Geometric–harmonic mean

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Thrust-to-weight ratio is a dimensionless ratio of thrust to weight of a rocket, jet engine, propeller engine, or a vehicle propelled by such an engine that indicates the performance of the engine or vehicle.

The instantaneous thrust-to-weight ratio of a vehicle varies continually during operation due to progressive consumption of fuel or propellant and in some cases a gravity gradient. The thrust-to-weight ratio based on initial thrust and weight is often published and used as a figure of merit for quantitative comparison of the initial performance of vehicles.

Calculation

The thrust-to-weight ratio can be calculated by dividing the thrust (in SI units – in newtons) by the weight (in newtons) of the engine or vehicle. It is a dimensionless quantity.

For valid comparison of the initial thrust-to-weight ratio of two or more engines or vehicles, thrust must be measured under controlled conditions.

Aircraft

The thrust-to-weight ratio and wing loading are the two most important parameters in determining the performance of an aircraft.[1] For example, the thrust-to-weight ratio of a combat aircraft is a good indicator of the manoeuvrability of the aircraft.[2]

The thrust-to-weight ratio varies continually during a flight. Thrust varies with throttle setting, airspeed, altitude and air temperature. Weight varies with fuel burn and changes of payload. For aircraft, the quoted thrust-to-weight ratio is often the maximum static thrust at sea-level divided by the maximum takeoff weight.[3]

In cruising flight, the thrust-to-weight ratio of an aircraft is the inverse of the lift-to-drag ratio because thrust is equal to drag, and weight is equal to lift.[4]

Propeller-driven aircraft

For propeller-driven aircraft, the thrust-to-weight ratio can be calculated as follows:[5]

where is propulsive efficiency at true airspeed

is engine power

Rockets

Rocket vehicle Thrust-to-weight ratio vs Isp for different propellant technologies.

The thrust-to-weight ratio of a rocket, or rocket-propelled vehicle, is an indicator of its acceleration expressed in multiples of gravitational acceleration g.[6]

Rockets and rocket-propelled vehicles operate in a wide range of gravitational environments, including the weightless environment. The thrust-to-weight ratio is usually calculated from initial gross weight at sea-level on earth [7] and is sometimes called Thrust-to-Earth-weight ratio.[8] The thrust-to-Earth-weight ratio of a rocket or rocket-propelled vehicle is an indicator of its acceleration expressed in multiples of earth’s gravitational acceleration, g0.[6]

The thrust-to-weight ratio for a rocket varies as the propellant is burned. If the thrust is constant, then the maximum ratio (maximum acceleration of the vehicle) is achieved just before the propellant is fully consumed. Each rocket has a characteristic thrust-to-weight curve or acceleration curve, not just a scalar quantity.

The thrust-to-weight ratio of an engine exceeds that of the whole launch vehicle but is nonetheless useful because it determines the maximum acceleration that any vehicle using that engine could theoretically achieve with minimum propellant and structure attached.

For a takeoff from the surface of the earth using thrust and no aerodynamic lift, the thrust-to-weight ratio for the whole vehicle must be more than one. In general, the thrust-to-weight ratio is numerically equal to the g-force that the vehicle can generate.[6] Take-off can occur when the vehicle's g-force exceeds local gravity (expressed as a multiple of g0).

The thrust to weight ratio of rockets typically greatly exceeds that of airbreathing jet engines because the comparatively far greater density of rocket fuel eliminates the need for much engineering materials to pressurize it.

Many factors affect a thrust-to-weight ratio. The instantaneous value typically varies over the flight with the variations of thrust due to speed and altitude along with the weight due to the remaining propellant and payload mass. The main factors include freestream air temperature, pressure, density, and composition. Depending on the engine or vehicle under consideration, the actual performance will often be affected by buoyancy and local gravitational field strength.

Examples

The Russian-made RD-180 rocket engine (which powers Lockheed Martin’s Atlas V) produces 3,820 kN of sea-level thrust and has a dry mass of 5,307 kg.Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. Using the Earth surface gravitational field strength of 9.807 m/s², the sea-level thrust-to-weight ratio is computed as follows: (1 kN = 1000 N = 1000 kg⋅m/s²)

Aircraft

Vehicle T/W Scenario
Concorde 0.373Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. Max take-off weight, full reheat
Lightning 0.63Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. Maximum takeoff weight, no reheat
Lightning c. 1.2[9] on an empty weight basis, full reheat
F-22 > 1.09 (1.26 with loaded weight and 50% fuel)[10] Maximum takeoff weight, dry thrust
MiG-29 1.09[10] Full internal fuel, 4 AAMs
F-15 1.04[11] Nominally loaded
F-16 1.096Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.
Harrier 1.1Potter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.
Typhoon 1.07[12] 100% fuel, 2 IRIS-T, 4 MBDA Meteor
Space Shuttle 1.5 Take-off [13]
Rafale 0.988[14] Version M, 100% fuel, 2 EM A2A missile, 2 IR A2A missiles
Space Shuttle 3 Peak (throttled back for astronaut comfort)[15]

Jet and rocket engines

Template:Engine thrust to weight table

Fighter aircraft

Table a: Thrust-to-weight ratios, fuel weights, and weights of different fighter planes
Specifications / Fighters F-15K F-15C MiG-29K MiG-29B JF-17 J-10 F-35A F-35B F-35C F-22
Engine(s) thrust maximum (lbf) 58,320 (2) 46,900 (2) 39,682 (2) 36,600 (2) 18,300 (1) 27,557 (1) 39,900 (1) 39,900 (1) 39,900 (1) 70,000 (2)
Aircraft weight empty (lb) 37,500 31,700 28,050 24,030 14,520 20,394 29,300 32,000 34,800[16] 43,340
Aircraft weight, full fuel (lb) 51,023 45,574 39,602 31,757 19,650 28,760 47,780 46,003 53,800 61,340
Aircraft weight, max take-off load (lb) 81,000 68,000 49,383 40,785 28,000 42,500 70,000 60,000 70,000 83,500
Total fuel weight (lb) 13,523 13,874 11,552 07,727 05,130 08,366 18,480 14,003 19,000[16] 18,000
T/W ratio (full fuel) 1.14 1.03 1.00 1.15 0.93 0.96 0.84 0.87 0.74 1.14
Table b: Thrust-to-weight ratios, fuel weights, and weights of different fighter planes (In International System)
In International System F-15K F-15C MiG-29K MiG-29B JF-17 J-10 F-35A F-35B F-35C F-22
Engine(s) thrust maximum (kgf) 26,456 (2) 21,274 (2) 18,000 (2) 16,600 (2) 08,300 (1) 12,500 (1) 18,098 (1) 18,098 (1) 18 098 (1) 31,764 (2)
Aircraft weight, empty (kg) 17,010 14,379 12,723 10,900 06,586 09,250 13,290 14,515 15,785 19,673
Aircraft weight, full fuel (kg) 23,143 20,671 17,963 14,405 08,886 13,044 21,672 20,867 24,403 27,836
Aircraft weight, max take-off load (kg) 36,741 30,845 22,400 18,500 12,700 19,277 31,752 27,216 31,752 37,869
Total fuel weight (kg) 06,133 06,292 05,240 03,505 02,300 03,794 08,382 06,352 08,618 08,163
T/W ratio (full fuel) 1.14 1.03 1.00 1.15 0.93 0.96 0.84 0.87 0.74 1.14
  • Fuel density used in calculations: 0.803 kg/l
  • The number inside brackets is the number of engines.
  • Engines powering F-15K are the Pratt & Whitney engines, not General Electric's.
  • MiG-29K's empty weight is an estimate.
  • JF-17's engine rating is of RD-93.
  • JF-17 if mated with its engine WS-13, and if that engine gets its promised 18,969 lb then the T/W ratio becomes 0.97
  • J-10's empty weight and fuelled weight are estimates.
  • J-10's engine rating is of AL-31FN.
  • J-10 if mated with its engine WS-10A, and if that engine gets its promised 132 KN(29,674 lbf) then the T/W ratio becomes 1.03

See also

References

  • John P. Fielding. Introduction to Aircraft Design, Cambridge University Press, ISBN 978-0-521-65722-8
  • Daniel P. Raymer (1989). Aircraft Design: A Conceptual Approach, American Institute of Aeronautics and Astronautics, Inc., Washington, DC. ISBN 0-930403-51-7
  • George P. Sutton & Oscar Biblarz. Rocket Propulsion Elements, Wiley, ISBN 978-0-471-32642-7

Notes

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

External links

  1. Daniel P. Raymer, Aircraft Design: A Conceptual Approach, Section 5.1
  2. John P. Fielding, Introduction to Aircraft Design, Section 4.1.1 (p.37)
  3. John P. Fielding, Introduction to Aircraft Design, Section 3.1 (p.21)
  4. Daniel P. Raymer, Aircraft Design: A Conceptual Approach, Equation 5.2
  5. Daniel P. Raymer, Aircraft Design: A Conceptual Approach, Equation 5.1
  6. 6.0 6.1 6.2 George P. Sutton & Oscar Biblarz, Rocket Propulsion Elements (p. 442, 7th edition) “thrust-to-weight ratio F/Wg is a dimensionless parameter that is identical to the acceleration of the rocket propulsion system (expressed in multiples of g0) if it could fly by itself in a gravity-free vacuum”
  7. George P. Sutton & Oscar Biblarz, Rocket Propulsion Elements (p. 442, 7th edition) “The loaded weight Wg is the sea-level initial gross weight of propellant and rocket propulsion system hardware.”
  8. Template:Cite web
  9. Section 9 Template:Cite web
  10. 10.0 10.1 http://www.aviationsmilitaires.net/display/aircraft/87/f_a-22 Cite error: Invalid <ref> tag; name "militaire" defined multiple times with different content
  11. Template:Cite web
  12. Kampflugzeugvergleichstabelle Mader/Janes
  13. Thrust: 6.781 million lbf, Weight: 4.5 million lbTemplate:Cite web
  14. http://www.aviationsmilitaires.net/display/variant/1
  15. Template:Cite web
  16. 16.0 16.1 Template:Cite web