V-22 Osprey: Difference between revisions
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{{Image|Osprey.png|left|350px|Osprey in action.}} | |||
'''The V-22 Osprey''' is a [[tiltrotor]] aircraft that marries the function of a helicopter with an airplane. A tiltrotor craft takes off like a [[helicopter]] and then switches to flying like an [[airplane]] while in flight. It is not, however, a helicopter or a fixed-wing aircraft. | |||
Field experience emphasizes that the Osprey should not be considered merely a helicopter replacement; it has advantages and disadvantages of its own. Both Marine and Air Force operators have observed that it is traditional, with helicopters, to send several on a mission that could be done by a single Osprey. The Osprey preferably flies at a much higher altitude than helicopters, and there can be performance tradeoffs that facilitate operating in high elevations such as in Afghanistan. One Marine officer said that he found, for mission planning, it was better to think of the Osprey as a small, agile [[C-130 Hercules]] rather than as a helicopter.<ref name=Drwiega>{{citation | |||
| title = Ospreys in Iraq: The Commander’s Perspective | |||
The | | author = Andrew Drwiega | journal = Defence Helicopter | ||
| date = March 2006 | |||
| url = http://www.boeing.com/ospreynews/2009/issue_01/proven_s3_p2.html}}</ref> As opposed to smaller helicopters, it can be [[air refueling|air refueled]], but it also can ''be'' a refueling tanker, a key Navy mission.<ref name=Easterly>{{citation | |||
| url http://www.nps.edu/Academics/Institutes/Meyer/docs/V22%20Easterly%20presentation%20Oct%2014%202004.pdf | |||
| title = Navy V-22: Concept of Employment | |||
| author = Arnie Easterly | |||
| date = January 2004 | |||
| publisher = U.S. Naval War College}}, pp. 13, 22</ref> | |||
According to the United States Navy Fact File, the Osprey is a tiltrotor aircraft with a 38-foot rotor system and engine/transmission nacelle mounted on each wing tip. It can operate as a helicopter when taking off and landing vertically. Once airborne, the nacelles rotate forward 90 degrees for horizontal flight, converting the V-22 to a high-speed, fuel-efficient turboprop airplane. The wing rotates for compact storage aboard ship. The first flight occurred in March 1989. The V-22 is the world's first production tiltrotor aircraft | According to the[[ United States Navy]] Fact File,<ref>{{citation | ||
| title = V-22A Osprey tilt rotor aircraft | |||
| publisher = [[United States Navy]] | |||
| url = http://www.navy.mil/navydata/fact_display.asp?cid=1200&tid=800&ct=1}}</ref> the Osprey is a tiltrotor aircraft with a 38-foot rotor system and engine/transmission [[nacelle]] mounted on each wing tip. It can operate as a helicopter when taking off and landing vertically. Once airborne, the nacelles rotate forward 90 degrees for horizontal flight, converting the V-22 to a high-speed, fuel-efficient turboprop airplane. The wing rotates for compact storage aboard ship. The first flight occurred in March 1989. The V-22 is the world's first production tiltrotor aircraft. | |||
The Osprey can carry 24 combat troops, up to 20,000 pounds internal cargo or 15,000 pounds external cargo, according to Boeing Defense, Space and Security. | The Osprey can carry 24 combat troops, up to 20,000 pounds internal cargo or 15,000 pounds external cargo, according to [[Boeing|Boeing Defense, Space and Security]]. | ||
==Controversies== | |||
Considerable attention has come from Congress and its auditing arm, the [[General Accountability Office]].A relatively recent GAO report asks for much more analysis before making further investments.<ref name-GAO-09-692T>{{citation | |||
| title = V-22 Osprey Aircraft: Assessments Needed to Address Operational and Cost Concerns to Define Future Investments; testimony before the Committee on Oversight and Government Reform, House of Representatives | |||
| id = GAO-09-692T | |||
| date = 23 June 2009 | |||
| author = Michael J. Sullivan, Director Acquisition and Sourcing Management | |||
| publisher = [[General Accountability Office]] | |||
| url = http://www.gao.gov/new.items/d09692t.pdf}}</ref> | |||
==Development history== | |||
While the aircraft is now operational and preliminary reports are positive, the development history was long and troubled, and involved balancing costs and risks, and managing the integrity of the procurement process. The [[U.S. Army]], generally considered the lead agency for [[air assault]] and [[tactical mobility]], began the program in 1981, but transferred it to the Navy in 1982, questioning if the technology was affordable. Full-scale funding began in 1986, and the first flight was in 1989. One month later, the [[Secretary of Defense]] stopped asking for funding, again concerned with affordability, and in December, the Navy was directed to terminate the program as not affordable when compared to helicopter alternatives | |||
"Congress disagreed with this decision, however, and continued to fund the project. In October of 1992 the Navy ordered development to continue and awarded a contract to a Bell Helicopter Textron and Boeing Helicopters joint venture to begin producing production-representative aircraft."<ref>GAO-09-692T, pp. 2-3</ref> | |||
While the aircraft is now operational and preliminary reports are positive, the development history was long and troubled, and involved balancing costs and risks, and managing the integrity of the procurement process. | |||
===Technology issues=== | |||
[[Image:V-22-vrs-image01.gif|right|thumb|350px|V-22 flight performance envelope during evaluation]] | |||
During operational evaluation in 2000, there was a fatal crash caused by the vortex ring state (VRS) condition.<blockquote>The side-by-side rotor configuration of V-22 is susceptible to asymmetric onset of Vortex Ring State (VRS), brought on by descending too quickly. The one-rotor-in/one-rotor-out conditions results in large rolling moments and departure from controlled flight. Such a characteristic is fundamental and cannot be remedied by minor design changes. The only near-term solution is to restrict operations to avoid proximity to VRS region. V-22 advocates say V-22 pilots can escape vortex ring state by tilting the rotors forward to get out of helicopter mode. <ref name=GS>{{citation | |||
| title = V-22 Osprey Vortex Ring State (VRS) | |||
| url = http://www.globalsecurity.org/military/systems/aircraft/v-22-vrs.htm | |||
| publisher = Globalsecurity}}</ref></blockquote> | |||
==Deployment and variants== | |||
It was first deployed operationally in Iraq. Not surprisingly, since it is not a true helicopter and has different characteristics, field experience led to rethinking some of its roles. "or example, the introduction of the MV-22 into Iraq in combination with existing helicopters has led to some reconsideration of the appropriate role of each. Battlefield commanders and aircraft operators in Iraq identified a need to better understand the role the Osprey should play in fulfilling warfighter needs. They indicated, for example, that the MV-22 may not be best suited for the full range of missions requiring medium lift, because the aircraft’s speed cannot be exploited over shorter distances or in transporting external cargo. These concerns were also highlighted in a recent preliminary analysis of the MV-22 by the Center for Naval Analysis, which found that the MV-22 may not be the optimal platform for those missions."<ref>GAO-09-692T, pp. 3-4</ref> | |||
Note that the "M" prefix, in U.S. aircraft naming, normally denotes a [[special operations]] variant, where "C" designates a [[transport aircraft]]. The Marines and Air Force appear to have, for unclear reasons, reversed this convention. "H", as used by the Navy, is a proper prefix for search missions. | |||
Boeing is responsible for building the fuselage, empennage, and all subsystems, digital avionics, and fly-by-wire control systems. [[Bell Helicopter Textron, Inc.]] is responsible for the wing, transmissions, rotor systes, engine installation and finally assembly at their assembly plant located in Amarillo, Texas, USA. | |||
The Osprey was approved for full-rate production by [[United States Department of Defense]] in September 2005, with a USD $19 billion contract authorizing:<ref>{{citation | |||
| title = Textron's Bell Helicopter Granted Approval for Full Rate Production of V-22 Osprey Tiltrotor | |||
| publisher = Textron Bell | |||
| date = 28 September 2005 | |||
| url = http://www.globalsecurity.org/military/library/news/2005/09/mil-050928-textron01.htm | |||
}}</ref> | |||
*360 (U.S. Marines) | |||
*50 (U.S. Air Force) | |||
*48 (U.S. Navy) | |||
The 2010 production schedule calls for making 29 deliveries of the Osprey. | The 2010 production schedule calls for making 29 deliveries of the Osprey. | ||
====U.S. Marine Corps==== | |||
[[MV-22]] is the Marine Corps version of the Osprey which promises serve as an [[expeditionary]] aircraft with assault capabilities. The Marine version of the Osprey is designed as an assault aircraft and for use in special operations. | |||
The USMC currently has five Osprey combat squadrons. VMM-263, were sent to Iraq in October 2007. This was the combat debut for the Osprey. Three squadrons were later deployed. | |||
Afloat, several MV-22's made the first inaugural voyage with the 22nd Marine Expeditionary Unit in 2009. <ref>{{citation | |||
| title = Osprey to deploy with 22nd MEU | |||
| date = 9 May 2009 | |||
| author = Jennifer Hlad | |||
| url = http://www.jdnews.com/news/ryan-64103-aircraft-osprey.html | |||
| publisher = JDNews.com (Jacksonville, North Carolina)}}</ref> | |||
The Osprey was sent to Afghanistan in November 2009. | |||
====U.S. Navy==== | |||
[[HV-22]] is the United States Navy'w designation for the V-22. The USN version is designed to provide [[combat search and rescue]], [[carrier onboard delivery]], air refueling, the delivery of special warfare teams and their removal from the theater, and fleet support. <ref name=Easterly/> | |||
V-22 | =====Transport===== | ||
In the [[carrier onboard delivery]] and [[vertical replenishment]] roles, its capacity is:<ref>Easterly, p. 12</ref> | |||
{{col-begin}} | |||
{{col-break|width=50%}} | |||
{| | |||
|- valign=top | |||
| | |||
*Internal Cargo Capacity | |||
**Maximum weight: 20,000 pounds | |||
**Maximum volume: 739 cubic feet | |||
**Maximum pallet/cargo length: 20.8 feet | |||
**Possible loads | |||
***24 combat loads | |||
***Four 40x48 in Warehouse Pallets | |||
***Two 463L Half-Pallets | |||
**Cargo handling | |||
***Roller Conveyer | |||
***Winch | |||
{{col-break|width=50%}} | |||
*External Cargo Capacity | |||
**Two retractable external cargo hooks | |||
**10,000# single hook | |||
**15,000# dual hook | |||
**130 knot maximum speed with external load | |||
|} | |||
=====Aerial refueling===== | |||
Capabilities:<ref>Easterly, p. 13</ref> | |||
*Auxiliary Tanks: 2 x 430 gal (5590 lbs.) | |||
*Internal Fuel: 11,700 lb/1720 gal | |||
*Fuel Giveaway: Auxiliary + Internal (17,290 lbs.) | |||
*Refueling Kit Weight: 660 lbs | |||
*Fuel rate: 120gpm | |||
*Reconfigure time: < 1.5 hours | |||
*Compatible aircraft: V-22, CH-53E, AV-8, F/A-18, JSF, etc. | |||
*Maximum speed: 230kts | |||
&80-91 ft hose length | |||
In a typical carrier refueling scenario, the operating cycle would be: <ref>Easterly, p. 21</ref> | |||
#Launches last, climbs to 10,00 feet | |||
#Consolidates other tankers currently airborne, relieving as necessary | |||
#Meets the outgoing strike group | |||
#Return overhead as Recovery Tanker for 2nd cycle | |||
#Recovers last in second recovery | |||
#Relieves Super Hornets that performed strike/enroutetanking | |||
====U.S. Air Force==== | |||
[[CV-22]] is the Air Force designation of the V-22. [[Air Force Special Operations Command]] received the Osprey in 2006, and first deployed to [[Mali]], for a 15-nation cooperative effort under [[United States Africa Command]], Exercise Flintlock of November 2008.<ref>{{citation | |||
| title = CV-22s complete first operational deployment | |||
| date = 3 December 2008 | |||
| author = Lauren Johnson | |||
| url = http://www.af.mil/news/story.asp?storyID=123126398 | |||
| publisher = 1st Special Operations Wing Public Affairs}}</ref> The Ospreys carried Malian and Senegalese [[special operations]] soldiers and their command team. Lt. Col. Eric Hill, leading the 8th Special Operations Squadron (SOS), onserved "The tyranny of distance in the African continent is amazing. We were able to go over 500 nautical miles, infiltrate a small team for them to run their exercise, and bring them back all the way to home base without doing an air refueling stop. And we were able to do that in the span of about four hours. " | |||
Capt. Dennis Woodlief, an 8th SOS pilot, said "It would take the [[MH-53 PAVE LOW]] twice, sometimes three times as long (to do these missions). And we did it with just one aircraft." In Marine deployments in Iraq, the lesson that Ospreys can do missions alone, rather than in sections as is common with helicopters. | |||
Much was learned by the 1st Special Operations Helicopter Maintenance Squadron at a remote location, Bamako, Mali, with very limited base facilities, they had to deploy with everything needed to support operations 5,000 miles from home. "We have a laundry list about three pages long of things we'd like to take next time," said Master Sgt. Craig Kornely, the squadron's lead production supervisor. "As we grow into the machine, we realize our needs for equipment and resources." Woodlief said "We had zero maintenance cancels, zero delays, and we executed 100 percent every time. I think we went above and beyond everyone's expectations." | |||
== Tactics == | |||
Like any aircraft, experience tends to be needed to learn the unique tactical advantages and disadvantages of the Osprey. Early World War II, for example, the Japanese [[A6M (fighter)|A6M Zero fighter]] was a fearsome opponent, but U.S. pilots learned that while it was a death sentence to try to turn with it in a dogfight, heavier fighters could win by diving on the Zero and firing on its totally unprotected areas. | |||
GAO said the "V-22 has maneuvering limits that restrict its ability to perform defensive maneuvers and it does not have a required integrated defensive weapon needed to suppress threats while approaching a landing zone, disembarking troops within the landing zone, or while leaving the landing zone. Currently, the Marine Corps intends to employ the aircraft in a manner that limits its exposure to threats mdash; a change from the original intent that the system would be able to operate in such environments.<ref>GAO-09-692T, p. 6 </ref> | |||
Lieutenant Colonel Christopher ‘Mongo’ Seymour, who commanded the Marine VMM-266 Osprey squadron, spoke of some of the lessons learned. In mission planning, he said the Osprey had to be understood as more like an extremely agile version of the [[C-130 Hercules]] fixed wing transport, typically flying at medium altitude, than a helicopter that routinely skims the ground. Helicopter doctrine is "that you have to have two aircraft. So we wanted to carry out the task in some scenarios as a little brother to the C-130 – they don’t task a C-130 in sections and we are the same case." Seymour said that two Ospreys were often sent on missions that could easily have been handled by one. | |||
He predicted that its characteristics would do well in the mountains of Afghanistan. "We can trade fuel for payload and altitude. The other beauty about the Osprey is that the [[CH-46]] – well even the [[CH-53]] (it could do this but they don’t like to) – if it was a hard hit mission, picking up somebody who’s been hit, troops in contact etc, I could go to a high zone at 9,000 or 10,000 ft, drop somebody off and pick them up. And if the mission has been long and maybe I do not have enough gas to get back to Kabul, I could meet a tanker pretty easily and refuel and make it – which is the difference. Once I am in aeroplane mode, hover performance is not an issue any more. I could go to 60,500 lb at 20,000 ft just like that."<ref name=Drwiega/> | |||
Addressing the survivability concerns, Seymour observed that the Osprey, at its normal altitude of 8-12,000 feet, is much quieter than a lower-flying helicopter, and is harder to see from the ground. "So nobody knows to look up – and even if they did a grey V-22 on a blue background is virtually impossible to spot. We have several tactical approaches that we use. Let me just tell you this, when I was in the test world I did a one-for-one comparison between a V-22 and an AH-1. The set-up was an array of [[geophysical MASINT|acoustic sensors]] in a target area. We had to fly over the sensors on the same path, type of day etc. | |||
"So we fly the V-22 at 200 ft and 220 kts over these sensors at a five-mile range. Then the Cobra did it. The unclassified data showed that if you were at the target you would hear the Cobra two minutes before he reached you; with the V-22 it wasn’t heard until 10 seconds beforehand [the author experienced and can verify the quietness of the aircraft over several days at Al Asad with Ospreys, [[CH-46]] Sea Knights, [[CH-53]]s, [UH-1]] Hueys and [[AH-1]] Cobras flying in and out during the period – the V-22 was the quietest of the lot]." In other words, accept that an Osprey is not a pure helicopter substitute. | |||
The pilot uses a single set of controls to fly the | ==Humanitarian assistance== | ||
In January 2010, in support of the [[United States Southern Command]], the 24th Marine Expeditionary Unit deployed aviation squadron VMM-162with 12 MV-22 Ospreys, four CH-53E Super Stallion heavy lift /transport helicopters, three UH-1N Huey helicopters and close air support jets and attack helicopters. It gave a new capability of "transporting 24 passengers or 12 aid litters (stretchers) that makes the aircraft a versatile mechanism for moving supplies, relief workers and medical personnel to disaster areas or casualties to health facilities."<ref>{{citation | |||
| title = Osprey's provide MEU's a new tool for Humanitarian Aid missions | |||
| date = 22 January 2010 | |||
| author = Alex C. Sauceda | publisher = 24th Marine Expeditionary Unit, U.S. Marine Corps | |||
| url = http://www.usmc.mil/unit/24thmeu/Pages/Osprey%27sprovideMEU%27swithanewtoolforHumanitarianAidmissions.aspx}}</ref> | |||
== Flying An Osprey == | |||
The pilot uses a single set of controls to fly the Osprey and can during flight switch from helicopter to fixed wing mode with ease by using automatic controls to switch from helicopter to fixed wing mode. | |||
The nacelle angle is controlled by the pilot using the nacelle control. The pilot can also adjust for angle, acceleration for forward or aft and control aircraft pitch. The nacelle control complements the longitudinal cyclic stick and includes automatic conversion corridor protection control. | The [[nacelle]] angle is controlled by the pilot using the nacelle control. The pilot can also adjust for angle, acceleration for forward or aft and control aircraft pitch. The nacelle control complements the longitudinal cyclic stick and includes automatic conversion corridor protection control. | ||
During flight the nacelles will begin to rotate allowing the craft to | During flight the nacelles will begin to rotate allowing the craft to switch from helicopter mode to airplane mode. The process is called transition. During transition the pilot can manually control the operation or opt for automatic transition using the flight control system. It takes approximately 16 seconds to complete the transition process. In the case of the Osprey, the nacelle is used to house or enclose the aircraft's engine. | ||
Conversion is the opposite process. The Osprey will switch from aircraft mode to helicopter mode during the conversion process. Again, the nacelles are a key part of the conversion process. | Conversion is the opposite process. The Osprey will switch from aircraft mode to helicopter mode during the conversion process. Again, the nacelles are a key part of the conversion process. | ||
Line 41: | Line 165: | ||
Both the transition and conversion modes of flying can take place continuously, stopped as needed, or reversed. Airplane flight though needs to take place when the Osprey is flying between 40 to 80 knots and has a wide range of permissible air speeds (approximately 100 knots). | Both the transition and conversion modes of flying can take place continuously, stopped as needed, or reversed. Airplane flight though needs to take place when the Osprey is flying between 40 to 80 knots and has a wide range of permissible air speeds (approximately 100 knots). | ||
==Logistics and support== | |||
Bell Boeing operates a logistics support center in New Bern, North Carolina. This is close to the Marine Corps Air Station at Cherry Point, the main location for Marine Osprey operational development. <ref>{{citation | |||
| title = New V-22 Osprey Logistics Support Center Opens in New Bern, North Carolina | |||
| date = 25 June 2005 | |||
| publisher = Bell [[Boeing]] Program Office | |||
| url =http://www.boeing.com/rotorcraft/military/v22/news/2005/q3/nr_050725n.html}}</ref> | |||
On 15 June 2009, Bell Boeing Program Office received an $11 million dollar, Phase 1.5 of a two-phase Joint Performance Based Logistics (PBL) contract from the U.S. Department of Defense to support the V-22 Osprey tiltrotor aircraft for the Marine Corps (MV-22), and Air Force Special Operations Command (CV-22).<ref>{{citation | |||
V22 | | title = Bell Boeing Team Awarded Contract for Next Phase of V-22 Osprey Support | ||
Engines | | date = 15 June 2009 | ||
Two Rolls-Royce Liberty AE1107C | | publisher = Bell [[Boeing]] Program Office | ||
AEO VTOL Normal Power, shp (kW) : 6,150 (4,586) | | url = http://boeing.mediaroom.com/index.php?s=43&item=699}}</ref> | ||
AEO VTOL Interim Power, shp (kW) : 6,830 (5,093) | == Characteristics == | ||
OEI VTOL, shp (kW) : 6,830 (5,093) | A baseline configuration has the following charactistics: <ref name="urlV22 Osprey Web">{{cite web | ||
Transmission | |url=http://www.navair.navy.mil/v22/?fuseaction=aircraft.main | ||
AEO VTOL Max Cont., rhp (kW) : 4,570 (3,408) | |title= V22 Osprey Web | ||
AEO VTOL Takeoff, rhp (kW) : 5,183 (3,865) | | publisher = Naval Air Systems Command | ||
Proprotor System | |accessdate=2010-08-14 | ||
Blades per hub : 3 | }}</ref> | ||
Construction : Graphite/fiberglass | {{col-begin}} | ||
Tip speed, fps (mps) : 661.90 (201.75) | {{col-break|width=50%}} | ||
Diameter, ft (m) : 38.00 (11.58) | {| | ||
Blade area, ft2 (m2) : 261.52 (24.30) | |- valign=top | ||
Disc area, ft2 (m2) : 2,268.00 (210.70) | | | ||
Blade folding : Automatic, powered | *Engines | ||
Performance | **Two Rolls-Royce Liberty AE1107C | ||
Max Cruise speed (MCP), SL, kts (km/h) : 241-257 (446-476) | **All engines operating (AEO) [[VTOL]] Normal Power, shp (kW) : 6,150 (4,586) | ||
Max R/C, A/P Mode, SL, fpm (m/m) : 3,200 (975) | **AEO VTOL Interim Power, shp (kW) : 6,830 (5,093) | ||
Service ceiling, ISA, ft (m) : 24,700 (7,529) | **OEI VTOL, shp (kW) : 6,830 (5,093) | ||
OEI Service ceiling, ISA, ft (m) : 10,300 (3,139) | *Transmission | ||
HOGE | **AEO VTOL Max Cont., rhp (kW) : 4,570 (3,408) | ||
Mission radius with aft sponson tank | **AEO VTOL Takeoff, rhp (kW) : 5,183 (3,865) | ||
Land-Assault Troop Mission (24 Troops), nm (km) : 242 (448) | *Proprotor System | ||
Pre-Assault Raid, nm (km) : 267 (495) | **Blades per hub : 3 | ||
Mission radius with wing tanks | **Construction : Graphite/fiberglass | ||
Land-Assault Troop Mission (24 Troops), nm (km) : 233 (432) | **Tip speed, fps (mps) : 661.90 (201.75) | ||
Pre-Assault Raid, nm (km) : 306 (567) | **Diameter, ft (m) : 38.00 (11.58) | ||
Accommodation | **Blade area, ft2 (m2) : 261.52 (24.30) | ||
Cockpit - crew seats : 2 MV / 3 CV | **Disc area, ft2 (m2) : 2,268.00 (210.70) | ||
Cabin - crew seat/troop seats/litters : 1/24/12 | **Blade folding : Automatic, powered | ||
Dimensions (External) | *Performance | ||
Length, fuselage, ft (m) : 57.3 (17.48) | **Max Cruise speed (MCP), SL, kts (km/h) : 241-257 (446-476) | ||
Width, rotors turning, ft (m) : 84.6 (25.55) | **Max R/C, A/P Mode, SL, fpm (m/m) : 3,200 (975) | ||
Length, stowed, ft (m) : 63 (19.20) | **Service ceiling, ISA, ft (m) : 24,700 (7,529) | ||
Width, stowed, ft (m) : 18.4 (5.61) | **OEI Service ceiling, ISA, ft (m) : 10,300 (3,139) | ||
Width, horizontal stabilizer, ft (m) : 18.4 (5.61) | **Maximum hover ceiling in ground effect at takeoff (HOGE), ISA, ft (m) : 5,400 (1,646) | ||
Height, nacelles fully vertical, ft (m) : 22.1 (6.73) | *Mission radius with aft sponson tank | ||
Height, vertical stabilizer, ft (m) : 17.9 (5.46) | **Land-Assault Troop Mission (24 Troops), nm (km) : 242 (448) | ||
Height, stowed, ft (m) : 18.3 (5.56) | **Pre-Assault Raid, nm (km) : 267 (495) | ||
Dimensions (Internal) | *Mission radius with wing tanks | ||
Length, max, ft (m) : 24.17 (7.37) | **Land-Assault Troop Mission (24 Troops), nm (km) : 233 (432) | ||
Width, max, ft (m) : 5.92 (1.80) | **Pre-Assault Raid, nm (km) : 306 (567) | ||
Height, max, ft (m) : 6.00 (1.83) | *Accommodation | ||
Weights | **Cockpit - crew seats : 2 MV / 3 CV | ||
Empty, lbs (kg) : 33,459 (15,177) | **Cabin - crew seat/troop seats/litters : 1/24/12 | ||
Takeoff, | {{col-break|width=50%}} | ||
Takeoff, short running, max, lbs (kg) : 57,000 (25,909) | *Dimensions (External) | ||
Takeoff, self-deploy mission, lbs (kg) : 60,500 (27,443) | **Length, fuselage, ft (m) : 57.3 (17.48) | ||
Cargo hook, single, lbs (kg) : 10,000 (4,536) | **Width, rotors turning, ft (m) : 84.6 (25.55) | ||
Cargo hook, dual, lbs (kg) : 15,000 (6,804) | **Length, stowed, ft (m) : 63 (19.20) | ||
Fuel Capacity | **Width, stowed, ft (m) : 18.4 (5.61) | ||
MV-22 (including aft sponson tank), gallons (liters) : 1,448 (5,481) | **Width, horizontal stabilizer, ft (m) : 18.4 (5.61) | ||
CV-22 (including aft sponson tank), gallons (liters) : 2,040 (7,722) | **Height, nacelles fully vertical, ft (m) : 22.1 (6.73) | ||
Fuel Capacity with wing tanks | **Height, vertical stabilizer, ft (m) : 17.9 (5.46) | ||
MV-22 (including wing tanks, no aft sponson tank), gallons (liters) : 1,724 (6,526) | **Height, stowed, ft (m) : 18.3 (5.56) | ||
*Dimensions (Internal) | |||
**Length, max, ft (m) : 24.17 (7.37) | |||
**Width, max, ft (m) : 5.92 (1.80) | |||
**Height, max, ft (m) : 6.00 (1.83) | |||
*Weights | |||
**Empty, lbs (kg) : 33,459 (15,177) | |||
**Takeoff, vertical, max, lbs (kg) : 52,600 (23,495) | |||
**Takeoff, short running, max, lbs (kg) : 57,000 (25,909) | |||
**Takeoff, self-deploy mission, lbs (kg) : 60,500 (27,443) | |||
**Cargo hook, single, lbs (kg) : 10,000 (4,536) | |||
**Cargo hook, dual, lbs (kg) : 15,000 (6,804) | |||
*Fuel Capacity | |||
**MV-22 (including aft sponson tank), gallons (liters) : 1,448 (5,481) | |||
**CV-22 (including aft sponson tank), gallons (liters) : 2,040 (7,722) | |||
*Fuel Capacity with wing tanks | |||
**MV-22 (including wing tanks, no aft sponson tank), gallons (liters) : 1,724 (6,526) | |||
|} | |||
== References == | |||
{{reflist|2}} |
Revision as of 12:30, 30 April 2024
The V-22 Osprey is a tiltrotor aircraft that marries the function of a helicopter with an airplane. A tiltrotor craft takes off like a helicopter and then switches to flying like an airplane while in flight. It is not, however, a helicopter or a fixed-wing aircraft.
Field experience emphasizes that the Osprey should not be considered merely a helicopter replacement; it has advantages and disadvantages of its own. Both Marine and Air Force operators have observed that it is traditional, with helicopters, to send several on a mission that could be done by a single Osprey. The Osprey preferably flies at a much higher altitude than helicopters, and there can be performance tradeoffs that facilitate operating in high elevations such as in Afghanistan. One Marine officer said that he found, for mission planning, it was better to think of the Osprey as a small, agile C-130 Hercules rather than as a helicopter.[1] As opposed to smaller helicopters, it can be air refueled, but it also can be a refueling tanker, a key Navy mission.[2]
According to theUnited States Navy Fact File,[3] the Osprey is a tiltrotor aircraft with a 38-foot rotor system and engine/transmission nacelle mounted on each wing tip. It can operate as a helicopter when taking off and landing vertically. Once airborne, the nacelles rotate forward 90 degrees for horizontal flight, converting the V-22 to a high-speed, fuel-efficient turboprop airplane. The wing rotates for compact storage aboard ship. The first flight occurred in March 1989. The V-22 is the world's first production tiltrotor aircraft.
The Osprey can carry 24 combat troops, up to 20,000 pounds internal cargo or 15,000 pounds external cargo, according to Boeing Defense, Space and Security.
Controversies
Considerable attention has come from Congress and its auditing arm, the General Accountability Office.A relatively recent GAO report asks for much more analysis before making further investments.Cite error: Invalid <ref>
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Development history
While the aircraft is now operational and preliminary reports are positive, the development history was long and troubled, and involved balancing costs and risks, and managing the integrity of the procurement process. The U.S. Army, generally considered the lead agency for air assault and tactical mobility, began the program in 1981, but transferred it to the Navy in 1982, questioning if the technology was affordable. Full-scale funding began in 1986, and the first flight was in 1989. One month later, the Secretary of Defense stopped asking for funding, again concerned with affordability, and in December, the Navy was directed to terminate the program as not affordable when compared to helicopter alternatives
"Congress disagreed with this decision, however, and continued to fund the project. In October of 1992 the Navy ordered development to continue and awarded a contract to a Bell Helicopter Textron and Boeing Helicopters joint venture to begin producing production-representative aircraft."[4]
While the aircraft is now operational and preliminary reports are positive, the development history was long and troubled, and involved balancing costs and risks, and managing the integrity of the procurement process.
Technology issues
During operational evaluation in 2000, there was a fatal crash caused by the vortex ring state (VRS) condition.
The side-by-side rotor configuration of V-22 is susceptible to asymmetric onset of Vortex Ring State (VRS), brought on by descending too quickly. The one-rotor-in/one-rotor-out conditions results in large rolling moments and departure from controlled flight. Such a characteristic is fundamental and cannot be remedied by minor design changes. The only near-term solution is to restrict operations to avoid proximity to VRS region. V-22 advocates say V-22 pilots can escape vortex ring state by tilting the rotors forward to get out of helicopter mode. [5]
Deployment and variants
It was first deployed operationally in Iraq. Not surprisingly, since it is not a true helicopter and has different characteristics, field experience led to rethinking some of its roles. "or example, the introduction of the MV-22 into Iraq in combination with existing helicopters has led to some reconsideration of the appropriate role of each. Battlefield commanders and aircraft operators in Iraq identified a need to better understand the role the Osprey should play in fulfilling warfighter needs. They indicated, for example, that the MV-22 may not be best suited for the full range of missions requiring medium lift, because the aircraft’s speed cannot be exploited over shorter distances or in transporting external cargo. These concerns were also highlighted in a recent preliminary analysis of the MV-22 by the Center for Naval Analysis, which found that the MV-22 may not be the optimal platform for those missions."[6]
Note that the "M" prefix, in U.S. aircraft naming, normally denotes a special operations variant, where "C" designates a transport aircraft. The Marines and Air Force appear to have, for unclear reasons, reversed this convention. "H", as used by the Navy, is a proper prefix for search missions.
Boeing is responsible for building the fuselage, empennage, and all subsystems, digital avionics, and fly-by-wire control systems. Bell Helicopter Textron, Inc. is responsible for the wing, transmissions, rotor systes, engine installation and finally assembly at their assembly plant located in Amarillo, Texas, USA.
The Osprey was approved for full-rate production by United States Department of Defense in September 2005, with a USD $19 billion contract authorizing:[7]
- 360 (U.S. Marines)
- 50 (U.S. Air Force)
- 48 (U.S. Navy)
The 2010 production schedule calls for making 29 deliveries of the Osprey.
U.S. Marine Corps
MV-22 is the Marine Corps version of the Osprey which promises serve as an expeditionary aircraft with assault capabilities. The Marine version of the Osprey is designed as an assault aircraft and for use in special operations.
The USMC currently has five Osprey combat squadrons. VMM-263, were sent to Iraq in October 2007. This was the combat debut for the Osprey. Three squadrons were later deployed.
Afloat, several MV-22's made the first inaugural voyage with the 22nd Marine Expeditionary Unit in 2009. [8]
The Osprey was sent to Afghanistan in November 2009.
HV-22 is the United States Navy'w designation for the V-22. The USN version is designed to provide combat search and rescue, carrier onboard delivery, air refueling, the delivery of special warfare teams and their removal from the theater, and fleet support. [2]
Transport
In the carrier onboard delivery and vertical replenishment roles, its capacity is:[9]
Aerial refuelingCapabilities:[10]
&80-91 ft hose length In a typical carrier refueling scenario, the operating cycle would be: [11]
U.S. Air ForceCV-22 is the Air Force designation of the V-22. Air Force Special Operations Command received the Osprey in 2006, and first deployed to Mali, for a 15-nation cooperative effort under United States Africa Command, Exercise Flintlock of November 2008.[12] The Ospreys carried Malian and Senegalese special operations soldiers and their command team. Lt. Col. Eric Hill, leading the 8th Special Operations Squadron (SOS), onserved "The tyranny of distance in the African continent is amazing. We were able to go over 500 nautical miles, infiltrate a small team for them to run their exercise, and bring them back all the way to home base without doing an air refueling stop. And we were able to do that in the span of about four hours. " Capt. Dennis Woodlief, an 8th SOS pilot, said "It would take the MH-53 PAVE LOW twice, sometimes three times as long (to do these missions). And we did it with just one aircraft." In Marine deployments in Iraq, the lesson that Ospreys can do missions alone, rather than in sections as is common with helicopters. Much was learned by the 1st Special Operations Helicopter Maintenance Squadron at a remote location, Bamako, Mali, with very limited base facilities, they had to deploy with everything needed to support operations 5,000 miles from home. "We have a laundry list about three pages long of things we'd like to take next time," said Master Sgt. Craig Kornely, the squadron's lead production supervisor. "As we grow into the machine, we realize our needs for equipment and resources." Woodlief said "We had zero maintenance cancels, zero delays, and we executed 100 percent every time. I think we went above and beyond everyone's expectations." TacticsLike any aircraft, experience tends to be needed to learn the unique tactical advantages and disadvantages of the Osprey. Early World War II, for example, the Japanese A6M Zero fighter was a fearsome opponent, but U.S. pilots learned that while it was a death sentence to try to turn with it in a dogfight, heavier fighters could win by diving on the Zero and firing on its totally unprotected areas. GAO said the "V-22 has maneuvering limits that restrict its ability to perform defensive maneuvers and it does not have a required integrated defensive weapon needed to suppress threats while approaching a landing zone, disembarking troops within the landing zone, or while leaving the landing zone. Currently, the Marine Corps intends to employ the aircraft in a manner that limits its exposure to threats mdash; a change from the original intent that the system would be able to operate in such environments.[13] Lieutenant Colonel Christopher ‘Mongo’ Seymour, who commanded the Marine VMM-266 Osprey squadron, spoke of some of the lessons learned. In mission planning, he said the Osprey had to be understood as more like an extremely agile version of the C-130 Hercules fixed wing transport, typically flying at medium altitude, than a helicopter that routinely skims the ground. Helicopter doctrine is "that you have to have two aircraft. So we wanted to carry out the task in some scenarios as a little brother to the C-130 – they don’t task a C-130 in sections and we are the same case." Seymour said that two Ospreys were often sent on missions that could easily have been handled by one. He predicted that its characteristics would do well in the mountains of Afghanistan. "We can trade fuel for payload and altitude. The other beauty about the Osprey is that the CH-46 – well even the CH-53 (it could do this but they don’t like to) – if it was a hard hit mission, picking up somebody who’s been hit, troops in contact etc, I could go to a high zone at 9,000 or 10,000 ft, drop somebody off and pick them up. And if the mission has been long and maybe I do not have enough gas to get back to Kabul, I could meet a tanker pretty easily and refuel and make it – which is the difference. Once I am in aeroplane mode, hover performance is not an issue any more. I could go to 60,500 lb at 20,000 ft just like that."[1] Addressing the survivability concerns, Seymour observed that the Osprey, at its normal altitude of 8-12,000 feet, is much quieter than a lower-flying helicopter, and is harder to see from the ground. "So nobody knows to look up – and even if they did a grey V-22 on a blue background is virtually impossible to spot. We have several tactical approaches that we use. Let me just tell you this, when I was in the test world I did a one-for-one comparison between a V-22 and an AH-1. The set-up was an array of acoustic sensors in a target area. We had to fly over the sensors on the same path, type of day etc. "So we fly the V-22 at 200 ft and 220 kts over these sensors at a five-mile range. Then the Cobra did it. The unclassified data showed that if you were at the target you would hear the Cobra two minutes before he reached you; with the V-22 it wasn’t heard until 10 seconds beforehand [the author experienced and can verify the quietness of the aircraft over several days at Al Asad with Ospreys, CH-46 Sea Knights, CH-53s, [UH-1]] Hueys and AH-1 Cobras flying in and out during the period – the V-22 was the quietest of the lot]." In other words, accept that an Osprey is not a pure helicopter substitute. Humanitarian assistanceIn January 2010, in support of the United States Southern Command, the 24th Marine Expeditionary Unit deployed aviation squadron VMM-162with 12 MV-22 Ospreys, four CH-53E Super Stallion heavy lift /transport helicopters, three UH-1N Huey helicopters and close air support jets and attack helicopters. It gave a new capability of "transporting 24 passengers or 12 aid litters (stretchers) that makes the aircraft a versatile mechanism for moving supplies, relief workers and medical personnel to disaster areas or casualties to health facilities."[14] Flying An OspreyThe pilot uses a single set of controls to fly the Osprey and can during flight switch from helicopter to fixed wing mode with ease by using automatic controls to switch from helicopter to fixed wing mode. The nacelle angle is controlled by the pilot using the nacelle control. The pilot can also adjust for angle, acceleration for forward or aft and control aircraft pitch. The nacelle control complements the longitudinal cyclic stick and includes automatic conversion corridor protection control. During flight the nacelles will begin to rotate allowing the craft to switch from helicopter mode to airplane mode. The process is called transition. During transition the pilot can manually control the operation or opt for automatic transition using the flight control system. It takes approximately 16 seconds to complete the transition process. In the case of the Osprey, the nacelle is used to house or enclose the aircraft's engine. Conversion is the opposite process. The Osprey will switch from aircraft mode to helicopter mode during the conversion process. Again, the nacelles are a key part of the conversion process. Both the transition and conversion modes of flying can take place continuously, stopped as needed, or reversed. Airplane flight though needs to take place when the Osprey is flying between 40 to 80 knots and has a wide range of permissible air speeds (approximately 100 knots). Logistics and supportBell Boeing operates a logistics support center in New Bern, North Carolina. This is close to the Marine Corps Air Station at Cherry Point, the main location for Marine Osprey operational development. [15] On 15 June 2009, Bell Boeing Program Office received an $11 million dollar, Phase 1.5 of a two-phase Joint Performance Based Logistics (PBL) contract from the U.S. Department of Defense to support the V-22 Osprey tiltrotor aircraft for the Marine Corps (MV-22), and Air Force Special Operations Command (CV-22).[16] CharacteristicsA baseline configuration has the following charactistics: [17]
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