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Comac C929

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CR929
Role Long-range wide-body airliner
National origin China, Russia
Manufacturer CRAIC (Comac - UAC JV)
First flight 2025 (projected)[1]
Introduction 2027 (projected)[1]
Status Joint-Venture established[2]

The CRAIC CR929 (UAC: LRWBCA[3]), formerly known as Comac C929, is a planned long-range 250-to-320-seat wide-body twinjet airliner family to be developed by CRAIC, a joint-venture between Chinese Comac and Russian United Aircraft Corporation (UAC), to challenge the Airbus and Boeing duopoly.

Development

In June 2011, Comac was studying the 290-seat C929 and 390-seat C939 wide-body aircraft.[4] In June 2012, after assessing demand, Russia and China were to set up a joint venture between UAC and Comac to develop a successor to the Il-96. Development was expected to take at least seven years and cost $7–12 billion, with target production of several hundred aircraft. Russia would contribute its knowledge and China would provide the resources.[5]

In May 2014, a memorandum on cooperation was reached and a feasibility study completed in autumn 2014. UAC estimated that wide-body demand worldwide through 2033 amounts to 8,000 aircraft, including 1,000 in China. In November 2014, UAC suggested a range of 12,000 km (6,500 nmi) range while Comac pointed to a gap in the market for a moderate range of 7,400 km (4,000 nmi); initial capacity was targeted for 250-280 seats with later shrink and stretch. In February 2015 preliminary design had begun. A nine-year, $13 billion development program was expected to be launched in 2016, targeting a 2025 introduction. Comac was expected to develop and build the fuselage while UAC handles the composite wing and fin.[6]

In June 2015, an agreement targeted a mid-2021 first flight, with certification and initial deliveries in 2024. The airframe would be 50% composite and 15% titanium; UAC would deliver the first composite wings in 2019–2020.[7] In November 2015, a more fuel-efficient, re-engined version of the Ilyushin IL-96-400M was announced as a more attainable and affordable alternative.[8]

In June 2016, an agreement was signed to set up a 50-50 joint venture.[9] In November 2016, at Zhuhai Airshow, Comac and UAC searched for suppliers and approached Honeywell and United Technologies.[10] A mock-up was exhibited at the show.[11] Comac and UAC estimated the development at 10 years, implying a first delivery in 2027 if the joint company was established and the program launched in 2017.[12]

CRAIC joint venture

The China-Russia Commercial Aircraft International Corporation Limited (CRAIC) 50-50 joint venture was launched on May 22, 2017 in Shanghai, targeting a 2025-2028 maiden flight and first delivery. It aims to take 10% of a market dominated by Boeing and Airbus of 9,100 widebodies over 20 years through 2035, with a plane 10-15% cheaper to run.[2] Based in Shanghai where the assembly line will be located, CRAIC will oversee the program : technology development, manufacturing, marketing, sales, customer services, and program management. The fuselage will be aluminium, total investment will be $13–20 billion.[13]

Seating : 1-2-1 in First, 2-2-2 in Business and 3-3-3 in Economy

For 2023–45, UAC and Comac forecast a 7,000 widebodies demand for $1.5 trillion - an average of $214 million, their goal for first delivery is 2027. The 280 passengers capacity over 12,000 km is comparable to the Airbus A330-900 but with a nine-abreast economy seating, the shrink would seat 230 while the stretch 320. Major suppliers will be picked among 169 companies by the end of 2018, as detailed design should be completed and a joint engineering center in Moscow with a branch in Shanghai will oversee development, employing around 100 engineers from both countries. Comac's will be in charge of the fuselage sections, horizontal and vertical stabilizers, wing fairings, nose cone and landing gear; UAC will develop the composite wing, wing flap systems, engine pylons and main landing gear, with Chinese manufacture if it is cheaper.[14]

For Russia, "Moscow will provide the know-how and technology, while Beijing will be responsible for the cash".[15] China could see the joint venture involving joint financial investments, rather than an intellectual property sale, as Russia wants with the research and development center in Moscow and the aircraft manufacturing in Shanghai.[16] The main design center is in Russia and Shanghai will also have its own design office, for half of the work each.[17]

In September 2017, it was named CR 929 (CR standing for China-Russia), concept approval was slated for 2017, early configuration and preliminary design for 2018, design documentation for 2021, first flight for 2023 and introduction for 2025. It will be powered by a western engine at first before an indigenous power plant is developed between Russia's United Engine Corporation and China's AECC, to start testing in 2022 and be certificated in 2027.[18]

Preliminary design

Suppliers should be selected by 2018 to mid 2019.[19] A request for proposal for the propulsion system, including the engine and nacelle, have been issued on 21 December 2017, to be answered by 30 May 2018.[20] On May 15 at a Shanghai conference on aeroengines, the design grew to a 63.25 m (207.5 ft) length, 45 cm (18 in) shorter than the A330-900 but still with nine-abreast economy seating, requiring 78,000 lbf (347 kN) of thrust. GE produces the 76,100 lbf (339 kN) GEnx-1B76, and Rolls-Royce the 78,129 lbf (347.54 kN) Trent 1000 TEN.[21] CRAIC received seven proposals by the 30 May deadline.[22] The responding engine manufacturers appears to be Chinese AECC, General Electric, Rolls-Royce and Russian UEC, the three others were for related systems.[23]

2017 mockup

The general layout and principal geometry was approved on 6 June: the wing span and shape, fuselage length, nose and tail dimensions, fins sizing and form, location of engines, landing gear and doors. Within the same Gate 3, which should be completed by mid-2019, are experimental aerodynamics research, structural materials selection and technical analysis of supplied systems and equipment.[24]

Comac plans to start construction in 2021, conduct the first flight in 2023 and make the first delivery in 2025, two years earlier than planned in November 2016. It should be over 50% composite, maintain C919 cockpit commonality and have more electric systems including the environmental control, thrust reversal, braking and flight controls with gusts alleviation.[25] The eight-year schedule could be delayed by multinational management and is shorter than the Sukhoi Superjet 100 which took 11 years or the Comac ARJ21 in 13 years, as the Irkut MC-21 will have in 2020 or the C919 in 2021.[26] For three years from 2018, UAC plans to invest ₽7.25 billion ($115.6 million) for the CR929.[27]

On 31 July 2018 was issued a request for proposals for the undercarriage, expecting a response from Europe, China or Russia by the end of November 2018.[28] Germany's Liebherr makes the C919 landing gear, Safran Landing Systems (formerly Messier-Bugatti-Dowty) supplies the A330 and A350 gear, Russian Hydromash builds the MC-21's, and Avic could bid, though less experienced.[29] The US-China trade war did not prevent bidding from UTC Aerospace Systems, which did not seek the contract and Canadian Héroux-Devtek has not received the RFP.[23] Leonardo-Finmeccanica was negotiating to set up a joint venture with Comac and the Chinese Kangde group before the end of October 2018, to produce the fuselage central section in Zhangjiagang for $10 billion until 2040.[30] Leonardo confirmed the joint venture on 26 October.[31]

In November 2018, a mockup of the forward cabin was unveiled at the Zhuhai Airshow China.[32] CRAIC requested technical and after sales support clarifications from four providers down from seven bids in May: Rolls-Royce, General Electric, UEC and AECC, to be closed by the first quarter of 2019.[33] UAC forecasts 8,000 airplanes worth $2.4 trillion over 20 years, with 20% of the demand from Russia and China, and out of a thousand aircraft, the CR929 may catch half of the sales: 250 in China, 50 in Russia plus from Southeast Asian countries. The program cost is estimated at $13–15 billion by UAC and $20 billion by Comac for a break-even within fifteen years. The vendor selection and draft design should be completed by the end of 2019.[34]

By December 2018, Comac produced the first composite forward fuselage prototype, a 15 by 6 m (49 by 20 ft) structure, towards joint definition in the second half of 2019.[35] By early 2019, Concept design was targeted for the end of 2019/early 2020, before the definition phase. Definition freeze is aimed for the first half of 2022, first flight for 2025 and certification for 2027.[1] By spring 2019, progress was slowed by multinational cooperation challenges and engine selection was expected for September or October.[36] High-speed wind tunnel testing was completed by December 2019 at the Moscow Central Aerohydrodynamic Institute, using a 1:39 scale model of the fuselage and wing.[37]

Design

Three variants are planned: the -500 will carry 250 passengers in three classes with a range of 14,000 km (7,560 nmi), the -600 will have 280 seats and a range of 12,000 km (6,480 nmi) and the -700 will carry 320 over 10,000 km (5,400 nmi).[18] A two class layout of the -600 would seat 291 with 243 economy seats and 48 six-abreast business seats, which can be split in eight four-abreast first class seats and 30 business for a seating of 281 in three classes. With a nine-abreast all-economy, the -600 would accommodate 405 to 440 with a seat pitch of 32 and 30 in (81 and 76 cm), respectively.[32]

The two-crew flightdeck looks like the Comac C919 with a five-screen EFIS and sidestick controls.[38] Composite materials and titanium should account for half of the structural weight.[32]

Engines

A competitive widebody would initially need Western powerplants and onboard systems.[6] The aircraft would need a 77,000–88,000 lbf (340–390 kN) thrust turbofan.[7] Initially, the engine is likely to be supplied by Rolls-Royce or General Electric that already have products in this class.[39] CRAIC expects a TSFC better by at least 10%.[1]

At the November 2014 Zhuhai Airshow, a later high-thrust joint turbofan was discussed between Avic Commercial Aircraft Engines and United Engine Corporation (UEC), with parameters defined in early 2015 for an introduction between 2025 and 2030.[6] In September 2017, a memorandum of understanding was signed between Rostec's UEC and Aero Engine Corporation of China: initially joint research and customer requirements analysis and definition, then determining engine design and operating parameters before testing in 2022 and certification in 2027.[40]

A more powerful version of the Aviadvigatel PD-14 developed for the Irkut MC-21 could be developed after its certification in 2017, with a 50% scaled up core.[7] In May 2016 began the development of a 35 tf (77,000 lbf) Russian engine Aviadvigatel PD-35 for the twinjet, expected to enter service in 2025.[41] A derivative of the Kuznetsov NK-32 PD-30 powering the Tupolev Tu-160 supersonic bomber has also been proposed in August 2015.[42]

China has been working independently on the CJ-2000 engine.[43] It could also use AI-38 engines co-developed by China and Ukrainian Ivchenko-Progress from the 225 kN Progress D-18T of the An-124/An-225.[44] The MoU between Russian UEC and Chinese AECC makes this possibility unlikely.[45]

Specifications

Specifications[46]
Variants CR929-600
Capacity 258-280 (3-class seating)
261-291 (2-class seating)
405-440 (1-class seating)[32]
Length 63.755 m (209.17 ft)[47]
Wingspan 63.86 m (209.5 ft)[47]
Height 17.9 m / 58.7 ft
Fuselage 5.92 m / 19.4 ft (width)
6.07 m / 19.9 ft (height)
Cabin max width 5.61 m / 18.4 ft
MTOW 245 t (540,000 lb)[47]
Payload 48.83–50.4 t (107,700–111,100 lb)
Fuel capacity 103.7 t (229,000 lb)
Turbofans (x2) TBA
Thrust 78,000 lbf (347 kN)[21]
Cruise Mach 0.85 (490 kn; 908 km/h)
Range 12,000 km / 6,480 nmi

See also

Aircraft of comparable role, configuration, and era

Related lists

References

  1. ^ a b c d Mavis Toh (25 Feb 2019). "CR929 boss details progress, timeline". Flightglobal.
  2. ^ a b Brenda Goh (May 22, 2017). "China, Russia set up wide-body jet firm in new challenge to Boeing, Airbus". Reuters.
  3. ^ "China-Russia Commercial Aircraft International Corporation Co., Ltd". UAC. Retrieved 29 January 2019.
  4. ^ "China's Comac Joins Commercial Passenger Plane Industry". The Chosun Ilbo. June 30, 2011.
  5. ^ Tom Zaitsev (1 June 2012). "Russia and China discuss Il-96 successor". Air Transport Intelligence. Flightglobal.
  6. ^ a b c Maxim Pyadushkin and Bradley Perrett (Feb 11, 2015). "Russo-Chinese Widebody Concept Design Underway". Aviation Week & Space Technology.
  7. ^ a b c Vladimir Karnozov (June 11, 2015). "Russia and China Push for Next-Gen Widebody". Aviation International News.
  8. ^ Vladimir Karnozov (February 15, 2016). "Russia Backs UAC to Expand Airliner Product Range". Aviation International News.
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  12. ^ Bradley Perrett. "Comac Foresees A Future Of 'Intelligent Aircraft' May 12, 2017". Aviation Daily. Aviation Week.
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  19. ^ David Kaminski Morrow (22 Dec 2017). "Supplier selection nears for Russian-Chinese CR929". Flightglobal.
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  29. ^ Bradley Perrett (Aug 2, 2018). "CR929 Landing Gear Candidates Revealed". Aviation Week Network.
  30. ^ Gianni Dragoni (9 Oct 2018). "Leonardo in corsa per il maxi-piano cinese di Comac". Il Sole 24 Ore (in Italian).
  31. ^ "Leonardo and Kangde Investment Group of China agree guiding principles to partner on the new COMAC CR929 long range airliner" (PDF) (Press release). Leonardo. 26 October 2018.
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  33. ^ Aaron Chong (6 Nov 2018). "CRAIC seeks more details on CR929 engine submissions". Flightglobal.
  34. ^ Vladimir Karnozov (November 7, 2018). "UAC Head Details CR929 Market Outlook and Timetable". AIN online.
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  38. ^ "Mock-up reveals CR929 cockpit and cabin ideas". Flightglobal. 9 Nov 2018.
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  40. ^ David Kaminski-Morrow (20 Sep 2017). "Russian-Chinese tie-up to develop new long-haul jet engine". Flightglobal.
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