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Soloviev D-30

December 31, 2022

The Soloviev D-30 (now the Aviadvigatel PS-30) is a Soviet two-shaft low-bypass turbofan engine, officially referred to as a "bypass turbojet". It is probably the single most important turbofan engine developed in the Soviet Union. Development of the turbofan spurred numerous growth versions with increased fan diameter and modified component arrangements. Developed within an amazingly short period of time (about three years), the D-30 turned out to be one of the most reliable engines in the history of Soviet engine development, and it was recognized with the USSR State Prize.[1]

D-30
Type Turbofan
National origin Soviet Union
Manufacturer Soloviev Design Bureau
First run 1963
Major applications Tupolev Tu-134
Tupolev Tu-154
Mikoyan MiG-31
Ilyushin Il-76
Ilyushin Il-62
Sukhoi Su-47
Developed into Soloviev D-30K

Design and development

The original version of the Soloviev D-30 was developed specifically to power the Tupolev Tu-134 short-to-medium range jet airliner; however, it also served as a base for the development of a family of advanced engines. Engine development was started in the early 60s. Nevertheless, by 1966, the engine was put into serial production.[1]

The D-30 engine has a two-stage compression spool, a cannular combustion chamber and a 4-stage turbine, and was the first Soviet-built engine to use cooled turbine blades. The turbine was manufactured using the newest heat-resistant material of the time, along with an exhaust nozzle with a lobe mixer. The technical and efficiency parameters of the D-30 were competitive and similar to those of the Western engines of that period.[1]

In 1969, an upgraded version, the D-30 engine series II, was created - the main difference being the addition of a thrust reverser and an improved control system. The engine was produced in 1970 through 1987 and was used on the Tu-134FA, Tu-134B, and Tu-134AK aircraft.[1]

In 1980, the D-30 engine series III, a further improvement, was created with the maximum thrust of 6930 kgf (with preserving it at up to до = +C). The number of the engine compressor stages was increased to 5, the gas dynamic stability margin was improved, the system was introduced that protected against engine over-speed and gas temperature overheating. The D-30 engine of the third series was produced between 1983-1993. These engines were installed on the Tu-134-A-3, Tu-134B-3, and Tu-134UB-L passenger airliners. The core of the third-series D-30 was also taken as a base point for developing gas turbine plants for the Russian fuel and energy complex.[1]

The Soloviev D-30 was produced in various modifications at the Perm Engine Plant (now JSC UEC-PM). In total, there were about 3000 units of D-30 engines (series I to III) manufactured in this engine plant.[1]

Variants

D-30KU

The D-30KU engine is capable of generating 11,000 kgf at takeoff and was developed in 1971 to replace the Kuznetsov NK-8-4 engine on the Il-62 long-haul airliner, which had some difficulties covering intercontinental routes because of its inadequate range. Ilyushin Design Bureau, the aircraft designer, made the decision to power the aircraft with newer engines which have lower specific fuel consumption. In contrast with the base D-30, the D-30KU has increased bypass ratio and higher turbine inlet temperature: its development was comparable to Pratt & Whitney's development of the Pratt & Whitney JT8D-200 series, but with an even greater increase in thrust. The first compressor spool has 3 stages, the second one has 11 stages, the design of the combustion chamber is however similar to that of D-30. The turbine hot section has a total of 6 stages, the nozzle is common for both flows and has a lobe mixer and a mixing chamber. The D-30KU engine was the first aviation engine in the USSR to include a bucket-type thrust reverser. The Il-62M aircraft equipped with D-30KU had a range extended by 1500 km, compared with the basic model equipped with NK-8-4 engines. A total of 1584 D-30KU engines were manufactured by Rybinsk Engine Plant (now PAO NPO UEC-Saturn) under the authorized supervision of the Perm Design Bureau.[2]

D-30KP

Similar to the D-30KU, a new engine variant called D-30KP which delivered 12,000 kgf of thrust was developed for military transport aircraft Il-76. The development was completed by the end of the 60s. In 1971, Il-76MD with the propulsion unit on the basis of four D-30KP was demonstrated to the country’s leaders. In 1972, engine passed certification tests and then was presented to the public at the next international air show in Le Bourget (France). By 1974 the engine was put into service to power not only military Il-76 itself, but also numerous modifications: tanker plane Il-78, “aircraft-hospital” Il-76MD Scalpel, early warning and control aircraft A-50, weightlessness simulator Il-76K, airborne test rig Il-76LL for in-flight tests of the aircraft engines and others. D-30KP was identical to its predecessor D-30KU - both are low bypass turbofan engines. The engine differs only by having a higher gas temperature at the turbine inlet and an increased compressor pressure ratio and bypass ratio. Powered by four D-30KP engines, Il-76 is capable of lifting a payload of 40 tons (88,000 lb) over a range of 5,000 km (2,700 nmi; 3,100 mi) at cruise speed up to 900 km/ hr. D-30KP engines were manufactured in the city of Rybinsk (Yaroslavl region) at Rybinsk Engine Production Plant (now NPO UEC-Saturn). The D-30KP engines production continues till present for military supplies. More than 4700 D-30KP engines have been manufactured in total.[3]

The Chinese Xi'an Y-20 prototype was also powered by four D-30KP-2 engines.[4]

D-30KU-154

The successful replacement of the engines on long-haul Il-62 stimulated the leaders of the Ministry of Aviation Industry in the Soviets to re-engine another popular aircraft – the medium-haul passenger airliner Tu-154. Ultimately, Tu-154M powered by D-30KU-154 was the backbone of the civil aviation industry in the Soviets till the end of the 20th century. The D-30KU-154 engine was developed with a maximum thrust of 10,500 kgf specifically to power the Tu-154. Development started in 1979. Pavel Solovyov used the D-30KU core as a starting point. In the course of designing the D-30KU-154 engine, some of the systems were improved, new components were added, and in 1984 the new engine entered serial production. The replacement of Kuznetsov NK-8 engine with the D-30KU-154 engine on Tu-154 allowed the reduction the fuel consumption by 28%![5] This ultimately defined the profitability of the air transportations industry in the Soviets for another 15 years. During the years of active operation of D-30KU-154, the manufacturer, Perm design bureau, continued working on improving the engine. A vivid example of that is the development of the noise suppression system with noise-absorbing structures from polymer composite materials. There were in total more than 1500 D-30KU-154 engines manufactured by Rybinsk Engine Plant (now NPO UEC-Saturn).[5]

D-30F-6

In the mid-1970s, the Soviet Union began the search for a high-speed interceptor to supplement and replace its MiG-25. The MiG-25 had two enormously powerful Tumansky R-15 turbojets, allowing Mach 3 speed at high altitudes, but the problem was their weak performance at low altitudes, not even sufficient to cross Mach 1 boundary.[citation needed] More acute problems stemmed from the tendency of the Foxbat's engines to break down at maximum throttle in high-speed situations. A new engine, this time a low-bypass turbofan, was needed to power the new interceptor. The Mikoyan-Gurevich (MiG) design bureau contracted OKB-19 design bureau (now part of Aviadvigatel) to build such an engine, for the aircraft that would become known as the MiG-31.

The Soloviev design bureau came up with the D-30F6 turbofan. Capable of generating 9,500 kgf (20,900 lbf or 93 kN) dry thrust and 15,500 kgf (34,200 lbf or 152 kN) afterburning thrust, the engine gave MiG's new interceptor a top speed exceeding 3,000 km/h (1,900 mph),[citation needed] and a maximum takeoff weight of 45,800 kg (101,000 lb). These powerful engines also allowed the large and complex interceptor to attain supersonic speeds at low altitudes under 1,500 m (4,900 ft). Data from: Aircraft engines of the World 1970,[6] Jane's all the World's Aircraft 1993–94[7]

Other Variants
D-30V12
High-altitude version for the Myasishchev M-55 de-rated to 49 kN (11,000 lbf)[8]
D-30F11
Engine for experimental twin-engine S-37 (Su-47) prototype[8]
D-21A1
Another variant of the two-spool engine with supersonic nozzle intended to power high-altitude supersonic business-jet S-21 from Sukhoi design bureau. Construction scheme is almost the same as for D-30F6 except for the absence of afterburner chamber.[8]
WS-18
Chinese reverse engineered copy of imported D-30KP-2.[9]

Applications

Specifications

 
A Soloviev D-30 II
Model D-30 II D-30KU-154 D-30KP-2
Compressor[10][11] Axial fan, 4-stage LP compressor, 10-stage HP compressor Axial fan, 3-stage LP compressor, 11-stage HP compressor Axial fan, 3-stage LP compressor, 11-stage HP compressor
Combustor[10][1] Cannular with 12 flame tubes
Turbine[10][11][12] 2-stage HP turbine, 2-stage LP turbine 2-stage HP turbine, 4-stage LP turbine 2-stage HP turbine, 4-stage LP turbine
Thrust 66.68 kN (14,990 lbf) 103.02 kN (23,160 lbf) 117.68 kN (26,460 lbf)
Dry Weight 1,546 kg (3,408 lb)[1] 2,305 kg (5,082 lb)[5] 2,640 kg (5,820 lb)(with reverser)[3]
Thrust-to-weight ratio 4.45 4.56 5.21
Length[12] 3,983 mm (156.8 in)[1] 5,698 mm (224.3 in)(with reverser) 5,448 mm (214.5 in)(with reverser)
Specific fuel consumption (Cruise)(kg/kgf hr)[12] 0.781[1] 0.705 0.715
Fan Diameter 963 mm (38 in)[1] 1,455 mm (57 in)[13] 1,455 mm (57 in)[3]
Bypass ratio[12][1] 1:1 2.50:1 2.24:1
Overall pressure ratio[10] 18.6 17.1[14] 20.1[11]
Turbine inlet temperature (K) 1360[1] 1336[5] 1427[3]

See also

Comparable engines

Related lists

References

  1. ^ a b c d e f g h i j k l m "D-30". Avid.ru. Retrieved 2019-11-19.
  2. ^ "D-30KU". Avid.ru. Retrieved 2019-11-19.
  3. ^ a b c d "D-30KP". Avid.ru. Retrieved 2019-11-19.
  4. ^ Fisher, Richard D Jr (4 September 2014). "China's Y-20 'enters second phase of testing'". IHS Jane's 360. Retrieved 5 May 2015.
  5. ^ a b c d "D-30KU-154". Avid.ru. Retrieved 2019-11-19.
  6. ^ Wilkinson, Paul H. (1970). Aircraft engines of the World 1970 (22nd ed.). London: Paul H. Wilkinson. p. 224.
  7. ^ Taylor, Michael J.H.; Lambert, Mark; Munson, Kenneth, eds. (1993). Jane's all the World's Aircraft 1993–94 (84th ed.). Coulson, Surrey, UK: Jane's Information Group. p. 633. ISBN 978-0710610669.
  8. ^ a b c "D-30F6". LeteckeMotory.cz. Retrieved 2019-11-19.
  9. ^ "The turbofan-18 engine has been mass produced and delivered, and the H-6 and Yun-20 will get rid of imported engines". daydaynews. 7 March 2020. Retrieved 2022-04-19.
  10. ^ a b c d "data" (PDF). www.flightglobal.com. Retrieved 2019-11-19.
  11. ^ a b c "data" (PDF). www.flightglobal.com. Retrieved 2019-11-19.
  12. ^ a b c d . Npo-saturn.ru. Archived from the original on 2020-09-28. Retrieved 2019-11-19.
  13. ^ "Butterworth-Heinemann - Civil Jet Aircraft Design - Engine Data File - Miscellaneous Engines". Booksite.elsevier.com. Retrieved 2019-11-19.
  14. ^ Stephen Payne. . Parts.jspayne.com. Archived from the original on 2020-09-26. Retrieved 2019-11-19.

External links

 
Wikimedia Commons has media related to Soloviev D-30.
  • D-30F6 description at manufacturer's site

December 31, 2022
soloviev, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, december, 2009, l. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Soloviev D 30 news newspapers books scholar JSTOR December 2009 Learn how and when to remove this template message The Soloviev D 30 now the Aviadvigatel PS 30 is a Soviet two shaft low bypass turbofan engine officially referred to as a bypass turbojet It is probably the single most important turbofan engine developed in the Soviet Union Development of the turbofan spurred numerous growth versions with increased fan diameter and modified component arrangements Developed within an amazingly short period of time about three years the D 30 turned out to be one of the most reliable engines in the history of Soviet engine development and it was recognized with the USSR State Prize 1 D 30Type TurbofanNational origin Soviet UnionManufacturer Soloviev Design BureauFirst run 1963Major applications Tupolev Tu 134Tupolev Tu 154Mikoyan MiG 31Ilyushin Il 76Ilyushin Il 62Sukhoi Su 47Developed into Soloviev D 30K Contents 1 Design and development 2 Variants 3 Applications 4 Specifications 5 See also 6 References 7 External linksDesign and development EditThe original version of the Soloviev D 30 was developed specifically to power the Tupolev Tu 134 short to medium range jet airliner however it also served as a base for the development of a family of advanced engines Engine development was started in the early 60s Nevertheless by 1966 the engine was put into serial production 1 The D 30 engine has a two stage compression spool a cannular combustion chamber and a 4 stage turbine and was the first Soviet built engine to use cooled turbine blades The turbine was manufactured using the newest heat resistant material of the time along with an exhaust nozzle with a lobe mixer The technical and efficiency parameters of the D 30 were competitive and similar to those of the Western engines of that period 1 In 1969 an upgraded version the D 30 engine series II was created the main difference being the addition of a thrust reverser and an improved control system The engine was produced in 1970 through 1987 and was used on the Tu 134FA Tu 134B and Tu 134AK aircraft 1 In 1980 the D 30 engine series III a further improvement was created with the maximum thrust of 6930 kgf with preserving it at up to do C The number of the engine compressor stages was increased to 5 the gas dynamic stability margin was improved the system was introduced that protected against engine over speed and gas temperature overheating The D 30 engine of the third series was produced between 1983 1993 These engines were installed on the Tu 134 A 3 Tu 134B 3 and Tu 134UB L passenger airliners The core of the third series D 30 was also taken as a base point for developing gas turbine plants for the Russian fuel and energy complex 1 The Soloviev D 30 was produced in various modifications at the Perm Engine Plant now JSC UEC PM In total there were about 3000 units of D 30 engines series I to III manufactured in this engine plant 1 Variants EditD 30KUThe D 30KU engine is capable of generating 11 000 kgf at takeoff and was developed in 1971 to replace the Kuznetsov NK 8 4 engine on the Il 62 long haul airliner which had some difficulties covering intercontinental routes because of its inadequate range Ilyushin Design Bureau the aircraft designer made the decision to power the aircraft with newer engines which have lower specific fuel consumption In contrast with the base D 30 the D 30KU has increased bypass ratio and higher turbine inlet temperature its development was comparable to Pratt amp Whitney s development of the Pratt amp Whitney JT8D 200 series but with an even greater increase in thrust The first compressor spool has 3 stages the second one has 11 stages the design of the combustion chamber is however similar to that of D 30 The turbine hot section has a total of 6 stages the nozzle is common for both flows and has a lobe mixer and a mixing chamber The D 30KU engine was the first aviation engine in the USSR to include a bucket type thrust reverser The Il 62M aircraft equipped with D 30KU had a range extended by 1500 km compared with the basic model equipped with NK 8 4 engines A total of 1584 D 30KU engines were manufactured by Rybinsk Engine Plant now PAO NPO UEC Saturn under the authorized supervision of the Perm Design Bureau 2 D 30KPSimilar to the D 30KU a new engine variant called D 30KP which delivered 12 000 kgf of thrust was developed for military transport aircraft Il 76 The development was completed by the end of the 60s In 1971 Il 76MD with the propulsion unit on the basis of four D 30KP was demonstrated to the country s leaders In 1972 engine passed certification tests and then was presented to the public at the next international air show in Le Bourget France By 1974 the engine was put into service to power not only military Il 76 itself but also numerous modifications tanker plane Il 78 aircraft hospital Il 76MD Scalpel early warning and control aircraft A 50 weightlessness simulator Il 76K airborne test rig Il 76LL for in flight tests of the aircraft engines and others D 30KP was identical to its predecessor D 30KU both are low bypass turbofan engines The engine differs only by having a higher gas temperature at the turbine inlet and an increased compressor pressure ratio and bypass ratio Powered by four D 30KP engines Il 76 is capable of lifting a payload of 40 tons 88 000 lb over a range of 5 000 km 2 700 nmi 3 100 mi at cruise speed up to 900 km hr D 30KP engines were manufactured in the city of Rybinsk Yaroslavl region at Rybinsk Engine Production Plant now NPO UEC Saturn The D 30KP engines production continues till present for military supplies More than 4700 D 30KP engines have been manufactured in total 3 The Chinese Xi an Y 20 prototype was also powered by four D 30KP 2 engines 4 D 30KU 154The successful replacement of the engines on long haul Il 62 stimulated the leaders of the Ministry of Aviation Industry in the Soviets to re engine another popular aircraft the medium haul passenger airliner Tu 154 Ultimately Tu 154M powered by D 30KU 154 was the backbone of the civil aviation industry in the Soviets till the end of the 20th century The D 30KU 154 engine was developed with a maximum thrust of 10 500 kgf specifically to power the Tu 154 Development started in 1979 Pavel Solovyov used the D 30KU core as a starting point In the course of designing the D 30KU 154 engine some of the systems were improved new components were added and in 1984 the new engine entered serial production The replacement of Kuznetsov NK 8 engine with the D 30KU 154 engine on Tu 154 allowed the reduction the fuel consumption by 28 5 This ultimately defined the profitability of the air transportations industry in the Soviets for another 15 years During the years of active operation of D 30KU 154 the manufacturer Perm design bureau continued working on improving the engine A vivid example of that is the development of the noise suppression system with noise absorbing structures from polymer composite materials There were in total more than 1500 D 30KU 154 engines manufactured by Rybinsk Engine Plant now NPO UEC Saturn 5 D 30F 6In the mid 1970s the Soviet Union began the search for a high speed interceptor to supplement and replace its MiG 25 The MiG 25 had two enormously powerful Tumansky R 15 turbojets allowing Mach 3 speed at high altitudes but the problem was their weak performance at low altitudes not even sufficient to cross Mach 1 boundary citation needed More acute problems stemmed from the tendency of the Foxbat s engines to break down at maximum throttle in high speed situations A new engine this time a low bypass turbofan was needed to power the new interceptor The Mikoyan Gurevich MiG design bureau contracted OKB 19 design bureau now part of Aviadvigatel to build such an engine for the aircraft that would become known as the MiG 31 The Soloviev design bureau came up with the D 30F6 turbofan Capable of generating 9 500 kgf 20 900 lbf or 93 kN dry thrust and 15 500 kgf 34 200 lbf or 152 kN afterburning thrust the engine gave MiG s new interceptor a top speed exceeding 3 000 km h 1 900 mph citation needed and a maximum takeoff weight of 45 800 kg 101 000 lb These powerful engines also allowed the large and complex interceptor to attain supersonic speeds at low altitudes under 1 500 m 4 900 ft Data from Aircraft engines of the World 1970 6 Jane s all the World s Aircraft 1993 94 7 Other VariantsD 30V12 High altitude version for the Myasishchev M 55 de rated to 49 kN 11 000 lbf 8 D 30F11 Engine for experimental twin engine S 37 Su 47 prototype 8 D 21A1 Another variant of the two spool engine with supersonic nozzle intended to power high altitude supersonic business jet S 21 from Sukhoi design bureau Construction scheme is almost the same as for D 30F6 except for the absence of afterburner chamber 8 WS 18 Chinese reverse engineered copy of imported D 30KP 2 9 Applications EditIlyushin Il 62 jet airliner Mikoyan Gurevich MiG 31 jet interceptor Sukhoi Su 47 Berkut formerly S 37 demonstrator jet fighter Tupolev Tu 134 jet airliner Tupolev Tu 154 jet airliner Ilyushin Il 76 strategic airlifter Xian H 6 jet bomber WS 18 Xian Y 20 strategic airlifter WS 18 Specifications Edit A Soloviev D 30 II Model D 30 II D 30KU 154 D 30KP 2Compressor 10 11 Axial fan 4 stage LP compressor 10 stage HP compressor Axial fan 3 stage LP compressor 11 stage HP compressor Axial fan 3 stage LP compressor 11 stage HP compressorCombustor 10 1 Cannular with 12 flame tubesTurbine 10 11 12 2 stage HP turbine 2 stage LP turbine 2 stage HP turbine 4 stage LP turbine 2 stage HP turbine 4 stage LP turbineThrust 66 68 kN 14 990 lbf 103 02 kN 23 160 lbf 117 68 kN 26 460 lbf Dry Weight 1 546 kg 3 408 lb 1 2 305 kg 5 082 lb 5 2 640 kg 5 820 lb with reverser 3 Thrust to weight ratio 4 45 4 56 5 21Length 12 3 983 mm 156 8 in 1 5 698 mm 224 3 in with reverser 5 448 mm 214 5 in with reverser Specific fuel consumption Cruise kg kgf hr 12 0 781 1 0 705 0 715Fan Diameter 963 mm 38 in 1 1 455 mm 57 in 13 1 455 mm 57 in 3 Bypass ratio 12 1 1 1 2 50 1 2 24 1Overall pressure ratio 10 18 6 17 1 14 20 1 11 Turbine inlet temperature K 1360 1 1336 5 1427 3 See also EditComparable engines Kuznetsov NK 8 Pratt amp Whitney JT3D Pratt amp Whitney JT8D Rolls Royce SpeyRelated lists List of aircraft enginesReferences Edit a b c d e f g h i j k l m D 30 Avid ru Retrieved 2019 11 19 D 30KU Avid ru Retrieved 2019 11 19 a b c d D 30KP Avid ru Retrieved 2019 11 19 Fisher Richard D Jr 4 September 2014 China s Y 20 enters second phase of testing IHS Jane s 360 Retrieved 5 May 2015 a b c d D 30KU 154 Avid ru Retrieved 2019 11 19 Wilkinson Paul H 1970 Aircraft engines of the World 1970 22nd ed London Paul H Wilkinson p 224 Taylor Michael J H Lambert Mark Munson Kenneth eds 1993 Jane s all the World s Aircraft 1993 94 84th ed Coulson Surrey UK Jane s Information Group p 633 ISBN 978 0710610669 a b c D 30F6 LeteckeMotory cz Retrieved 2019 11 19 The turbofan 18 engine has been mass produced and delivered and the H 6 and Yun 20 will get rid of imported engines daydaynews 7 March 2020 Retrieved 2022 04 19 a b c d data PDF www flightglobal com Retrieved 2019 11 19 a b c data PDF www flightglobal com Retrieved 2019 11 19 a b c d D 30KU KP UEC SATURN Npo saturn ru Archived from the original on 2020 09 28 Retrieved 2019 11 19 Butterworth Heinemann Civil Jet Aircraft Design Engine Data File Miscellaneous Engines Booksite elsevier com Retrieved 2019 11 19 Stephen Payne Soloviev D 30 Parts jspayne com Archived from the original on 2020 09 26 Retrieved 2019 11 19 External links Edit Wikimedia Commons has media related to Soloviev D 30 D 30F6 description at manufacturer s site Retrieved from https en wikipedia org w index php title Soloviev D 30 amp oldid 1123956498, wikipedia, wiki, book, books, library,

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