Pratt & Whitney/Allison 578-DX

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Model 578-DX
PW-Allison-578-DX 1989.png
The PW-Allison Model 578-DX geared propfan demonstrator.
Type Propfan
National origin United States
Manufacturer Pratt & Whitney / Allison Engine Company
First runMid-1987 [1]
Major applications Boeing 7J7 (proposed)
McDonnell Douglas MD-91, MD-92, and MD-94X
Number built2 demonstrators
Developed from Allison T701 / Allison 501-M62B

The Pratt & Whitney/Allison 578-DX was an experimental aircraft engine, a hybrid between a turbofan and a turboprop known as a propfan. The engine was designed in the 1980s to power proposed propfan aircraft such as the Boeing 7J7 and the MD-91 and MD-92 derivatives of the McDonnell Douglas MD-80. As of 2019, it is still one of only four different contra-rotating propfan engines to have flown in service or in flight testing.

Contents

Development

The Allison Engine Company, a division of automobile manufacturer General Motors (GM), unveiled its Model 578 contra-rotating propfan engine at the Paris Air Show in mid-1985. [2] The engine represented Allison's attempt to re-enter the commercial airline engine market, because after turboprop aircraft were overtaken in civil aviation in the 1950s and 1960s, Allison was mostly confined to selling military aircraft engines. [3] Targeted to power passenger airliners seating between 100 and 160 passengers, the engine would be based on the core of the Allison T701 heavy lift helicopter turboshaft engine, which first ran in 1975. The engine would come in two sizes: a 10,000 shaft horsepower (7,500 kilowatts) variant with a 23:1 compression ratio and a three-stage boost compressor and power turbine added to the T701 core, and a 16,000 shaft hp (12,000 kW) variant with a 33:1 pressure ratio and a four-stage boost and power section. [4] Since Allison estimated that a 100-seat plane required two 9,000–10,000 shaft hp (6,700–7,500 kW) engines and that a 150-seat plane needed two 13,000–15,000 shaft hp (9,700–11,200 kW) engines, the two sizes chosen should handle the 100-160 passenger aircraft market. Allison hoped to have its 578 engine ready for flight tests in late 1987. [5]

Joint venture

Allison and United Technologies aircraft engine division Pratt & Whitney announced on March 14, 1986 that they would develop the engine as a joint venture. [6] The agreement, which was signed on February 25, was reached because Pratt & Whitney would not be able to develop its own propfan engine by the planned 1992 certification date of the 7J7, and because it also did not have an engine core in the size range of 10,000–16,000 shaft hp (7,500–11,900 kW). [7] Allison would develop the engine and perform ground testing, while Pratt & Whitney would integrate the propulsion system into the aircraft and manage the flight test program. [8]

On February 23, 1987 in Detroit, Michigan, Pratt & Whitney and Allison officially formed a joint company named PW–Allison Engines. [9] The new company claimed that compared a commercial jet engine, its propfan engines would consume 30-percent less fuel, require shorter runway lengths during takeoffs and landings, and be quieter [10] (because of the slower propfan rotational speeds enabled by the 578's gearbox). [11] The partnership would last 20 years and cover geared propfan development in the 8,200–16,000 shaft hp (6,100–11,900 kW) range, though the power range could be increased by fifteen percent with a specific mechanical modification. [12] The new company also expected Japanese and European engine makers to eventually join its program instead of creating competing propfan engines. PW–Allison Engines was to invest at least 500 million dollars to bring the engine into commercial production (depending on airline commitments to buy aircraft using its engines), [11] and it assumed that the new company would take half of the market for new medium-sized airliners over the next ten years—a 13-to-18 billion dollar market, it estimated. [13] Pratt & Whitney would handle the marketing to commercial customers, while Allison would do the marketing to military customers. [14] Other members of the new company included GM subsidiaries Hughes Aircraft and Delco Electronics and United Technologies subsidiary Hamilton Standard, [15] the propeller manufacturer that invented the propfan concept with the National Aeronautics and Space Administration (NASA) in the 1970s. [16]

An early version of the Pratt & Whitney/Allison 578-DX demonstrator engine, intended to power propfan-powered aircraft such as the Boeing 7J7 and the McDonnell Douglas MD-91. PW-Allison 578-DX (1987).png
An early version of the Pratt & Whitney/Allison 578-DX demonstrator engine, intended to power propfan-powered aircraft such as the Boeing 7J7 and the McDonnell Douglas MD-91.

Boeing 7J7

On December 20, 1985, Boeing and Allison agreed to test its new propfan engine for use on the Boeing 7J7. [17] As of early 1986, Allison maintained that it could have its propfan engine certified by early 1990, [18] although a few months later the company changed the certification target timeline to 1992. [19] By early/mid 1987, Boeing had rejected using the PW–Allison engine for its 7J7. Although Boeing had not tested PW–Allison's propfan in flight, the airframer said that the PW–Allison engine's off-the-shelf core was not powerful enough to power the 150-seat plane. PW–Allison vigorously objected, claiming its engine's gearbox could handle 13,000 shaft hp (9,700 kW), the agreement between Pratt & Whitney and Allison covered up to 16,000 shaft hp (12,000 kW), and the gearbox design could go to 25,000 shaft hp (19,000 kW). [11] The decision became moot in December 1987, when Boeing indefinitely suspended development of the 7J7 aircraft, four months after delaying the 7J7 availability date from 1992 to 1993. [20]

McDonnell Douglas MD-91X/MD-92X

In January 1986, Allison also signed a memorandum of understanding with McDonnell Douglas to perform flight tests on the Allison demonstrator engine, now known as the 578-DX, on an MD-80 testbed in late 1987. [21] The flight test program was in preparation for McDonnell Douglas's ultra-high bypass (UHB) MD-91X derivative, a 114-seat airliner [12] that had a planned service entry in the early 1990s. The demonstrator engine would convert 10,400 shaft hp (7,800 kW) into 19,000 pounds-force (85 kilonewtons) of thrust. One engine would be built for ground testing, while another would be used in flight tests. [21] The 578-DX would follow in testing the competing General Electric GE36 UDF engine, which was scheduled for 75 hours of flight tests on the MD-80 testbed from May 1987 through August 1987; the 578-DX would complete its 75 hours of flight testing from December 1987 through February 1988. During the middle of each engine's test program, McDonnell Douglas would let airline representatives fly in the testbed aircraft to assess the passenger experience. [11] McDonnell Douglas would begin installing one 578-DX demonstrator on its testbed in September 1987, while PW-Allison would perform ground tests with its other 578-DX demonstrator from mid-June 1987 to November 1987. [12] Ground testing was to begin around August 1987, and PW–Allison was confident that its engine would be flight tested by early December. [22]

A number of issues hindered the 578-DX, though. First, there was difficulty in manufacturing the thin, swept blades. Then, after one test engine was disassembled for inspection, the second engine ingested parts of the first engine into its compressor during testing. These problems delayed flight tests until the end of February 1988, [23] and they delayed ground testing of the engine until December 19, 1987. [24] In February 1988, PW–Allison postponed the service entry date until the end of 1993 at the earliest, as it said that the 578-DX was not powerful enough for the MD-92, [25] and the required increase in engine power from 14,000 to 16,000 shaft hp (10,000 to 12,000 kW) could not be finished in time for the McDonnell Douglas's 1992 target date. PW–Allison moved the beginning of flight tests to May 1988, [26] [27] but the flight date target was missed again because of endurance problems from the electrical pitch-change motors, so flight testing was put off until August to October of 1988. [28]

Amidst the flight test delays, McDonnell Douglas repeatedly expressed dismay that PW–Allison had not made a formal offer to place its engines into an MD-90 production program. [29] [30] The airframer wanted to offer its proposed derivatives to airlines with a choice of powerplant options, instead of advertising aircraft availability with just the competing GE36 UDF engine. However, PW–Allison refused to submit an offering to McDonnell Douglas and the airlines before its flight tests were completed and evaluated. [30]

Ground tests for the 578-DX finished on August 10, 1988 after almost 2,500 hours of runs, resulting in a successful preliminary flight rating test (PFRT), which cleared the way for flight testing. [31] However, the 578-DX could not undergo flight tests until early 1989, because the GE36 demonstrator had been reinstalled on the MD-80 testbed for additional tests. [32] The 578-DX was shipped off for testbed installation on October 18, 1988, [33] and it was installed on the MD-80 testbed in November 1988. The testbed then performed ground runs and taxi tests at Edwards Air Force Base, [34] with the first flight scheduled for January 1989. [35] More delays occurred, though, including one during preparation for a planned March 12, 1989 first flight that was caused by an abrasion on the gearbox's bearing separator. [36]

Nearly a year and a half after the flight test was originally planned, the 578-DX engine finally flew on April 13, 1989, with the first five flights being described as performing "flawlessly" through nearly the whole flight envelope. [37] At the time, the 578-DX demonstration program was planning to conduct 50 hours of flight tests over the upcoming three to four months. [34] The demonstrator covered a flight envelope of up to Mach 0.77 and up to an altitude of 30,000 ft (9,100 m), with one flight attaining an indicated airspeed (IAS) of 340 knots (390 mph; 630 km/h) at an altitude of 22,000 feet (6,700 m), or over Mach 0.8. [37] However, the 578-DX testbed aircraft ended up flying only through May 1989, [38] making 14 test flights for a total of just 20 hours. [39]

Due to the absence of firm propfan orders, McDonnell Douglas announced in May 1989 that the V2500 turbofan engine from International Aero Engines (a multinational engine consortium that included Pratt & Whitney as a member) would be provided as a powerplant option for the MD-90 series. [40] In September 1989, with the order drought continuing, McDonnell Douglas decided to offer the MD-90 series exclusively with the V2500 turbofan engine, ending the airliner sales prospects for the PW–Allison 578-DX propfan. [41] Allison acknowledged that the higher price of its propfan, which some estimated to have a cost of US$4 million (or 40 percent higher than existing turbofan engines), would be unattractive to airline customers at the low fuel prices of the time. It also said that it would not perform any more flight tests of its propfan, preferring to study the data from the flight tests previously done on the MD-80. [42]

Military proposals

Allison's engine was also being examined by the military for airlift and reconnaissance aircraft, [17] and it was offered unsuccessfully for some military aircraft applications. As of early 1988, the Allison 578-D engine was the base powerplant for the Future International Military/Civil Airlifter (FIMA) consortium, [43] which intended to build a replacement military transport aircraft for the Lockheed C-130 Hercules and the French-German Transall C-160 for American and western European military airfleets. The FIMA engine would be smaller than the demonstrator engine, as its contra-rotating propellers would have only four blades in front and four blades in back, and it would generate 8,800 hp (6,600 kW). [44] The aircraft would fly at Mach 0.72 and operate from 2,000 to 3,000 ft (610 to 910 m) runway strips. [43]

Design

The propfan engine had 11.6 ft diameter (3.5 m; 139 in; 350 cm) coaxial contra-rotating propellers, with the front and back propellers (supplied by Hamilton Standard) each containing six blades [11] of 4.35 ft (1.33 m; 52.2 in; 133 cm) in length. [45] The propellers had a recommended tip speed of 750 feet per second (230 metres per second; 510 miles per hour; 820 kilometres per hour), [46] and the engine could support a maximum aircraft flight speed of Mach 0.80–0.82. [47] 44 percent of the engine's torque would be handled by the front propeller, while the other 56 percent would be absorbed by the back propeller. [48] The hot gas exhaust contributes just two to three percent of the total thrust. [49] The 578-DX engine was longer and thinner than the competing GE36 UDF engine. [50]

A closeup of the PW-Allison 578-DX propfan demonstrator, installed on the port side of a McDonnell Douglas MD-80 testbed. 578-DX (on testbed).png
A closeup of the PW–Allison 578-DX propfan demonstrator, installed on the port side of a McDonnell Douglas MD-80 testbed.

Origin

The design adopted many aspects of the Allison 501-M78 single-rotation propfan engine, a single-rotation, 9 ft diameter (2.7 m; 110 in; 270 cm) powerplant being prepared for flight testing on a Gulfstream II business jet. [51] The 501-M78 was an experimental engine that Allison was developing since 1984 as part of the NASA Propfan Test Assessment (PTA). [52] It was a variant of the Allison T701 heavy lift helicopter turboshaft engine, [4] which produced 8,079 shp (6,025 kW) and was also known as the Allison 501-M62B. [53] The T701 was to power the Boeing Vertol XCH-62 helicopter, but after the XCH-62 was abandoned, the engine technology was redirected in 1976 toward an industrial gas turbine, which debuted in 1979 as the Allison 570-K. [54] The 578-DX was derived from the Allison 571, [12] a variant of the Allison 570 that entered service in 1985. [55] There was much commonality in the participants of both engines: in addition to Allison supplying both of the engine cores, the PTA engine also used propellers designed by Hamilton Standard, and both the 501-M78 and the 578-DX had nacelles built by Rohr Industries. This arrangement facilitated the technology transfer from the 501-M78 to the 578-DX. [56] In addition, the blades and the coaxial propellers on the 578-DX were inspired by the SR-7 single-rotation fan on the 501-M78 and the NASA-studied CRP-X1, [57] a 2 ft contra-rotating (0.61 m; 24 in; 61 cm) model propfan with a 5x5 blade configuration. [58]

Gearbox

Unlike the GE36, the 578-DX was fairly conventional, having a reduction gearbox between the low-pressure turbine and the propfan blades, which was thought to give a fuel efficiency advantage of seven percent against the GE36, according to McDonnell Douglas. [59] Allison, which developed the gearbox, [34] claimed a fuel savings of ten percent and the elimination of 1,000 turbine blades. [60] The demonstrator engines produced 10,400 horsepower (7,800 kilowatts), [21] generating a thrust of 21,000 pounds-force (93 kilonewtons). [32] The gearbox would have a reduction ratio of 8.33 to 1, [46] and it would be in service to an airline for 30,000 flight hours (ten years) before requiring a major overhaul, [61] which bettered the mean time between removals (MTBR) of 8,000 flight hours for the Allison T56 turboprop, Allison's top-performing gearbox. The new gearbox, which the propfan developers said had only 15 major parts and was technologically simple, [62] would provide accessory access without having to remove the engine or gearbox, since half of the removals on the T56 historically were caused by failures of accessories. [4] Instead of the six accessory drives used on the T56, the PW-Allison propfan would have no more than two accessory drives. [63] The design was also aided by a study funded by NASA and Allison to develop a 13,000 shaft hp (9,700 kW) contra-rotating gearbox. [64] [4]

Variants

Pratt & Whitney and Allison planned to offer their propfan in three different production models: the 578-D, which produced 11,800 hp (8,800 kW), climbed at an overall pressure ratio (OPR) of 23.4, and had a combustor exit temperature (CET) of 2,230 °F (1,220 °C; 2,690 °R; 1,490 K); the 578-E, a 13,500 hp (10,100 kW) model with a climb OPR of 31.3 and a CET of 2,390 °F (1,310 °C; 2,850 °R; 1,580 K); [63] and the 578-F, the most powerful engine at 16,000 hp (12,000 kW), [65] climbing at OPR 31.3 and with a CET of 2,535 °F (1,391 °C; 2,995 °R; 1,664 K). [63] The 578-DX demonstrator engine did not completely reflect the design of the planned production models. For example, the 578-DX expels its hot exhaust gases forward of the propfan blades, [66] initially requiring the use of heat-resistant blade materials to withstand the 500 °F (260 °C) exhaust stream, [21] but the production engine design was modified to release the gases at the back of the engine to prevent the blades from heating up. [12]

Engines on display

The 578-DX demonstrator engines are on public display at the following museums:

Specifications

General characteristics

Components

Performance

See also

Related development

Comparable engines

Related lists

Related Research Articles

<span class="mw-page-title-main">Propfan</span> Type of aircraft engine

A propfan, also called an open rotor engine, open fan engine or unducted fan, is a type of aircraft engine related in concept to both the turboprop and turbofan, but distinct from both. The design is intended to offer the speed and performance of a turbofan, with the fuel economy of a turboprop. A propfan is typically designed with a large number of short, highly twisted blades, similar to the (ducted) fan in a turbofan engine. For this reason, the propfan has been variously described as an "unducted fan" (UDF) or an "ultra-high-bypass (UHB) turbofan".

<span class="mw-page-title-main">Rolls-Royce T406</span> Rolls-Royce North America turboshaft aircraft engine (1986)

The Rolls-Royce T406 is a turboshaft engine that powers the Bell Boeing V-22 Osprey tiltrotor. The engine delivers 6,000 shp (4,470 kW).

<span class="mw-page-title-main">Europrop TP400</span> Military turboprop engine

The Europrop International TP400-D6 is an 11,000 shp (8,200 kW) powerplant, developed and produced by Europrop International for the Airbus A400M Atlas military transport aircraft. The TP400 is the most powerful turboprop in service using a single propeller; only the Kuznetsov NK-12 from Russia and Progress D-27 from Ukraine, using contra-rotating propellers, is larger.

<span class="mw-page-title-main">Rolls-Royce AE 2100</span> Turboprop aircraft engine family

The Rolls-Royce AE 2100 is a turboprop developed by Allison Engine Company, now part of Rolls-Royce North America. The engine was originally known as the GMA 2100, when Allison was a division of former corporate parent General Motors.

<span class="mw-page-title-main">Boeing 7J7</span> Proposed short to medium range airliner that would have succeeded the 727

The Boeing 7J7 was an American short- to medium-range airliner proposed by American aircraft manufacturer Boeing in the 1980s. It would have carried 150 passengers and was touted as the successor to the successful Boeing 727. It was initially planned to enter service in 1992. This was intended as a highly fuel-efficient aircraft employing new technologies, but it was postponed indefinitely as the price of oil dropped during the 1980s.

<span class="mw-page-title-main">Pratt & Whitney Canada PW100</span> Aircraft engine family

The Pratt & Whitney Canada PW100 aircraft engine family is a series of 1,800 to 5,000 shaft horsepower turboprops manufactured by Pratt & Whitney Canada. Pratt & Whitney Canada dominates the turboprops market with 89% of the turboprop regional airliner installed base in 2016, leading GE Aviation and Allison Engine Company.

<span class="mw-page-title-main">McDonnell Douglas MD-94X</span> Proposal for a propfan-powered airliner

The McDonnell Douglas MD-94X was a planned propfan-powered airliner, intended to begin production in 1994. Announced in January 1986, the aircraft was to seat between 160 and 180 passengers, possibly using a twin-aisle configuration. An all-new design that was investigated internally since at least 1984, the MD-94X was developed in the mid-1980s to compete with the similar Boeing 7J7. The price of oil would have to be at least US$1.40 per gallon for McDonnell Douglas to build the plane, though. Configuration was similar to the MD-80, but advanced technologies such as canard noseplanes, laminar and turbulent boundary layer control, side-stick flight control, and aluminum-lithium alloy construction were under consideration. Airline interest in the brand-new propfan technology was weak despite claims of up to a 60% reduction in fuel use, and both aircraft were canceled.

<span class="mw-page-title-main">Allison T56</span> American-built military turboprop (1954–)

The Allison T56 is an American single-shaft, modular design military turboprop with a 14-stage axial flow compressor driven by a four-stage turbine. It was originally developed by the Allison Engine Company for the Lockheed C-130 Hercules transport entering production in 1954. It has been a Rolls-Royce product since 1995 when Allison was acquired by Rolls-Royce. The commercial version is designated 501-D. Over 18,000 engines have been produced since 1954, logging over 200 million flying hours.

<span class="mw-page-title-main">General Electric GE36</span> US experimental propfan

The General Electric GE36 was an experimental aircraft engine, a hybrid between a turbofan and a turboprop, known as an unducted fan (UDF) or propfan. The GE36 was developed by General Electric Aircraft Engines, with its CFM International equal partner Snecma taking a 35 percent share of development. Development was cancelled in 1989.

IAE International Aero Engines AG is a Zürich-registered joint venture aeroengine manufacturing company.

The Yakovlev Yak-46 was a proposed aircraft design based on the Yak-42 with two contra-rotating propellers on the propfan located at the rear. The specification of the Samara turbofans was in the 11,000 kg thrust range. Though proposed in the 1990s, production of the Yak-46 never commenced.

<span class="mw-page-title-main">Progress D-27</span> Propfan engine

The Progress D-27 is a three-shaft propfan engine developed by Ivchenko Progress, and manufactured by Motor Sich in Ukraine. The gas generator was designed using experience from the Lotarev D-36 turbofan. The D-27 engine was designed to power more-efficient passenger aircraft such as the abandoned Yakovlev Yak-46 project, and it was chosen for the Antonov An-70 military transport aircraft. As of 2019, the D-27 is the only contra-rotating propfan engine to enter service.

<span class="mw-page-title-main">General Electric GE38</span> Gas turbine

The General Electric GE38 is a gas turbine developed by GE Aviation for turboprop and turboshaft applications. It powers the Sikorsky CH-53K King Stallion as the T408.

<span class="mw-page-title-main">Garrett TPF351</span> 1980s American turboprop engine

The Garrett TPF351 is a turboprop engine designed by Garrett Engine Division of AlliedSignal Aerospace Company. Initiated by Garrett in October 1987, the TPF351-20 engine was selected by Embraer to power the Embraer/FMA CBA 123 Vector, a high-speed commuter "pusher" aircraft. It was first tested on May 19, 1989 and then ground tested and flight tested on a Boeing 720 on July 9, 1990. The first prototype CBA 123 was tested on July 18, 1990, followed by a flight to the Farnborough Air Show in September of the same year. Both programs were cancelled in 1992, when the TPF351 was nine months from engine certification.

The Rolls-Royce RB3011 is a prototype propfan engine in development by Rolls-Royce plc. The design is also known as an "open rotor" engine.

MPC 75 was an aircraft project of MPC Aircraft GmbH, a subsidiary of Deutsche Airbus. Work on the project was done mainly between 1988 and 1992 in Hamburg, Germany. Predevelopment work was finished, however the project never got the "go ahead" and never made it into full development.

The IAE V2500SF SuperFan was a design study for a high-bypass geared turbofan derived from the IAE V2500. It was offered as the primary engine option for the Airbus A340 in January 1987. Although several customers signed preliminary contracts for this variant, the International Aero Engines board decided in April 1987 to stop the development of the SuperFan, which forced Airbus to partly re-design the A340.

<span class="mw-page-title-main">Progress D-236</span> Propfan engine

The Progress D-236 was an experimental aircraft engine, a hybrid between a turbofan and a turboprop known as a propfan. Also known as the Lotarev D-236T, the three-shaft geared engine was designed in the 1980s and 1990s to power proposed propfan aircraft such as the Tupolev Tu-334, Ilyushin Il-118, and Ilyushin Il-88.

<span class="mw-page-title-main">Kuznetsov NK-93</span> 1980s Soviet propfan aircraft engine

The Kuznetsov NK-93 was a civilian aircraft engine, a hybrid between a turbofan and a turboprop known as a propfan. The engine was also unique in having a separate duct around the contra-rotating propellers, as most other propfans are unducted. Once described in a respected aviation encyclopedia as "potentially the most fuel-efficient aircraft jet engine ever to be tested", the NK-93 was targeted for derivatives of Soviet/Russian airliners such as the Ilyushin Il-96, Tupolev Tu-204, and Tupolev Tu-330. Five in-flight engine tests were conducted on the NK-93 from December 2006 to December 2008.

<span class="mw-page-title-main">Allison T56 variants</span> Range of American turboprop aircraft engines

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.

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