamilton 54460-1 propeller; Grumman C-2A Greyhound from June 1974.
;T56-A-426: Used on the C-2A, E-2B, and TE-2A
;T56-A-427: Northrop Grumman E-2 Hawkeye upgrades from 1972.
;T56-A-427A: Used on the Northrop Grumman E-2D Advanced Hawkeye, which first flew in 2007.