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Dornier Do 31

December 20, 2023

The Dornier Do 31 is an experimental, jet-propelled, vertical take-off and landing (VTOL) cargo aircraft that was designed and produced by West German aircraft manufacturer Dornier.

Do 31
Dornier Do 31 in 1968
Role VTOL transport
Manufacturer Dornier Flugzeugwerke
First flight 10 February 1967
Status Project cancelled in April 1970
Primary user German Air Force
Number built 3
Variants Dornier Do 231

The development of the Do 31 was motivated principally by heavy interest expressed by the German Air Force in the acquisition of short take-off and vertical landing aircraft (STOVL)-capable aircraft. Such ambitions received a further boost from the issuing of NATO specification NBMR-4, which called for a VTOL-capable tactical support aircraft that would be operated in conjunction with the EWR VJ 101, a West German VTOL strike aircraft designed under the NATO contract of BMR-3.[1] A total of three aircraft, two flight-capable and one static airframe, were constructed and used for testing. On 10 February 1967, the Do 31 performed its maiden flight; the first hovering flight of the type took place during July 1967.

In addition to performing test flights, Dornier often demonstrated the Do 31 prototypes to officials and the general public, such as at the 1969 Paris Air Show. Several world records were set by the type during its limited flying career. When the high cost, technical and logistical difficulties of operating such an aircraft were realized, the German Air Force opted to cease trials involving VTOL aircraft, such as the Do 31, VJ101, and the later VFW VAK 191B. In the face of limited sales prospects and a lack of state support, the Do 31 and other VTOL projects lingered as research projects for a time prior to their manufacturers abandoning all activity. The Do 31 remains the only VTOL-capable jet-powered transport aircraft to ever fly.

Design and development edit

Background edit

During the late 1950s and 1960s, the German Air Force became increasingly concerned that, in the event of a major conflict with the Eastern Bloc, its airfields would be highly vulnerable to attack, quickly preventing the use of conventional aircraft in any such conflict. Seeking to counter this threat, the service actively researched the possibility of dispersed operations; one of the options was the use of the nation's Autobahns, which necessitated such aircraft to possess short take-off and vertical landing (STOVL) capabilities.[2] Due to this interest, a series of trials were conducted, which involved the modification of several German Air Force Lockheed F-104 Starfighters so that they could be rocket-launched from stationary ramps; these trials became known as the zero length launch (ZELL) programme. The Starfighters were to be recovered to short strips using aircraft carrier-type arresting gear; similarly, the later Do 31 was intended to use these same austere air strips as forward operating bases.[2]

As early as 1959, West German aircraft manufacturer Dornier had been informally working on several VTOL-related concepts,[3] although it would not be until 1961 that the design team would formalise what would become the Do 31.[4] Early activity centred around a series of studies on the topic of a VTOL-capable utility transport aircraft. Dornier's design team, based at the company's facility in Friedrichshafen, was headed by the aeronautical engineer Gustav Wieland. Already at this stage, Dornier was liaising with foreign companies, including British engine manufacturer Bristol Siddeley, who were independently working on their own VTOL-orientated engine already.[3]

The design of the flight control system was considered to be a critical element of any aircraft performing vertical flight, particularly in how it handled control failures.[5] To support the development programme, a purpose-built flight control test rig was constructed by Dornier, which allowed their design team to explore and evaluate different attitude control laws and flying qualities.[6][7] To solve the differential equations necessary to model the aircraft in detail, the Dornier DO-960 hybrid computer was developed.[8] In spite of allowances to facilitate control during vertical flight, the flight control philosophy used upon the Do 31 was more akin to a conventional aircraft than that of a helicopter.[9]

Programme launch and design edit

 
Fairings at the top of a lift nacelle in the open position

During February 1962, the formal launch of the Do 31 programme occurred with the issuing of a development contract from the West German government.[3] By the start of 1964, Dornier had started building a pair of prototype aircraft; their manufacture was largely performed at the company's Oberpfaffenhofen plant.[10][11] A total of three test prototypes were constructed, these being E1, E2 and E3 - the "E" indicating Experimentell (Experimental). E1 was powered only by the Pegasus engines, having been designed to test horizontal flight. E2 was a static test airframe, and did not ever fly. E3 was furnished with both Pegasus and RB162 lift engines installed, being intended to evaluate the design's vertical flight mode.[citation needed]

 
The four Rolls-Royce RB162 lift engines seen from the bottom of a nacelle

The design of the Do 31 was heavily reliant upon its engine configuration. Dornier had opted to incorporate the British-built Bristol Pegasus[note 1] vectored-thrust turbofan engine, an existing powerplant that was most famously used to power the Harrier jump jet. On the Do 31, a pair of Pegasus engines were housed in each of the two inboard nacelles; during the vertical phase of flight, additional lift was provided by an arrangement of four vertically mounted Rolls-Royce RB162 lift engines located in each of the outer nacelles.[4][12]

 
Cargo area

By mounting the engines in pods, the fuselage could accommodate a capacious hold for storing cargo, which was primarily accessed via a rear-facing loading ramp. Early designs of the Do 31 used more than four Rolls-Royce RB162s; the availability of more powerful versions of the Pegasus engine enabled the reduction to four supplemental lift engines.[13] Due to the engines being placed in nacelles, as opposed to within the fuselage as on the Harrier, the Pegasus had to be specially modified for the Do 31.[14]

 
Pitch control nozzles in the tail, fed from the Pegasus engines, two pointing up, two pointing down

Beyond providing adequate lift and control, other factors influenced the propulsion system. According to Dow, noise was a considerable concern, particularly as the airframe's critical frequency was close to that which was naturally generated by the lift engines.[15] The re-ingestion of hot exhaust gasses was another critical area, complicated by there being 16 'fountains' of gas being generated during vertical hover, 12 of which being hot. Following intense study during the flight testing phase of development, it was determined that positioning the nozzles at an angle of 85-degrees, rather than 90-degrees, was sufficient to avoid encountering any issue during takeoff, while no such issues were observed during landings at all.[16] Several different types of air intakes were also trialled, both to deter ingestion issues and the uneven start-up of the lift engines. Bleed air was also drawn from the Pegasus engines to the lift engines as a measure to address ingestion issues, while dedicated studies were performed on ground erosion effects.[17]

Into flight edit

On 10 February 1967, the first prototype (E1) conducted its maiden flight, powered by just the two Pegasus engines. During July 1967, the third prototype (E3), which was furnished with all ten of its engines, performed the first hovering flight.[4] During December 1967, forward-and-backward transitions between vertical and horizontal phases of flight were successfully conducted. On 28 February 1968, the first flight involving multiple transitions was performed.[4] According to aviation author Andrew Dow, while some initial teething issues were encountered, confidence in the aircraft grew quickly.[18] As the flight envelope was explored, test pilot Drury W. Wood performed several exploratory manoeuvres while flying the Do 31, on one occasion deliberately flying it backwards to prove it could be done and performing a barrel roll on another.[19]

Seeking to garner publicity for its new aircraft, Dornier flew one of the prototypes to the 1969 Paris Air Show, where it was demonstrated to the general public. The ferry flight to reach the event established multiple Fédération Aéronautique Internationale (FAI) world records for the type.[20][21][22][23][24] Public recognition was viewed as particularly valuable in light of Dornier's long-term ambitions for the Do 31, as the company foresaw civilian uses for the aircraft as a commercial VTOL transport.[25] At one point, Dornier was negotiating with both Douglas Aircraft and Ling-Temco-Vought (LTV) for involvement in the Do 31 programme, even rejecting one approach made by Douglas.[26]

 
Model of the unrealised prototype Do 131

The Do 31 was the first, and so far only, vertical takeoff jet transport ever built. During April 1970, it was announced that the project had been terminated, although the Do 31 performed its final public flight on 4 May 1970 during the Internationale Luft- und Raumfahrtausstellung (ILA) in Hannover.[27] One of the alleged contributing factors towards the Do 31's cancellation was the relatively large drag and weight imposed by the lift engine pods, which reduced both the useful payload and range of the type compared to conventional transport aircraft.[citation needed] According to Dow, the German government had been frustrated by a lack of commitment forthcoming from other NATO countries, and was unwilling to contribute alone to the high funding requirement needs for full-scale development.[28]

During a later stage of development, Dornier planned to dispense with the Do 31's outer nacelles and their engines; in their place, larger RB153 turbofan engines, each capable of generating approximately 5,000 lbf (22 kN) of thrust, would have been adopted once this powerplant had become available. A further development of the Do 31, referred to as the Do 131, intended to be powered by either twelve or fourteen liftjets, was also explored by Dornier; however, no prototype of this variant was ever constructed.[29][28]

Aircraft on display edit

 
Do 31 E1 at the Dornier Museum Friedrichshafen
 
Do 31 E3 at the Deutsches Museum Flugwerft Schleissheim

Both flying prototypes have been preserved in Germany, but the fate and current location of the non-flying testbed (E2) is not known.

Operators edit

 
Artist drawing
  Germany

Specifications (Do 31E) edit

 
Flight deck of the Do 31

Data from The Observers Book of Aircraft.[32]

General characteristics

  • Crew: Two
  • Capacity: 36 troops or 24 casualty stretchers and 3,500 kg (7,715 lb) useful load
  • Length: 20.53 m (67 ft 4 in)
  • Wingspan: 18 m (59 ft 3 in)
  • Height: 8.53 m (28 ft 0 in)
  • Wing area: 57 m2 (613.56 sq ft)
  • Gross weight: 22,453 kg (49,500 lb) (VTOL)
  • Max takeoff weight: 27,422 kg (60,500 lb)
  • Powerplant: 2 × Rolls-Royce Pegasus BE.53/2 turbofan, 68.95 kN (15,500 lbf) thrust each
  • Powerplant: 8 × Rolls-Royce RB162-4D Vertically mounted turbojet lift engines, 19.57 kN (4,400 lbf) thrust each

Performance

  • Maximum speed: 730 km/h (452 mph, 393 kn)
  • Cruise speed: 650 km/h (404 mph, 351 kn)
  • Range: 1,800 km (1,120 mi, 970 nmi) with maximum payload
  • Service ceiling: 10,700 m (35,100 ft)
  • Rate of climb: 19.2 m/s (3,780 ft/min) -using Pegasus engines only

See also edit

Related development

Aircraft of comparable role, configuration, and era

Related lists

References edit

Notes edit

  1. ^ By the time of the first flight, Rolls-Royce had taken over Bristol Engines.

Citations edit

  1. ^ Jackson 1976, p. 143.
  2. ^ a b Jackson 1976, p. 29.
  3. ^ a b c Dow 2009, p. 233.
  4. ^ a b c d Hirschel, Prem and Madelung 2012, p. 375.
  5. ^ Hirschel, Prem and Madelung 2012, p. 380.
  6. ^ Hirschel, Prem and Madelung 2012, p. 611.
  7. ^ Dow 2009, pp. 237-238.
  8. ^ "The Dornier DO-960 Analog Computer." vaxman.de, Retrieved: 5 August 2019.
  9. ^ Dow 2009, p. 239.
  10. ^ Hoffert, Fritz. "The Dornier DO 31 Jet-Lift Concept, A Light Military Transport with VTOL Capability." SAE Technical Paper 640229, 1964.
  11. ^ Dow 2009, p. 236.
  12. ^ Dow 2009, pp. 233-234.
  13. ^ Dow 2009, p. 234.
  14. ^ Dow 2009, pp. 234-235.
  15. ^ Dow 2009, p. 246.
  16. ^ Dow 2009, pp. 246-247.
  17. ^ Dow 2009, p. 247.
  18. ^ Dow 2009, pp. 246-248.
  19. ^ Dow 2009, pp. 248-249.
  20. ^ "FAI Record ID #5536 - Speed over a recognized course, München - Paris. Class H (VTOL aircraft)" Fédération Aéronautique Internationale Record date 27 May 1969. Accessed: 4 October 2015.
  21. ^ "FAI Record ID #15153 - Speed, München - Paris. Class H (VTOL aircraft)" Fédération Aéronautique Internationale Record date 27 May 1969. Accessed: 4 October 2015.
  22. ^ "FAI Record ID #15151 - Altitude, München - Paris. Class H (VTOL aircraft)" Fédération Aéronautique Internationale Record date 27 May 1969. Accessed: 4 October 2015.
  23. ^ "FAI Record ID #15152 - Duration, München - Paris. Class H (VTOL aircraft)" Fédération Aéronautique Internationale Record date 27 May 1969. Accessed: 4 October 2015.
  24. ^ "FAI Record ID #6370 - Distance, München - Paris. Class H (VTOL aircraft)" Fédération Aéronautique Internationale Record date 27 May 1969. Accessed: 4 October 2015.
  25. ^ Dow 2009, p. 250.
  26. ^ Dow 2009, pp. 250-251.
  27. ^ Hirschel, Prem and Madelung 2012, pp. 375-376.
  28. ^ a b Dow 2009, p. 253.
  29. ^ Dornier: die Chronik des ältesten deutschen Flugzeugwerks. Dornier GmbH (Friedrichshafen). Aviatic-Verlag, 1985.
  30. ^ Dornier Museum press release (German language) July 18, 2011, at the Wayback Machine Retrieved: 9 August 2009.
  31. ^ Deutsches Museum, Do 31 2015-04-28 at the Wayback Machine www.deutsches-museum.de Retrieved: 5 April 2010.
  32. ^ Green, 1968. p. 88.

Bibliography edit

  • Dow, Andrew. Pegasus, The Heart of the Harrier. Pen and Sword, 2009. ISBN 1-848-84042-X.
  • Green, William. The Observer's Book of Aircraft. London. Frederick Warne & Co. Ltd., 1968.
  • Jackson, Paul A. German Military Aviation 1956–1976. Hinckley, Leicestershire, UK: Midland Counties Publications, 1976. ISBN 0-904597-03-2.
  • Hirschel, Ernst Heinrich., Horst Prem and Gero Madelung. Aeronautical Research in Germany: From Lilienthal until Today. Springer Science & Business Media, 2012. ISBN 3-642-18484-7.
  • "V/STOL YEAR A Review of Progress by Rolls-Royce Jet Lift". Flight International. 8 (2859): 1031–1034. 26 December 1963. Retrieved 22 April 2019..

External links edit

 
Wikimedia Commons has media related to Dornier Do 31.
  • Inside The Cockpit - Dornier Do-31 Military Aviation History

December 20, 2023
dornier, experimental, propelled, vertical, take, landing, vtol, cargo, aircraft, that, designed, produced, west, german, aircraft, manufacturer, dornier, 1968role, vtol, transportmanufacturer, dornier, flugzeugwerkefirst, flight, february, 1967status, project. The Dornier Do 31 is an experimental jet propelled vertical take off and landing VTOL cargo aircraft that was designed and produced by West German aircraft manufacturer Dornier Do 31Dornier Do 31 in 1968Role VTOL transportManufacturer Dornier FlugzeugwerkeFirst flight 10 February 1967Status Project cancelled in April 1970Primary user German Air ForceNumber built 3Variants Dornier Do 231The development of the Do 31 was motivated principally by heavy interest expressed by the German Air Force in the acquisition of short take off and vertical landing aircraft STOVL capable aircraft Such ambitions received a further boost from the issuing of NATO specification NBMR 4 which called for a VTOL capable tactical support aircraft that would be operated in conjunction with the EWR VJ 101 a West German VTOL strike aircraft designed under the NATO contract of BMR 3 1 A total of three aircraft two flight capable and one static airframe were constructed and used for testing On 10 February 1967 the Do 31 performed its maiden flight the first hovering flight of the type took place during July 1967 In addition to performing test flights Dornier often demonstrated the Do 31 prototypes to officials and the general public such as at the 1969 Paris Air Show Several world records were set by the type during its limited flying career When the high cost technical and logistical difficulties of operating such an aircraft were realized the German Air Force opted to cease trials involving VTOL aircraft such as the Do 31 VJ101 and the later VFW VAK 191B In the face of limited sales prospects and a lack of state support the Do 31 and other VTOL projects lingered as research projects for a time prior to their manufacturers abandoning all activity The Do 31 remains the only VTOL capable jet powered transport aircraft to ever fly Contents 1 Design and development 1 1 Background 1 2 Programme launch and design 1 3 Into flight 2 Aircraft on display 3 Operators 4 Specifications Do 31E 5 See also 6 References 6 1 Notes 6 2 Citations 6 3 Bibliography 7 External linksDesign and development editBackground edit During the late 1950s and 1960s the German Air Force became increasingly concerned that in the event of a major conflict with the Eastern Bloc its airfields would be highly vulnerable to attack quickly preventing the use of conventional aircraft in any such conflict Seeking to counter this threat the service actively researched the possibility of dispersed operations one of the options was the use of the nation s Autobahns which necessitated such aircraft to possess short take off and vertical landing STOVL capabilities 2 Due to this interest a series of trials were conducted which involved the modification of several German Air Force Lockheed F 104 Starfighters so that they could be rocket launched from stationary ramps these trials became known as the zero length launch ZELL programme The Starfighters were to be recovered to short strips using aircraft carrier type arresting gear similarly the later Do 31 was intended to use these same austere air strips as forward operating bases 2 As early as 1959 West German aircraft manufacturer Dornier had been informally working on several VTOL related concepts 3 although it would not be until 1961 that the design team would formalise what would become the Do 31 4 Early activity centred around a series of studies on the topic of a VTOL capable utility transport aircraft Dornier s design team based at the company s facility in Friedrichshafen was headed by the aeronautical engineer Gustav Wieland Already at this stage Dornier was liaising with foreign companies including British engine manufacturer Bristol Siddeley who were independently working on their own VTOL orientated engine already 3 The design of the flight control system was considered to be a critical element of any aircraft performing vertical flight particularly in how it handled control failures 5 To support the development programme a purpose built flight control test rig was constructed by Dornier which allowed their design team to explore and evaluate different attitude control laws and flying qualities 6 7 To solve the differential equations necessary to model the aircraft in detail the Dornier DO 960 hybrid computer was developed 8 In spite of allowances to facilitate control during vertical flight the flight control philosophy used upon the Do 31 was more akin to a conventional aircraft than that of a helicopter 9 Programme launch and design edit nbsp Fairings at the top of a lift nacelle in the open positionDuring February 1962 the formal launch of the Do 31 programme occurred with the issuing of a development contract from the West German government 3 By the start of 1964 Dornier had started building a pair of prototype aircraft their manufacture was largely performed at the company s Oberpfaffenhofen plant 10 11 A total of three test prototypes were constructed these being E1 E2 and E3 the E indicating Experimentell Experimental E1 was powered only by the Pegasus engines having been designed to test horizontal flight E2 was a static test airframe and did not ever fly E3 was furnished with both Pegasus and RB162 lift engines installed being intended to evaluate the design s vertical flight mode citation needed nbsp The four Rolls Royce RB162 lift engines seen from the bottom of a nacelleThe design of the Do 31 was heavily reliant upon its engine configuration Dornier had opted to incorporate the British built Bristol Pegasus note 1 vectored thrust turbofan engine an existing powerplant that was most famously used to power the Harrier jump jet On the Do 31 a pair of Pegasus engines were housed in each of the two inboard nacelles during the vertical phase of flight additional lift was provided by an arrangement of four vertically mounted Rolls Royce RB162 lift engines located in each of the outer nacelles 4 12 nbsp Cargo areaBy mounting the engines in pods the fuselage could accommodate a capacious hold for storing cargo which was primarily accessed via a rear facing loading ramp Early designs of the Do 31 used more than four Rolls Royce RB162s the availability of more powerful versions of the Pegasus engine enabled the reduction to four supplemental lift engines 13 Due to the engines being placed in nacelles as opposed to within the fuselage as on the Harrier the Pegasus had to be specially modified for the Do 31 14 nbsp Pitch control nozzles in the tail fed from the Pegasus engines two pointing up two pointing downBeyond providing adequate lift and control other factors influenced the propulsion system According to Dow noise was a considerable concern particularly as the airframe s critical frequency was close to that which was naturally generated by the lift engines 15 The re ingestion of hot exhaust gasses was another critical area complicated by there being 16 fountains of gas being generated during vertical hover 12 of which being hot Following intense study during the flight testing phase of development it was determined that positioning the nozzles at an angle of 85 degrees rather than 90 degrees was sufficient to avoid encountering any issue during takeoff while no such issues were observed during landings at all 16 Several different types of air intakes were also trialled both to deter ingestion issues and the uneven start up of the lift engines Bleed air was also drawn from the Pegasus engines to the lift engines as a measure to address ingestion issues while dedicated studies were performed on ground erosion effects 17 Into flight edit On 10 February 1967 the first prototype E1 conducted its maiden flight powered by just the two Pegasus engines During July 1967 the third prototype E3 which was furnished with all ten of its engines performed the first hovering flight 4 During December 1967 forward and backward transitions between vertical and horizontal phases of flight were successfully conducted On 28 February 1968 the first flight involving multiple transitions was performed 4 According to aviation author Andrew Dow while some initial teething issues were encountered confidence in the aircraft grew quickly 18 As the flight envelope was explored test pilot Drury W Wood performed several exploratory manoeuvres while flying the Do 31 on one occasion deliberately flying it backwards to prove it could be done and performing a barrel roll on another 19 Seeking to garner publicity for its new aircraft Dornier flew one of the prototypes to the 1969 Paris Air Show where it was demonstrated to the general public The ferry flight to reach the event established multiple Federation Aeronautique Internationale FAI world records for the type 20 21 22 23 24 Public recognition was viewed as particularly valuable in light of Dornier s long term ambitions for the Do 31 as the company foresaw civilian uses for the aircraft as a commercial VTOL transport 25 At one point Dornier was negotiating with both Douglas Aircraft and Ling Temco Vought LTV for involvement in the Do 31 programme even rejecting one approach made by Douglas 26 nbsp Model of the unrealised prototype Do 131The Do 31 was the first and so far only vertical takeoff jet transport ever built During April 1970 it was announced that the project had been terminated although the Do 31 performed its final public flight on 4 May 1970 during the Internationale Luft und Raumfahrtausstellung ILA in Hannover 27 One of the alleged contributing factors towards the Do 31 s cancellation was the relatively large drag and weight imposed by the lift engine pods which reduced both the useful payload and range of the type compared to conventional transport aircraft citation needed According to Dow the German government had been frustrated by a lack of commitment forthcoming from other NATO countries and was unwilling to contribute alone to the high funding requirement needs for full scale development 28 During a later stage of development Dornier planned to dispense with the Do 31 s outer nacelles and their engines in their place larger RB153 turbofan engines each capable of generating approximately 5 000 lbf 22 kN of thrust would have been adopted once this powerplant had become available A further development of the Do 31 referred to as the Do 131 intended to be powered by either twelve or fourteen liftjets was also explored by Dornier however no prototype of this variant was ever constructed 29 28 Aircraft on display edit nbsp Do 31 E1 at the Dornier Museum Friedrichshafen nbsp Do 31 E3 at the Deutsches Museum Flugwerft SchleissheimBoth flying prototypes have been preserved in Germany but the fate and current location of the non flying testbed E2 is not known Dornier Do 31 E1 D 9530 is preserved and displayed at the Dornier Museum Friedrichshafen 30 Dornier Do 31 E3 D 9531 was initially put into storage at Oberpfaffenhofen then for several years on display in the open in the courtyard of the Deutsches Museum in Munich and after restoration is now on display at the Deutsches Museum Flugwerft Schleissheim at Oberschleissheim near Munich 31 Operators edit nbsp Artist drawing nbsp GermanyGerman Air Force Luftwaffe Specifications Do 31E edit nbsp Flight deck of the Do 31Data from The Observers Book of Aircraft 32 General characteristicsCrew Two Capacity 36 troops or 24 casualty stretchers and 3 500 kg 7 715 lb useful load Length 20 53 m 67 ft 4 in Wingspan 18 m 59 ft 3 in Height 8 53 m 28 ft 0 in Wing area 57 m2 613 56 sq ft Gross weight 22 453 kg 49 500 lb VTOL Max takeoff weight 27 422 kg 60 500 lb Powerplant 2 Rolls Royce Pegasus BE 53 2 turbofan 68 95 kN 15 500 lbf thrust each Powerplant 8 Rolls Royce RB162 4D Vertically mounted turbojet lift engines 19 57 kN 4 400 lbf thrust eachPerformance Maximum speed 730 km h 452 mph 393 kn Cruise speed 650 km h 404 mph 351 kn Range 1 800 km 1 120 mi 970 nmi with maximum payload Service ceiling 10 700 m 35 100 ft Rate of climb 19 2 m s 3 780 ft min using Pegasus engines onlySee also edit nbsp Aviation portalRelated development Dornier Do 231Aircraft of comparable role configuration and era Armstrong Whitworth AW 681 LTV XC 142Related lists List of military aircraft of GermanyReferences editNotes edit By the time of the first flight Rolls Royce had taken over Bristol Engines Citations edit Jackson 1976 p 143 a b Jackson 1976 p 29 a b c Dow 2009 p 233 a b c d Hirschel Prem and Madelung 2012 p 375 Hirschel Prem and Madelung 2012 p 380 Hirschel Prem and Madelung 2012 p 611 Dow 2009 pp 237 238 The Dornier DO 960 Analog Computer vaxman de Retrieved 5 August 2019 Dow 2009 p 239 Hoffert Fritz The Dornier DO 31 Jet Lift Concept A Light Military Transport with VTOL Capability SAE Technical Paper 640229 1964 Dow 2009 p 236 Dow 2009 pp 233 234 Dow 2009 p 234 Dow 2009 pp 234 235 Dow 2009 p 246 Dow 2009 pp 246 247 Dow 2009 p 247 Dow 2009 pp 246 248 Dow 2009 pp 248 249 FAI Record ID 5536 Speed over a recognized course Munchen Paris Class H VTOL aircraft Federation Aeronautique Internationale Record date 27 May 1969 Accessed 4 October 2015 FAI Record ID 15153 Speed Munchen Paris Class H VTOL aircraft Federation Aeronautique Internationale Record date 27 May 1969 Accessed 4 October 2015 FAI Record ID 15151 Altitude Munchen Paris Class H VTOL aircraft Federation Aeronautique Internationale Record date 27 May 1969 Accessed 4 October 2015 FAI Record ID 15152 Duration Munchen Paris Class H VTOL aircraft Federation Aeronautique Internationale Record date 27 May 1969 Accessed 4 October 2015 FAI Record ID 6370 Distance Munchen Paris Class H VTOL aircraft Federation Aeronautique Internationale Record date 27 May 1969 Accessed 4 October 2015 Dow 2009 p 250 Dow 2009 pp 250 251 Hirschel Prem and Madelung 2012 pp 375 376 a b Dow 2009 p 253 Dornier die Chronik des altesten deutschen Flugzeugwerks Dornier GmbH Friedrichshafen Aviatic Verlag 1985 Dornier Museum press release German language Archived July 18 2011 at the Wayback Machine Retrieved 9 August 2009 Deutsches Museum Do 31 Archived 2015 04 28 at the Wayback Machine www deutsches museum de Retrieved 5 April 2010 Green 1968 p 88 Bibliography edit Dow Andrew Pegasus The Heart of the Harrier Pen and Sword 2009 ISBN 1 848 84042 X Green William The Observer s Book of Aircraft London Frederick Warne amp Co Ltd 1968 Jackson Paul A German Military Aviation 1956 1976 Hinckley Leicestershire UK Midland Counties Publications 1976 ISBN 0 904597 03 2 Hirschel Ernst Heinrich Horst Prem and Gero Madelung Aeronautical Research in Germany From Lilienthal until Today Springer Science amp Business Media 2012 ISBN 3 642 18484 7 V STOL YEAR A Review of Progress by Rolls Royce Jet Lift Flight International 8 2859 1031 1034 26 December 1963 Retrieved 22 April 2019 External links edit nbsp Wikimedia Commons has media related to Dornier Do 31 Inside The Cockpit Dornier Do 31 Military Aviation History Retrieved from https en wikipedia org w index php title Dornier Do 31 amp oldid 1190287081, wikipedia, wiki, book, books, library,

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