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Slowed rotor

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The McDonnell XV-1 could slow its rotor from 410 to 180 RPM

The slowed rotor principle is used in the design of some helicopters. On a conventional helicopter the rotational speed of the rotor is constant; reducing it at lower flight speeds can reduce fuel consumption and enable the aircraft to fly more economically. In the compound helicopter and related aircraft configurations such as the gyrodyne and winged autogyro, reducing the rotational speed of the rotor and offloading part of its lift to a fixed wing reduces drag, enabling the aircraft to fly faster.

Introduction

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Traditional helicopters get both their propulsion and lift from the main rotor; by using a dedicated propulsion device such as a propeller or jet engine, the rotor burden is lessened.[1] If wings are also used to lift the aircraft, the rotor can be unloaded (partially or fully) and its rotational speed further reduced, enabling higher aircraft speed. Compound helicopters use these methods,[2][3][4] but the Boeing A160 Hummingbird shows that rotor-slowing is possible without wings or propellers, and regular helicopters may reduce turbine RPM (and thus rotor speed) to 85% using 19% less power.[5] Alternatively, research suggests that twin-engine helicopters may decrease fuel consumption by 25%-40% when running only one engine, given adequate height and velocity well inside the safe areas of the height–velocity diagram.[6][7][8]

As of 2012, no compound or hybrid wing/rotor (manned) aircraft had been produced in quantity, and only a few had been flown as experimental aircraft,[9] mainly because the increased complexities have not been justified by military or civilian markets.[10] Varying the rotor speed may induce severe vibrations at specific resonance frequencies.[11]

Contra-rotating rotors (as on the Sikorsky X2) solve the problem of lift dissymmetry by having both left and right sides provide near equal lift with less flapping.[12][1] The X2 deals with the compressibility issue by reducing its rotor speed[1] from 446 to 360 RPM[13][14] to keep the advancing blade tip below the sound barrier when going above 200 knots.[15]

Design principles

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Speed limits of aircraft rotors

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Effect of blade airspeed on lift on advancing and retreating side, when aircraft speed is 100 knots.

The rotors of conventional helicopters are designed to operate at a fixed speed of rotation, to within a few percent.[16][17][18][11] This introduces limitations in areas of the flight envelope where the optimal speed differs.[5]

In particular, it limits the maximum forward speed of the aircraft. Two main issues restrict the speed of rotorcraft:[11][4][19][12]

  • Retreating blade stall. As forward speed of the helicopter increases, the airflow over the retreating blade becomes relatively slower, while the airflow over the advancing blade is relatively faster, creating more lift. If not counteracted by flapping,[20] this would cause dissymmetry of lift and eventually retreating blade stall,[2][3][21][22][1] and blade stability suffers as the blade reaches its limits for flapping.[12][23]
  • Transonic drag near the rotor blade tip. The faster-moving advancing blade tip may begin to approach the speed of sound, where transonic drag begins to rise steeply, and severe buffeting and vibration effects can occur. This effect prevents any further increase in speed, even if the helicopter has surplus power remaining, and even if it features a highly streamlined fuselage. A similar effect prevents propeller-driven aircraft from achieving supersonic speeds, although they can achieve higher speeds than a helicopter since the propeller blade isn't advancing in the direction of travel.[2][3][1][24][25][26]

These (and other)[27][28] problems limit the practical speed of a conventional helicopter to around 160–200 knots (300–370 km/h).[1][26][29][30] At the extreme, the theoretical top speed for a rotary winged aircraft is about 225 knots (259 mph; 417 km/h),[28] just above the current official speed record for a conventional helicopter held by a Westland Lynx, which flew at 400 km/h (250 mph) in 1986[31] where its blade tips were nearly Mach 1.[32]

Slowed rotors and aircraft speed

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Rotorcraft Aspect ratio (mu) diagram
Drag type curves as a function of airspeed (simulated)
Cruise combinations for rotor power, propeller and wings.
Cruise combinations for rotor power, propeller and wings.

For rotorcraft, advance ratio (or Mu, symbol ) is defined as the aircraft forward speed V divided by its relative blade tip speed.[33][34][35] Upper mu limit is a critical design factor for rotorcraft,[23] and the optimum for traditional helicopters is around 0.4.[4][26]

The "relative blade tip speed" u is the tip speed relative to the aircraft (not the airspeed of the tip). Thus the formula for Advance ratio is

where Omega (Ω) is the rotor's angular velocity, and R is the rotor radius (about the length of one rotor blade)[36][23][13]

When the rotor blade is perpendicular to the aircraft and advancing, its tip airspeed Vt is the aircraft speed plus relative blade tip speed, or Vt=V u.[12][37] At mu=1, V is equal to u and the tip airspeed is twice the aircraft speed.

At the same position on the opposite side (retreating blade), the tip airspeed is the aircraft speed minus relative blade tip speed, or Vt=V-u. At mu=1, the tip airspeed is zero.[30][38] At a mu between 0.7 and 1.0, most of the retreating side has reverse airflow.[13]

Although rotor characteristics are fundamental to rotorcraft performance,[39] little public analytical and experimental knowledge exists between advance ratios of 0.45 to 1.0,[13][40] and none is known above 1.0 for full-size rotors.[41][42] Computer simulations are not capable of adequate predictions at high mu.[43][44] The region of reverse flow on the retreating blade is not well understood,[45][46] however some research has been conducted,[47][48] particularly for scaled rotors.[49][50] The US Army Aviation Applied Technology Directorate runs a supporting program in 2016 aiming at developing transmissions with a 50% rotor speed reduction.[51]

The profile drag of a rotor corresponds to the cube of its rotational speed.[52][53] Reducing the rotational speed is therefore a significant reduction of rotor drag, allowing higher aircraft speed[13] A conventional rotor such as the UH-60A has lowest consumption around 75% rpm, but higher aircraft speed (and weight) requires higher rpm.[54]

A rotor disk with variable radius is a different way of reducing tip speed to avoid compressibility, but blade loading theory suggests that a fixed radius with varying rpm performs better than a fixed rpm with varying radius.[55]

Fuel economy of slowed rotors

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Conventional helicopters have constant-speed rotors and adjust lift by varying the blade angle of attack or collective pitch. The rotors are optimised for high-lift or high-speed flight modes and in less demanding situations are not as efficient.

The profile drag of a rotor corresponds to the cube of its rotational speed.[52][53] Reducing the rotational speed and increasing the angle of attack can therefore give a significant reduction in rotor drag, allowing lower fuel consumption.[5]

History

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Pitcairn PCA-2 autogyro. Unpowered rotor, tractor propeller, wings.

Technical parameters given for each type listed:

  • maximum speed.
  • μ, the ratio of forward airspeed to rotational tip speed.
  • Rotor lift as a percentage of total lift, at full speed.
  • Lift-to-drag ratio (L/D).

Early development

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When Juan de la Cierva developed the autogyro through the 1920s and 1930s, it was found that the tip speeds of the advancing rotor blade could become excessive. Designers such as he and Harold F. Pitcairn developed the idea of adding a conventional wing to offload the rotor during high-speed flight, allowing it to rotate at slower speeds.[citation needed]

The 1932 Pitcairn PCA-2 autogyro had a maximum speed of 20-102 knots (117 mph; 189 km/h),[56] μ of 0.7,[57] and L/D of 4.8[58]

NACA engineer John Wheatley examined the effect of varying advance ratios up to about 0.7 in a wind tunnel in 1933 and published a landmark study in 1934. Although lift could be predicted with some accuracy, by 1939 the state of the art theory still gave unrealistically low values for rotor drag.[59]

Postwar projects

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Fairey Aviation in the UK worked on gyrodynes in the late 1940s and 1950s developing tip-jet propulsion which eliminated the need for countertorque. They culminated in the Fairey Rotodyne, the prototype for a VTOL passenger aircraft, which could combine the vertical landing of a helicopter with the speed of a fixed wing aircraft. The Rotodyne had a single 90 ft diameter main rotor supplemented by a 46 ft wide wing with forward thrust provided by twin turboprop engines. In forward flight the power to the rotor was reduced to about 10%.[citation needed] Its maximum speed was 166 knots (191 mph; 307 km/h) a record set in 1959.[60][61] 0.6.[62] Rotor speed was 120 (high speed cruising flight as an autogyro) to 140 (flare out while landing as a helicopter) rpm[63] During forward flight 60% of the lift came from the wings and 40% from the rotor.[64]

At the same time, the US Air Force was investigating fast VTOL aircraft. McDonnell developed what became the McDonnell XV-1, the first of the V-designated types, which flew in 1955. It was a tip-jet driven gyrodyne, which turned off rotor thrust at high airspeeds and relied on a pusher propeller to maintain forward flight and rotor autorotation. Lift was shared between the rotor and stub wings. It established a rotorcraft speed record of 170 knots (200 mph; 310 km/h). 0.95.[65] 180-410[66] (50%[67]). 85% \ 15%.[68] 6.5 (Wind tunnel tests at 180 RPM with no propeller.[69])

The Lockheed AH-56 Cheyenne military attack helicopter for the US Army arose out of Lockheed's ongoing research programme into rigid rotors, which began with the CL-475 in 1959. Stub wings and a thrust turbojet to offload the rotor were first added to an XH-51A and in 1965 this allowed the craft to achieve a world speed record of 272 miles per hour (438 km/h). The Cheyenne flew just two years later, obtaining its forward thrust from a pusher propeller. Although pre-production prototypes were ordered the program met problems and was cancelled.[70] 212 knots (244 mph; 393 km/h).[71][72] 0.8.[65] .. \ 20%.[73]

The Piasecki 16H Pathfinder project similarly evolved an initially conventional design into a compound helicopter through the 1960s, culminating in the 16H-1A Pathfinder II which flew successfully in 1965. Thrust was obtained via a ducted fan at the tail.[74]

The Bell 533 of 1969 was a compound jet helicopter. 275 knots (316 mph; 509 km/h).[75][76]

Modern developments

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The compound helicopter has continued to be studied and flown experimentally. In 2010 the Sikorsky X2 flew with coaxial rotors. 250 knots (290 mph; 460 km/h).[77][78] 0.8.[13] 360 to 446.[13][14] No wings.[79] In 2013 the Eurocopter X3 flew.[80] 255 knots (293 mph; 472 km/h).[81][82] 310 minus 15%.[12] 40[12][1]-80% \.[83][84]

The compound autogyro, in which the rotor is supplemented by wings and thrust engine but is not itself powered, has also undergone further refinement by Jay Carter Jr. He flew his CarterCopter in 2005. 150 knots (170 mph; 280 km/h).[85] 1. 50%.[13] By 2013 he had developed its design into a personal air vehicle, the Carter PAV. 175 knots (201 mph; 324 km/h). 1.13. 105[86] to 350.[87]

The potential of the slowed rotor in enhancing fuel economy has also been studied in the Boeing A160 Hummingbird UAV, a conventional helicopter. 140 knots (160 mph; 260 km/h). 140 to 350.[88]

See also

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References

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Citations

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  1. ^ a b c d e f g Chandler, Jay. "Advanced rotor designs break conventional helicopter speed restrictions (page 1) Archived 2013-07-18 at the Wayback Machine" Page 2 Archived 2013-07-18 at the Wayback Machine Page 3 Archived 2013-07-18 at the Wayback Machine. ProPilotMag, September 2012. Accessed: 10 May 2014. Archive 1 Archive 2 Archive 3
  2. ^ a b c Robb 2006, page 31
  3. ^ a b c Silva 2010, page 1.
  4. ^ a b c Harris 2003, page 7
  5. ^ a b c Khoshlahjeh
  6. ^ Dubois, Thierry. "Researchers Look at Single-engine Cruise Ops on Twins" AINonline, 14 February 2015. Accessed: 19 February 2015.
  7. ^ Perry, Dominic. "Airbus Helicopters promises safe single-engine operations with Bluecopter demonstrator" Flight Global, 8 July 2015. Archive
  8. ^ Perry, Dominic. "Turbomeca eyes flight tests of 'engine sleep mode'" Flight Global, 25 September 2015. Archive
  9. ^ Rigsby, page 3
  10. ^ Johnson HT, p. 325
  11. ^ a b c Lombardi, Frank. "Optimizing the Rotor" Rotor&Wing, June 2014. Accessed: 15 June 2014. Archived on 15 June 2014
  12. ^ a b c d e f Nelms, Douglas. "Aviation Week Flies Eurocopter’s X3" Aviation Week & Space Technology, 9 July 2012. Accessed: 10 May 2014. Alternate link Archived 2012-10-11 at the Wayback Machine Archived on 12 May 2014
  13. ^ a b c d e f g h Datta, page 2.
  14. ^ a b Jackson, Dave. "Coaxial - Sikorsky ~ X2 TD" Unicopter. Accessed: April 2014.
  15. ^ Walsh 2011, page 3
  16. ^ Robert Beckhusen. "Army Dumps All-Seeing Chopper Drone" Wired June 25, 2012. Accessed: 12 October 2013. "for standard choppers ... the number of revolutions per minute is also set at a fixed rate"
  17. ^ The UH-60 permits 95–101% rotor RPM UH-60 limits US Army Aviation. Retrieved 2 January 2010
  18. ^ Trimble, Stephen (3 July 2008). "DARPA's Hummingbird unmanned helicopter comes of age". FlightGlobal. Archived from the original on 14 May 2014. Retrieved 14 May 2014. The rotor speed on a typical helicopter can be varied around 95-102%
  19. ^ Chiles, James R. "Hot-Rod Helicopters" Page 2 Page 3 Air & Space/Smithsonian, September 2009. Accessed: 18 May 2014.
  20. ^ "Blade flapping" Dynamic Flight
  21. ^ "Helicopter Limitations Archived 2014-05-17 at the Wayback Machine" Challis Heliplane
  22. ^ "Retreating blade stall" Dynamic Flight
  23. ^ a b c Johnson HT, p. 323
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  25. ^ "Nomenclature: Transonic drag rise Archived 2016-12-03 at the Wayback Machine" NASA
  26. ^ a b c Filippone, Antonio (2000). "Data and performances of selected aircraft and rotorcraft" pages 643-646. Department of Energy Engineering, Technical University of Denmark / Progress in Aerospace Sciences, Volume 36, Issue 8. Accessed: 21 May 2014. doi:10.1016/S0376-0421(00)00011-7 Abstract
  27. ^ Beare, Glenn. "Why can't a Helicopter fly faster than it does ?" helis.com . Accessed: 9 May 2014.
  28. ^ a b Krasner, Helen. "Why Can’t Helicopters Fly Fast?" Decoded Science, 10 December 2012. Accessed: 9 May 2014.
  29. ^ Majumdar, Dave. "DARPA Awards Contracts in Search of a 460 MPH Helicopter" United States Naval Institute, 19 March 2014. Accessed: 9 May 2014.
  30. ^ a b Wise, Jeff. "The Rise of Radical New Rotorcraft" Popular Mechanics, 3 June 2014. Accessed: 19 June 2014. Archive Quote: "This aerodynamic principle limits conventional helicopters to about 200 mph."
  31. ^ "Rotorcraft Absolute: Speed over a straight 15/25 km course Archived 2013-12-03 at the Wayback Machine". Fédération Aéronautique Internationale (FAI). Note search under E-1 Helicopters and "Speed over a straight 15/25 km course". Accessed: 26 April 2014.
  32. ^ Hopkins, Harry (27 December 1986), "Fastest blades in the world" (pdf), Flight International: 24–27, retrieved 28 April 2014, Archive page 24 Archive page 25 Archive page 26 Archive page 27 {{citation}}: External link in |quote= (help)
  33. ^ "Nomenclature: Mu Archived 2016-12-03 at the Wayback Machine" NASA
  34. ^ Definition of Advance ratio
  35. ^ "Flapping Hinges" Aerospaceweb.org. Accessed: 8 May 2014.
  36. ^ Jackson, Dave. "Tip Speed Ratio (Advance Ratio)" Unicopter, 6 September 2013. Retrieved: 22 May 2015. Archived on 21 October 2014.
  37. ^ "Helicopter Flying Handbook", Chapter 02: Aerodynamics of Flight (PDF, 9.01 MB), Figure 2-33 page 2-18. FAA-H-8083-21A, 2012. Accessed: 21 May 2014.
  38. ^ Berry, page 3-4
  39. ^ Harris 2008, page 13
  40. ^ Berry, page 25
  41. ^ Harris 2008, page 25
  42. ^ Kottapalli, page 1
  43. ^ Harris 2008, page 8
  44. ^ Bowen-Davies, page 189-190
  45. ^ Harris 2008, page 14
  46. ^ Bowen-Davies, page 198
  47. ^ DuBois 2013
  48. ^ Potsdam, Mark; Datta, Anubhav; Jayaraman, Buvana (18 March 2016). "Computational Investigation and Fundamental Understanding of a Slowed UH-60A Rotor at High Advance Ratios". Journal of the American Helicopter Society. 61 (2): 1–17. doi:10.4050/JAHS.61.022002.
  49. ^ Bowen-Davies, page 216
  50. ^ Granlund, Kenneth; Ol, Michael; Jones, Anya (2016). "Streamwise oscillation of airfoils into reverse-flow". AIAA Journal. 54 (5): 1628–1636. Bibcode:2016AIAAJ..54.1628G. doi:10.2514/1.J054674.
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  52. ^ a b Gustafson, page 12
  53. ^ a b Johnson RA, page 251.
  54. ^ Bowen-Davies, page 97-99
  55. ^ Bowen-Davies, page 101
  56. ^ Harris 2003, page A-40
  57. ^ Harris 2008, page 19
  58. ^ Duda, Holger; Insa Pruter (2012). "Flight performance of lightweight gyroplanes" (PDF). German Aerospace Center. p. 5. Retrieved 5 April 2020.
  59. ^ Harris (2008) pp.35-40.
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  67. ^ Watkinson, page 355
  68. ^ Robb 2006, page 41
  69. ^ Harris 2003, page 18. Lift forces at page A-101
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  75. ^ Robb 2006, page 43
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  80. ^ The X3 concept Archived 2014-05-12 at the Wayback Machine Video1 Video2, at 2m50s Airbus Helicopters. Accessed: 9 May 2014.
  81. ^ Thivent, Viviane. "Le X3, un hélico à 472 km/h" Le Monde, 11 June 2013. Accessed: 10 May 2014. Possible mirror
  82. ^ X3 Helicopter Sets Speed Record At Nearly 300 MPH Wired
  83. ^ Norris, Guy. "Eurocopter X-3 Targets U.S. Market[permanent dead link]" Aviation Week, 28 February 2012. Accessed: 1 March 2012. Mirror Archived 2014-04-13 at the Wayback Machine
  84. ^ Tarantola, Andrew. "Monster Machines: The New Fastest Helicopter On Earth Can Fly At An Insane 480km/h" Gizmodo, 19 June 2013. Accessed: April 2014.
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  87. ^ Moore, Jim. "Carter seeks factory" Aircraft Owners and Pilots Association, 21 May 2015. Accessed: 28 May 2014. Archived on 22 May 2015.
  88. ^ Hambling, David. "The Rise of the Drone Helicopter - A160T Hummingbird" Popular Mechanics. Accessed: April 2014.

Bibliography

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