Diverterless supersonic inlet: Difference between revisions

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A diverterless supersonic inlet (DSI) is a type of jet engine air intake used by some modern combat aircraft to control air flow into their engines. It consists of a "bump" and a forward-swept inlet cowl, which work together to divert boundary layer airflow away from the aircraft's engine. This eliminates the need for a splitter plate, while compressing the air to slow it down from supersonic to subsonic speeds. The DSI can be used to replace conventional methods of controlling supersonic and boundary-layer airflow.

DSIs can be used to replace the intake ramp and inlet cone, which are more complex, heavy and expensive.^[1]

History

Initial development in this area was done by Grumman, who made an alteration to the Grumman F11F-1F Super Tiger inlet, to replace a splitter plate with a bump.They still used bleed air holes on the bump.^[2] Further research into the DSI was done by Lockheed Martin in the early 1990s. The first Lockheed DSI was flown on 11 December 1996, installed on a F-16 Block 30 fighter and replacing aircraft's original intake diverter. The modified F-16 demonstrated a maximum speed of Mach 2.0 (Mach 2.0 is the F-16's clean certified maximum speed) and handling characteristics similar to a normal F-16. It was also shown that subsonic specific excess power was slightly improved.

A DSI was later incorporated into the design of the Lockheed Martin F-35 Lightning II. The DSI concept was introduced into the JAST/JSF program as a trade study item in mid-1994. It was compared with a traditional "caret" style inlet. The trade studies involved additional CFD, testing, and weight and cost analyses. The new inlet earned its way into the JSF design after proving to be thirty percent lighter and showing lower production and maintenance costs over traditional inlets while still meeting all performance requirements. ^[1]

Technology

When an aircraft is flying, the speed of the air relative to the engine is equal to the plane's flight speed. However, current turbine engines are unable to handle supersonic airflow. This is because shock waves associated with supersonic speeds can damage or cause dangerous vibrations in turbine blades, resulting in loss of thrust or engine failure. Consequently, in aircraft travelling at supersonic speeds, the air entering the inlet must be slowed down to subsonic speeds before reaching the compressor and turbine blades of the jet engine. Additionally, the airflow must also be at the optimal speed and volume so as to offer maximum thrust.^[3]

Inlets

The diverter plates on an F-22 inlet are clearly visible in this photograph as the gap between the engine intake and the main aircraft body

Modern combat aircraft accomplish this in a variety of ways, through design of the inlet. The inlet sits upstream of the compressor and has a strong influence on engine net thrust. A well-designed inlet straightens out the flow, and feeds the compressor with turbulence-free air at a relatively constant speed and volume. This is not difficult to achieve in subsonic aircraft such as passenger jets, which do not perform high-speed, high-G maneuvers that lead to turbulent airflow.^[4] Inlets on subsonic aircraft are simple and shorter, and are basically an opening designed to minimize drag.^[5]

On supersonic military jets, the inlets are usually much more complex and use shock waves to slow down the air, and movable internal vanes to shape and control the flow. At supersonic flight speeds, shock waves form in the intake system and reduce the recovered pressure at inlet to the compressor. So some supersonic intakes use devices, such as a cone or ramp, to increase pressure recovery, by making more efficient use of the shock wave system. The complexity of these inlets increases with an increase in top speed. Planes with top speeds over Mach 2 require much more elaborate inlet designs. This limits most modern combat aircraft to top speeds of Mach 1.8-2.0.

Diverterless Inlets

The DSI bump functions as a compression surface and creates a pressure distribution that prevents the majority of the boundary layer air from entering the inlet at speeds up to Mach 2. In essence, the DSI does away with complex and heavy mechanical systems.

Benefits

File:J-10b.JPG

Chengdu J-10B during take-off, with a clear view of the DSI inlets. Notice how the DSI inlet shields the engine fan from view. This improves the stealthiness of the platform.

Weight and complexity reduction

DSIs completely eliminates all moving parts. This results in an inlet that is far less complex than earlier diverter-plate inlets. The removal of moving parts also lightens the overall weight of the aircraft. Traditional aircraft inlets contain many moving parts and are much heavier than newer diverterless inlets.^[6]

Stealth

DSIs also crucially improve the aircraft's very-low-observable characteristics (by eliminating radar reflections between the diverter and the aircraft's skin).^[1] Additionally, the "bump" surface reduces the engine's exposure to radar, significantly reducing a strong source of radar reflection^[7] because they provide an additional shielding of engine fans against radar waves.

Analysts have noted that the DSI reduces the need for application of radar-absorbent materials.^[1]^[8]

List of Aircraft with DSI

References

^ ^a ^b ^c ^d Hehs, Eric (15 July 2000). "JSF Diverterless Supersonic Inlet". Code One magazine. Lockheed Martin. Retrieved 11 February 2011.
^ [Naval Fighters 44, F-11F Supertiger pg 37, by Corwin ( Corky ) Meyer]
^ http://kakunhome.tripod.com/aviation.htm
^ University presentation on JSF Program
^ Inlet Design and Inlet types, NASA.
^ F-35 JSF Technology
^ "Fast History: Lockheed's Diverterless Supersonic Inlet Testbed F-16" aviationintel.com, 13 January 2013
^ "J-20's Stealth Signature Poses Interesting Unknowns". Aviation Week. Retrieved 13 January 2013
^ "歼-10B改进型". AirForceWorld.com.
^ "JL-9 Trainer Jet gets DSI inlet, Guizhou China". AirForceWorld.com. Retrieved 29 Aug 2011.
^ "Paris Air Show 2011 - Naval air trainer unveiled by Chinese media". home.janes.com, 15 February 2012.

External links

[code_one_magazine_article-1] Hehs, Eric (15 July 2000). "JSF Diverterless Supersonic Inlet". Code One magazine. Lockheed Martin. Retrieved 11 February 2011.

[2] [Naval Fighters 44, F-11F Supertiger pg 37, by Corwin ( Corky ) Meyer]

[3] ttp://kakunhome.tripod.com/aviation.htm

[4] University presentation on JSF Program

[5] Inlet Design and Inlet types, NASA.

[6] F-35 JSF Technology

[7] "Fast History: Lockheed's Diverterless Supersonic Inlet Testbed F-16" aviationintel.com, 13 January 2013

[8] "J-20's Stealth Signature Poses Interesting Unknowns". Aviation Week. Retrieved 13 January 2013

[J10-B-9] "歼-10B改进型". AirForceWorld.com.

[JL-9_Trainer_Jet_DSI_Inlet_AirForceWorld.com-10] "JL-9 Trainer Jet gets DSI inlet, Guizhou China". AirForceWorld.com. Retrieved 29 Aug 2011.

[home.janes.com-11] "Paris Air Show 2011 - Naval air trainer unveiled by Chinese media". home.janes.com, 15 February 2012.

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 == Technology ==
+When an aircraft is flying, the speed of the air relative to the engine is equal to the plane's flight speed. However, current turbine engines are unable to handle supersonic airflow. This is because [[shock wave|shock waves]] associated with supersonic speeds can damage or cause dangerous vibrations in turbine blades, resulting in loss of thrust or engine failure. Consequently, in aircraft travelling at supersonic speeds, the air entering the inlet must be slowed down to [[subsonic]] speeds before reaching the compressor and turbine blades of the [[Gas turbine|jet engine]]. Additionally, the airflow must also be at the optimal speed and volume so as to offer maximum thrust.<ref>[http://kakunhome.tripod.com/aviation.htm http://kakunhome.tripod.com/aviation.htm]</ref>
 === Inlets ===
 [[File:Raptor-ElmendorfAFB-2009.JPG|thumb|The diverter plates on an [[Lockheed_Martin_F-22_Raptor|F-22]] inlet are clearly visible in this photograph as the gap between the engine intake and the main aircraft body]]
+Modern combat aircraft accomplish this in a variety of ways, through design of the inlet. The inlet sits upstream of the compressor and has a strong influence on engine net thrust. A well-designed inlet straightens out the flow, and feeds the compressor with turbulence-free air at a relatively constant speed and volume. This is not difficult to achieve in subsonic aircraft such as passenger jets, which do not perform high-speed, high-G maneuvers that lead to turbulent airflow.<ref>[http://www.nsinnovations.com.au/Downloads/seminars/JSF%20Uni%20Brief%2028Jun06(1100).pdf University presentation on JSF Program]</ref> Inlets on subsonic aircraft are simple and shorter, and are basically an opening designed to minimize drag.<ref>[http://www.grc.nasa.gov/www/BGH/inlet.html Inlet Design and Inlet types], [[NASA]].</ref>
-When an aircraft is flying, the speed of the air relative to the engine is equal to the plane's flight speed. However, the airflow into the engine compressor chamber needs to be subsonic, and at the optimal speed and volume so as to offer maximum thrust. The inlet sits upstream of the compressor and has a strong influence on engine net thrust.
-The speed of air entering the compressor of a normal [[Gas turbine|jet engine]] must not be [[supersonic]], even for supersonic aircraft. Current turbine engines are unable to handle the [[shock wave]]s associated with supersonic airflow, and might be damaged or suffer loss of thrust if supersonic airflow passes through compressor blades. Thus, on aircraft traveling above the speed of sound, the airflow must be slowed down to subsonic speeds before entering the engine. In modern jet aircraft, this is done in a variety of ways through design of the inlet.<ref>[http://kakunhome.tripod.com/aviation.htm http://kakunhome.tripod.com/aviation.htm]</ref>
-A well-designed inlet straightens out the flow, and feeds the compressor with turbulence-free air at a relatively constant speed and volume. This is not difficult to achieve in subsonic aircraft such as passenger jets, which do not perform high-speed, high-G maneuvers that lead to turbulent airflow.<ref>[http://www.nsinnovations.com.au/Downloads/seminars/JSF%20Uni%20Brief%2028Jun06(1100).pdf University presentation on JSF Program]</ref> Consequently, subsonic aircraft have simple, and shorter inlets.<ref>[http://www.grc.nasa.gov/www/BGH/inlet.html Inlet Design and Inlet types], [[NASA]].</ref>
-On supersonic military jets, the inlets are usually much more complex and use shock waves to slow down the air, and movable internal vanes to shape and control the flow. The complexity of these inlets increases with an increase in top speed. Planes with top speeds over Mach 2 require much more elaborate inlet designs, which limits most modern combat jets to a top speed of Mach 2.
+On supersonic military jets, the inlets are usually much more complex and use shock waves to slow down the air, and movable internal vanes to shape and control the flow. At supersonic flight speeds, shock waves form in the intake system and reduce the recovered pressure at inlet to the compressor. So some supersonic intakes use devices, such as a cone or ramp, to increase pressure recovery, by making more efficient use of the shock wave system. The complexity of these inlets increases with an increase in top speed. Planes with top speeds over Mach 2 require much more elaborate inlet designs. This limits most modern combat aircraft to top speeds of Mach 1.8-2.0.
 === Diverterless Inlets ===

v t e Aircraft components and systems
Airframe structure	Aft pressure bulkhead Cabane strut Canopy Crack arrestor Cruciform tail Dope Empennage Fabric covering Fairing Flying wires Former Fuselage Hardpoint Interplane strut Jury strut Leading edge Lift strut Longeron Nacelle Rib Spar Stabilizer Stressed skin Strut T-tail Tailplane Trailing edge Triple tail Twin tail V-tail Vertical stabilizer Wing root Wing tip Wingbox
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Landing and arresting gear	Aircraft tire Arrestor hook Autobrake Conventional landing gear Drogue parachute Landing gear Landing gear extender Oleo strut Tricycle landing gear Tundra tire
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