venerdì 5 giugno 2020

Il Bell Boeing V-22 Osprey (falco pescatore)


Il Bell Boeing V-22 Osprey (falco pescatore) è un convertiplano medio ad uso militare prodotto dalla Bell, per le forze armate statunitensi.



Questo velivolo è il risultato del programma JVX (Joint Vertical-lift Experimental) avviato nel dicembre 1981, varato dall'allora Segretario alla Difesa degli Stati Uniti, Frank Carlucci. La commessa venne assegnata congiuntamente alla Bell Helicopter Textron e alla Boeing Vertol. La necessità di un velivolo di tali caratteristiche fu formulata dalla US Navy e dal US Army, che chiedevano la trasportabilità di 24 soldati equipaggiati a 370 km di distanza.
Il primo prototipo del velivolo V-22 Osprey fu presentato ufficialmente ad Arlington, Texas, il 23 maggio 1988. Il 1º dicembre 1989 il Segretario alla Difesa Dick Cheney decretò la sospensione dell'intero programma, a causa del notevole aumento dei costi di produzione. Il programma è stato in seguito riattivato e il 2 maggio 2008 si è avuta la prima missione di combattimento in Iraq dopo un semestre di impiego operativo prevalentemente nel ruolo di trasporto.



Caratteristiche

Questo velivolo è basato sulla tecnologia e sulle esperienze della Bell con il velivolo sperimentale XV-15 del 1977. I suoi motori basculanti lo rendono in grado di effettuare collegamenti da piazzole di atterraggio per elicottero o anche parcheggi, con la velocità di trasferimento di un aereo ad elica convenzionale.
I requisiti iniziali erano per un mezzo da assalto anfibio in grado di trasportare truppe, equipaggiamento e rifornimenti per altre navi da sbarco e mezzi terrestri. Il futuro V-22 era descritto come "un mezzo bimotore, con doppio pilota, auto-dispiegabile, con capacità di trasporto media, decollo ed atterraggio verticale (VTOL) a rotori basculanti progettato per il combattimento, il supporto al combattimento e le missioni di operazioni speciali su scala mondiale". La necessità operativa era quella di rimpiazzare i CH-46E e CH-53D, in fase di obsolescenza. I costi in crescita e l'allungamento dei tempi di sviluppo hanno in realtà fatto in modo che le cose andassero diversamente.



Versioni

I Marines statunitensi stanno utilizzando una unità sperimentale equipaggiata con il V-22, anche se due degli esemplari di valutazione sono andati persi nel 2000 a causa di un incidente, con la morte di tutto l'equipaggio e dei passeggeri, ed un prototipo era andato perso nel 1992, anch'esso con la morte dell'equipaggio. Altre versioni sono previste per l'esercito (UV-22), con un gancio baricentrico che lo rende in grado di trasportare un Humvee o un pezzo di artiglieria leggera, per la marina (HV-22) e per l'aeronautica (CV-22).



Evoluzione

Dopo 25 anni di sviluppo, ed un notevole incremento dei costi (dai 49 milioni di dollari iniziali si è passati ai 119 milioni del 2007), l'Osprey è arrivato all'impiego operativo. In effetti, il programma è stato riesumato in virtù delle forti pressioni lobbistiche e nonostante il parere fortemente contrario del segretario alla difesa statunitense Cheney. Nel frattempo, nei 25 anni di sviluppo, 30 tra civili e militari sono morti durante le prove.
Molte polemiche sono sorte anche in seguito alla rinuncia da parte del corpo dei Marines sia al requisito della capacità di autorotazione, unica possibilità di atterraggio di fortuna per un elicottero in caso di avaria ai motori, sia per la mancanza di una mitragliera anteriore. Tuttavia, l'Osprey, in caso di necessità, è in grado di atterrare planando come un normale aeroplano, e la mancanza di un'arma frontale non appare essenziale per un velivolo destinato specificamente al trasporto truppe e quindi bisognoso di essere comunque scortato da velivoli armati.



Versioni:
  • V-22A: modello di pre produzione in scala ridotta usato per i test di volo.
  • CV-22B: versione per operazioni speciali, adatta all'infiltrazione e all'esfiltrazione a lungo raggio di uomini e materiali in ambiente notturno, prodotta in 51 esemplari per l'United States Special Operations Command (USSOCOM) dell'U.S. Air Force, ed introdotta in servizio nel marzo 2006 presso la Kirtland AFB. La capacità carburante è pari a 2 230 litri, e nel vano di carico possono trovare posto tre serbatoi supplementari da 200 o 430 galloni. La dotazione elettronica comprende un radar multi mode Raytheon AN/APQ-186, sensore elettro-ottico (FLIR) Raytheon AN/ALQ-27, sistema di autodifesa SIRFC (Suite of Integrated Radio Frequency Countermeasures) AN/ALQ-211(V)2 con lanciatore di chaff/flares AN/ALE-47 e sistema DIRMC (Directional Infrared Counter Measures) AN/AQQ-24 Nemesis. L'equipaggio è composto da due piloti e due ingegneri di volo e dispone di un avanzato glass cockpit con quattro schermi MFD, una Central Display Unit, un Head-up display utilizzabile con occhiali da visione notturna (NVG), e Helmet Mounted Display. Il vano di carico consente di trasportare 4 540 kg di materiali, o 24 soldati seduti o 32 seduti sul pavimento. L'armamento difensivo è composto da una mitragliatrice Browning M2 da 12,7 mm o M240 da 7,62 mm, mentre per la difesa passiva vi sono pannelli di blindatura sul pavimento.




Utilizzatori

Stati Uniti - United States Air Force

54 CV-22B ordinati, 52 in servizio al settembre 2019, che saranno tutti aggiornati con il radar Raytheon AN/APQ-187 SKR (Silent Knight Radar) entro la fine del 2021.

8th Special Operations Squadron (8 SOS) presso l'Hurlburt Field, Florida
71st Special Operations Squadron (71 SOS) presso l'Kirtland Air Force Base, Nuovo Messico
20th Special Operations Squadron (20 SOS) presso l'Cannon Air Force Base, Nuovo Messico.

United States Navy - 39 CMV-22B ordinati a giugno 2018 e destinati al ruolo COD (Carrier On-Board Delivery, i collegamenti con le portaeromobili) in sostituzione dei C-2 Greyhound. Il primo esemplare è stato consegnato agli inizi di febbraio 2020.

United States Marine Corps Aviation - 360 esemplari ordinati. 253 in servizio al marzo 2018. 12 MV-22B sono in carico all'HMX-1 Marine Helicopter Squadron "Nighthawks" che si occupa del trasporto a corto raggio del Presidente degli Stati Uniti d'America.

VMM-162
VMM-261
VMM-263
VMM-264
VMM-266
VMM-365
VMMT-204 - Squadron addestrativo
VMX-22 - Marine Tiltrotor Operational Test and Evaluation Squadron (Squadrone di test e valutazione)




Giappone - Rikujō Jieitai

5 macchine allo standard V-22B Block C ordinate il 14 luglio 2015. All'Agosto 2017 risultano ordinati 17 V-22B Block C di cui uno già consegnato.







Potenziali operatori

India

Nel 2015 l'Indian Aviation Research Centre (ARC) si è interessata all'acquisto di quattro V-22 per l'evacuazione del personale in condizioni ostili, i rifornimenti logistici e il dispiegamento della Special Frontier Force (SFF) nelle zone di confine. L'India l'aveva visto svolgere operazioni di soccorso in seguito al terremoto in Nepal dell'aprile 2015. Elementi della Marina indiana hanno anche preso in considerazione il V-22 piuttosto che l'E-2D per l'allarme e il controllo aereo per sostituire il Kamov Ka-31 a corto raggio. L'India è interessata ad acquistare sei versioni d'attacco V-22 per l'inserimento rapido delle truppe nelle zone di confine.




Israele

Israele aveva mostrato interesse per il V-22. Nel 2009, Israele favorì il Sikorsky CH-53K rispetto al V-22. Nel 2011, Israele era anche interessato a utilizzare il V-22 per sostenere operazioni speciali e missioni di ricerca e salvataggio. Nel 2013, Israele era interessato ad un possibile leasing da sei a otto velivoli per missioni di operazioni speciali; il tipo non è quello di fungere da sostituto dei velivoli a rotore esistenti.
Il 22 aprile 2013 è stato finalizzato un accordo per la vendita di sei V-22 alla Israel Air Force. Tuttavia, nell'ottobre 2014, i media hanno riferito che l'acquisto del V-22 da parte di Israele è stato rinviato o annullato a causa dei vincoli di bilancio e delle politiche di cambiamento. Nel dicembre 2014, la Lettera di accordo che offriva uno sconto di 400 milioni di dollari e la consegna anticipata è formalmente scaduta, il ministro della Difesa ha deciso di aspettare le elezioni del marzo 2015 per spingere per l'approvazione da parte di un nuovo gabinetto. Alla fine del 2016, Israele non aveva ancora ordinato il V-22; Israele sta invece mostrando interesse ad acquistare l'elicottero C-47 Chinook o il CH-53K. Al 2017, Israele ha congelato la valutazione del V-22 Osprey, "con una fonte di difesa senior che indica che il convertiplano non è in grado di eseguire alcune missioni attualmente condotte con i suoi elicotteri da trasporto Sikorsky CH-53".

Corea del Sud

Nel febbraio 2015, l'esercito sudcoreano ha mostrato interesse per il V-22 per il trasporto di forze speciali nelle isole del Mar Giallo vicino al territorio nordcoreano; nel corso del 2015 si sono tenuti colloqui sull'argomento.

Emirati Arabi Uniti

Nel maggio 2012, gli Emirati Arabi Uniti erano in fase di negoziazione finale per l'acquisto di diversi V-22. Gli Emirati Arabi Uniti intendevano utilizzarli per sostenere le forze speciali ad un costo unitario di 58 milioni di dollari. Il 10 novembre 2015, gli Emirati Arabi Uniti hanno selezionato una variante del convertiplano AgustaWestland AW609 per i compiti di ricerca e salvataggio, e hanno negato che ci fossero trattative in corso per quanto riguarda il V-22.


ENGLISH

The Bell Boeing V-22 Osprey is an American multi-mission, tiltrotor military aircraft with both vertical takeoff and landing (VTOL), and short takeoff and landing (STOL) capabilities. It is designed to combine the functionality of a conventional helicopter with the long-range, high-speed cruise performance of a turboprop aircraft.
The failure of Operation Eagle Claw during the Iran hostage crisis in 1980 underscored the requirement for a new long-range, high-speed, vertical-takeoff aircraft for the United States Department of Defense. In response, the Joint-service Vertical take-off/landing Experimental (JVX) aircraft program started in 1981. A partnership between Bell Helicopter and Boeing Helicopters was awarded a development contract in 1983 for the V-22 tiltrotor aircraft. The Bell Boeing team jointly produce the aircraft. The V-22 first flew in 1989, and began flight testing and design alterations; the complexity and difficulties of being the first tiltrotor for military service led to many years of development.
The United States Marine Corps began crew training for the MV-22B Osprey in 2000, and fielded it in 2007; it supplemented and then replaced their Boeing Vertol CH-46 Sea Knights. The U.S. Air Force fielded their version of the tiltrotor, CV-22B, in 2009. Since entering service with the U.S. Marine Corps and Air Force, the Osprey has been deployed in transportation and medevac operations over Iraq, Afghanistan, Libya, and Kuwait. The U.S. Navy plan to use the CMV-22B for carrier onboard delivery (COD) duties beginning in 2021.

Development

Origins

The failure of the Iran hostage rescue mission in 1980 demonstrated to the United States military a need for "a new type of aircraft, that could not only take off and land vertically but also could carry combat troops, and do so at speed." The U.S. Department of Defense began the Joint-service Vertical take-off/landing Experimental (JVX) aircraft program in 1981, under U.S. Army leadership.
The defining mission of the U.S Marine Corps (USMC) has been to perform an amphibious landing; the service quickly became interested in the JVX program. Recognizing that a concentrated force was vulnerable to a single nuclear weapon, airborne solutions with good speed and range allowed for rapid dispersal, and their CH-46s were wearing out. Without replacement, the USMC and the Army merging was a lingering threat, akin to President Truman's proposal following World War II. The OSD and Navy administration opposed the tiltrotor project, but congressional pressure proved persuasive.
The Navy and USMC were given the lead in 1983. The JVX combined requirements from the USMC, USAF, Army and Navy. A request for proposals (RFP) was issued in December 1982 for preliminary design work. Interest was expressed by Aérospatiale, Bell Helicopter, Boeing Vertol, Grumman, Lockheed, and Westland. Contractors were encouraged to form teams. Bell partnered with Boeing Vertol to submit a proposal for an enlarged version of the Bell XV-15 prototype on 17 February 1983. Being the only proposal received, a preliminary design contract was awarded on 26 April 1983.
The JVX aircraft was designated V-22 Osprey on 15 January 1985; by that March, the first six prototypes were being produced, and Boeing Vertol was expanded to handle the workload. Work was split evenly between Bell and Boeing. Bell Helicopter manufactures and integrates the wing, nacelles, rotors, drive system, tail surfaces, and aft ramp, as well as integrates the Rolls-Royce engines and performs final assembly. Boeing Helicopters manufactures and integrates the fuselage, cockpit, avionics, and flight controls. The USMC variant received the MV-22 designation and the USAF variant received CV-22; this was reversed from normal procedure to prevent USMC Ospreys from having a conflicting designation with aircraft carriers (CV). Full-scale development began in 1986. On 3 May 1986, Bell Boeing was awarded a $1.714 billion contract for the V-22 by the U.S. Navy. At this point, all four U.S. military services had acquisition plans for the V-22.
The first V-22 was publicly rolled out in May 1988. The project soon suffered several blows. That year, the U.S. Army left the program, citing a need to focus its budget on more immediate aviation programs. In 1989, the V-22 survived two separate Senate votes that could have resulted in cancellation. Despite the Senate's decision, the Department of Defense instructed the Navy not to spend more money on the V-22. When the projected development budget greatly increased in 1988, Defense Secretary Dick Cheney tried to defund it from 1989 to 1992 in order to cancel it. He was overruled by Congress, which provided unrequested program funding. Multiple studies of alternatives found the V-22 provided more capability and effectiveness with similar operating costs. The Clinton Administration was supportive of the V-22, helping it attain funding.

Flight testing and design changes

The first of six prototypes first flew on 19 March 1989 in the helicopter mode, and on 14 September 1989 in fixed-wing mode. The third and fourth prototypes successfully completed the first sea trials on USS Wasp in December 1990. The fourth and fifth prototypes crashed in 1991–92. From October 1992 – April 1993, the V-22 was redesigned to reduce empty weight, simplify manufacture, and reduce build costs; it was designated V-22B. Flights resumed in June 1993 after safety changes were made to the prototypes. Bell Boeing received a contract for the engineering manufacturing development (EMD) phase in June 1994. The prototypes were also modified to resemble the V-22B standard. At this stage, testing focused on flight envelope expansion, measuring flight loads, and supporting the EMD redesign. Flight testing with the early V-22s continued into 1997.
Flight testing of four full-scale development V-22s began at the Naval Air Warfare Test Center, Naval Air Station Patuxent River, Maryland. The first EMD flight took place on 5 February 1997. Testing soon fell behind schedule. The first of four low rate initial production aircraft, ordered on 28 April 1997, was delivered on 27 May 1999. The second sea trials were completed onboard USS Saipan in January 1999. During external load testing in April 1999, a V-22 transported the light-weight M777 howitzer.
In 2000, there were two further fatal crashes, killing a total of 23 marines, and the V-22 was again grounded while the crashes' causes were investigated and various parts were redesigned. In June 2005, the V-22 completed its final operational evaluation, including long-range deployments, high altitude, desert and shipboard operations; problems previously identified had reportedly been resolved.
U.S. Naval Air Systems Command worked on software upgrades to increase the maximum speed from 250 knots (460 km/h; 290 mph) to 270 knots (500 km/h; 310 mph), increase helicopter mode altitude limit from 10,000 feet (3,000 m) to 12,000 feet (3,700 m) or 14,000 feet (4,300 m), and increase lift performance. By 2012, changes had been made to the hardware, software, and procedures in response to hydraulic fires in the nacelles, vortex ring state control issues, and opposed landings; reliability has improved accordingly.
An MV-22 landed and refueled onboard Nimitz in an evaluation in October 2012. In 2013, cargo handling trials occurred on Harry S. Truman. In October 2015, NAVAIR tested rolling landings and takeoffs on a carrier, preparing for carrier onboard delivery.

Controversy

Development was protracted and controversial, partly due to large cost increases, some of which are caused by a requirement to fold wing and rotors to fit aboard ships. The development budget was first set at $2.5 billion in 1986, increasing to a projected $30 billion in 1988. By 2008, $27 billion had been spent and another $27.2 billion was required for planned production numbers. Between 2008 and 2011, the V-22's estimated lifetime cost grew by 61 percent, mostly for maintenance and support.
Its [The V-22's] production costs are considerably greater than for helicopters with equivalent capability—specifically, about twice as great as for the CH-53E, which has a greater payload and an ability to carry heavy equipment the V-22 cannot... an Osprey unit would cost around $60 million to produce, and $35 million for the helicopter equivalent.
In 2001, Lieutenant Colonel Odin Lieberman, commander of the V-22 squadron at Marine Corps Air Station New River, was relieved of duty after allegations that he instructed his unit to falsify maintenance records to make it appear more reliable. Three officers were implicated for their roles in the falsification scandal.
In October 2007, a Time Magazine article condemned the V-22 as unsafe, overpriced, and inadequate; the USMC responded that the article's data was partly dated, obsolete, inaccurate, and held expectations too high for any new field of aircraft. In 2011, the controversial defense industry supported Lexington Institute reported that the average mishap rate per flight hour over the past 10 years was the lowest of any USMC rotorcraft, approximately half of the average fleet accident rate. In 2011, Wired Magazine reported that the safety record had excluded ground incidents; the USMC responded that MV-22 reporting used the same standards as other Navy aircraft.
By 2012, the USMC reported fleetwide readiness rate had risen to 68 percent; however, the DOD's Inspector General later found 167 of 200 reports had "improperly recorded" information. Captain Richard Ulsh blamed errors on incompetence, saying that they were "not malicious" or deliberate. The required mission capable rate was 82%, but the average was 53% from June 2007 to May 2010. In 2010, Naval Air Systems Command aimed for an 85% reliability rate by 2018. From 2009 to 2014, readiness rates rose 25 percent to the "high 80s", while cost per flight hour had dropped 20 percent to $9,520 through a rigorous maintenance improvement program that focused on diagnosing problems before failures occur. As of 2015, although the V-22 requires more maintenance and has lower availability (62%) than traditional helicopters, it also has a lower incidence rate. The average cost per flight hour is US$9,156, whereas the Sikorsky CH-53E Super Stallion cost about $20,000 per flight hour in 2007. V-22 ownership cost was $83,000 per hour in 2013.
While technically capable of autorotation if both engines fail in helicopter mode, a safe landing is difficult. In 2005, a director of the Pentagon's testing office stated that in a loss of power while hovering below 1,600 feet (490 m), emergency landings "...are not likely to be survivable." V-22 pilot Captain Justin "Moon" McKinney stated that: "We can turn it into a plane and glide it down, just like a C-130." A complete loss of power requires both engines to fail, as one engine can power both proprotors via interconnected drive shafts. Though vortex ring state (VRS) contributed to a deadly V-22 accident, flight testing found it to be less susceptible to VRS than conventional helicopters. A GAO report stated that the V-22 is "less forgiving than conventional helicopters" during VRS. Several test flights to explore VRS characteristics were canceled. The USMC trains pilots in the recognition of and recovery from VRS, and has instituted operational envelope limits and instrumentation to help avoid VRS conditions.

Production

On 28 September 2005, the Pentagon formally approved full-rate production, increasing from 11 V-22s a year to between 24 and 48 a year by 2012. Of the 458 total planned, 360 are for the USMC, 50 for the USAF, and 48 for the Navy at an average cost of $110 million per aircraft, including development costs. The V-22 had an incremental flyaway cost of $67 million per aircraft in 2008, The Navy had hoped to shave about $10 million off that cost via a five-year production contract in 2013. Each CV-22 cost $73 million in the FY 2014 budget.
On 15 April 2010, the Naval Air Systems Command awarded Bell Boeing a $42.1 million contract to design an integrated processor in response to avionics obsolescence and add new network capabilities. By 2014, Raytheon will provide an avionics upgrade that includes Situational awareness and Blue Force Tracking. In late 2009, a contract for Block C upgrades was awarded to Bell Boeing. In February 2012, the USMC received the first V-22C, featuring a new radar, additional mission management and electronic warfare equipment. In 2015, options for upgrading all aircraft to the V-22C standard were examined.
On 12 June 2013, the U.S. DoD awarded a $4.9 billion contract for 99 V-22s in production Lots 17 and 18, including 92 MV-22s for the USMC, for completion in September 2019. A provision gives NAVAIR the option to order 23 more Ospreys. As of June 2013, the combined value of all contracts placed totaled $6.5 billion. In 2013, Bell started laying off production staff following defense cuts which reduced the US order to about half of the planned number. Production rate went from 40 in 2012 to 22 planned for 2015. Manufacturing robots have replaced older automated machines for increased accuracy and efficiency; large parts are held in place by suction cups and measured electronically.
In March 2014, Air Force Special Operations Command (AFSOC) issued a Combat Mission Need Statement for armor to protect V-22 passengers. NAVAIR worked with a Florida-based composite armor company and the Army Aviation Development Directorate to develop and deliver the Advanced Ballistic Stopping System (ABSS) by October 2014. Costing $270,000, the ABSS consists of 66 plates fitting along interior bulkheads and deck, adding 800 lb (360 kg) to the aircraft's weight, affecting payload and range. The ABSS can be installed or removed when needed in hours and partially assembled in pieces for partial protection of specific areas. As of May 2015, 16 kits had been delivered to the USAF.
In 2015, Bell Boeing set up the V-22 Readiness Operations Center (VROC) at Ridley Park, Pennsylvania to gather information from each aircraft to improve fleet performance in a similar manner as the F-35's Autonomic Logistics Information System (ALIS).

Design

Overview

The Osprey is the world's first production tiltrotor aircraft, with one three-bladed proprotor, turboprop engine, and transmission nacelle mounted on each wingtip. It is classified as a powered lift aircraft by the Federal Aviation Administration. For takeoff and landing, it typically operates as a helicopter with the nacelles vertical and rotors horizontal. Once airborne, the nacelles rotate forward 90° in as little as 12 seconds for horizontal flight, converting the V-22 to a more fuel-efficient, higher speed turboprop aircraft. STOL rolling-takeoff and landing capability is achieved by having the nacelles tilted forward up to 45°. Other orientations are possible. It has a ferry range of over 2,100 nmi. Its operational range is 1,100 nmi.
Composite materials make up 43% of the airframe, and the proprotor blades also use composites. For storage, the V-22's rotors fold in 90 seconds and its wing rotates to align, front-to-back, with the fuselage. Due to the requirement for folding rotors, their 38-foot (11.6 m) diameter is 5 feet (1.5 m) less than optimal for vertical takeoff, resulting in high disk loading. Most missions use fixed wing flight 75% or more of the time, reducing wear and tear and operational costs. This fixed wing flight is higher than typical helicopter missions allowing longer range line-of-sight communications for improved command and control.
Exhaust heat from the V-22's engines can potentially damage ships' flight decks and coatings. Naval Air Systems Command (NAVAIR) devised a temporary fix of portable heat shields placed under the engines, and determined that a long-term solution would require redesigning decks with heat resistant coating, passive thermal barriers, and ship structure changes. Similar changes are required for F-35B operations. In 2009, DARPA requested solutions for installing robust flight deck cooling. A heat-resistant anti-skid metal spray named Thermion has been tested on USS Wasp.

Propulsion

The V-22's two Rolls-Royce AE 1107C engines are connected by drive shafts to a common central gearbox so that one engine can power both proprotors if an engine failure occurs. Either engine can power both proprotors through the wing driveshaft. However, the V-22 is generally not capable of hovering on one engine. If a proprotor gearbox fails, that proprotor cannot be feathered, and both engines must be stopped before an emergency landing. The autorotation characteristics are poor partly due to the rotors' low inertia.
In September 2013, Rolls-Royce announced that it had increased the AE-1107C engine's power by 17% via the adoption of a new Block 3 turbine, increased fuel valve flow capacity, and software updates; it should also improve reliability in high-altitude, high-heat conditions and boost maximum payload limitations from 6,000 to 8,000 shp (4,500 to 6,000 kW). A Block 4 upgrade is reportedly being examined, which may increase power by up to 26 percent, producing close to 10,000 shp (7,500 kW), and improve fuel consumption.
In August 2014, the US military issued a request for information (RFI) for a potential drop-in replacement for the AE-1107C engines. Submissions must have a power rating of no less than 6,100 shp (4,500 kW) at 15,000 rpm, operate at up to 25,000 ft (7,600 m) at up to 130 degrees Fahrenheit (54 degrees Celsius), and fit into the existing wing nacelles with minimal structural or external modifications. In September 2014, the US Navy, who already purchase engines separately to airframes, was reportedly considering an alternative engine supplier to reduce costs. The General Electric GE38 is one option, giving commonality with the Sikorsky CH-53K King Stallion.
The V-22 has a maximum rotor downwash speed of over 80 knots (92 mph; 150 km/h), more than the 64-knot (74 mph; 119 km/h) lower limit of a hurricane. The rotorwash usually prevents the starboard door's usage in hover; the rear ramp is used for rappelling and hoisting instead. The V-22 loses 10% of its vertical lift over a tiltwing design when operating in helicopter mode due to the wings' airflow resistance, while the tiltrotor design has better short takeoff and landing performance. V-22s must keep at least 25 ft (7.6 m) of vertical separation between each other to avoid each other's rotor wake, which causes turbulence and potentially control loss.

Avionics

The V-22 is equipped with a glass cockpit, which incorporates four Multi-function displays (MFDs, compatible with night-vision goggles) and one shared Central Display Unit (CDU), to display various images including: digimaps, imagery from the Turreted Forward Looking Infrared System primary flight instruments, navigation (TACAN, VOR, ILS, GPS, INS), and system status. The flight director panel of the Cockpit Management System (CMS) allows for fully coupled (autopilot) functions that take the aircraft from forward flight into a 50 ft (15 m) hover with no pilot interaction other than programming the system. The glass cockpit of the canceled CH-46X was derived from the V-22. The fuselage is not pressurized, and personnel must wear on-board oxygen masks above 10,000 feet.
The V-22 has triple-redundant fly-by-wire flight control systems; these have computerized damage control to automatically isolate damaged areas. With the nacelles pointing straight up in conversion mode at 90° the flight computers command it to fly like a helicopter, cyclic forces being applied to a conventional swashplate at the rotor hub. With the nacelles in airplane mode (0°) the flaperons, rudder, and elevator fly similar to an airplane. This is a gradual transition, occurring over the nacelles' rotation range; the lower the nacelles, the greater effect of the airplane-mode control surfaces. The nacelles can rotate past vertical to 97.5° for rearward flight. The V-22 can use the "80 Jump" orientation with the nacelles at 80° for takeoff to quickly achieve high altitude and speed. The controls automate to the extent that it can hover in low wind without hands on the controls. Some V-22 pilots claim that former fixed-wing pilots may be preferable over helicopter users as they are not trained to constantly adjust the controls in hover.

Armament

The V-22 can be armed with one 7.62×51mm NATO (.308 in caliber) M240 machine gun or .50 in caliber (12.7 mm) M2 machine gun on the rear loading ramp. A 12.7 mm (.50 in) GAU-19 three-barrel Gatling gun mounted below the nose was studied. BAE Systems developed a belly-mounted, remotely operated gun turret system, the Interim Defense Weapon System (IDWS); it is remotely operated by a gunner, targets are acquired via a separate pod using color television and forward looking infrared imagery. The IDWS was installed on half of the V-22s deployed to Afghanistan in 2009; it found limited use due to its 800 lb (360 kg) weight and restrictive rules of engagement.
There were 32 IDWSs available to the USMC in June 2012; V-22s often flew without it as the added weight reduced cargo capacity. The V-22's speed allows it to outrun conventional support helicopters, thus a self-defense capability was required on long-range independent operations. The infrared gun camera proved useful for reconnaissance and surveillance. Other weapons were studied to provide all-quadrant fire, including nose guns, door guns, and non-lethal countermeasures to work with the current ramp-mounted machine gun and the IDWS.
In 2014, the USMC studied new weapons with "all-axis, stand-off, and precision capabilities", akin to the AGM-114 Hellfire, AGM-176 Griffin, Joint Air-to-Ground Missile, and GBU-53/B SDB II. In November 2014, Bell Boeing conducted self-funded weapons tests, equipping a V-22 with a pylon on the front fuselage and replacing the AN/AAQ-27A EO camera with an L-3 Wescam MX-15 sensor/laser designator. 26 unguided Hydra 70 rockets, two guided APKWS rockets, and two Griffin B missiles were fired over five flights. The USMC and USAF sought a traversable nose-mounted weapon connected to a helmet-mounted sight; recoil complicated integrating a forward-facing gun. A pylon could carry 300 lb (140 kg) of munitions. However, by 2019, the USMC opted for IDWS upgrades over adopting new weapons.

Refueling capability

Boeing is developing a roll-on/roll-off aerial refueling kit, which would give the V-22 the ability to refuel other aircraft. Having an aerial refueling capability that can be based on Wasp-class amphibious assault ships would increase the F-35B's strike power, removing reliance on refueling assets solely based on large Nimitz-class aircraft carriers or land bases. The roll-on/roll-off kit can also be applicable to intelligence, surveillance and reconnaissance (ISR) functions. Boeing funded a non-functional demonstration on a VMX-22 aircraft; a prototype kit was successfully tested with an F/A-18 on 5 September 2013.
The high-speed version of the hose/drogue refueling system can be deployed at 185 knots (213 mph; 343 km/h) and function at up to 250 knots (290 mph; 460 km/h). A mix of tanks and a roll-on/roll-off bladder house up to 12,000 lb (5,400 kg) of fuel. The ramp must open to extend the hose, then raised once extended. It can refuel rotorcraft, needing a separate drogue used specifically by helicopters and a converted nacelle. Many USMC ground vehicles can run on aviation fuel, a refueling V-22 could service these. In late 2014, it was stated that V-22 tankers could be in use by 2017, but contract delays pushed IOC to late 2019. As part of a 26 May 2016 contract award to Boeing, Cobham was contracted to adapt their FR-300 hose drum unit as used by the KC-130 in October 2016. While the Navy has not declared its interest in the capability, it could be leveraged later on.

Operational history

By early October 2019, the fleet of 375 Ospreys in service in the US Air Force, the US Marine Corps and the US Navy surpassed the 500,000 flight hour mark.

U.S. Marine Corps

Since March 2000, VMMT-204 has conducted training for the type. On 3 June 2005, squadron Marine Medium Helicopter 263 (HMM-263) stood down to transition to the MV-22. On 8 December 2005, Lieutenant General James Amos, commander of II Marine Expeditionary Force, accepted delivery of the first batch of MV-22s. The unit reactivated on 3 March 2006 as the first MV-22 squadron, redesignated as VMM-263. On 23 March 2007, HMM-266 became Marine Medium Tiltrotor Squadron 266 (VMM-266).
The MV-22 reached initial operational capability (IOC) on 13 June 2007. It started replacing the CH-46 Sea Knight in 2007; the CH-46 was retired in October 2014. On 13 April 2007, the USMC announced the first V-22 combat deployment at Al Asad Airbase, Iraq. On 10 July 2007, an MV-22 landed aboard the Royal Navy aircraft carrier HMS Illustrious, the first time it landed on a non-U.S. vessel. On 17 September 2007, 10 MV-22Bs of VMM-263 left for Iraq aboard USS Wasp; the decision to go by ship instead of self-deploying was made due to icing concerns during the North Atlantic portion of the trip, lack of available KC-130s for mid-air refueling, and Wasp's availability.
V-22s in Iraq's Anbar province were used for transport and riskier scout missions. General David Petraeus, the top U.S. military commander in Iraq, used one to visit troops on Christmas Day 2007; as did then-presidential candidate Barack Obama during his 2008 tour of Iraq. Obtaining spares proved problematic. By July 2008, the V-22 had flown 3,000 sorties totaling 5,200 hours in Iraq. General George J. Trautman, III praised its increased speed and range over legacy helicopters, saying "it turned his battle space from the size of Texas into the size of Rhode Island." Despite frequent attacks by man-portable air-defense systems and small arms, none were lost to enemy fire by late 2009.
A Government Accountability Office study stated that by January 2009, the 12 MV-22s in Iraq had completed all assigned missions; mission capable rates averaged 57% to 68%, and an overall full mission capable rate of 6%. It also noted weaknesses in situational awareness, maintenance, shipboard operations and transport capability. The report concluded: "...deployments confirmed that the V-22’s enhanced speed and range enable personnel and internal cargo to be transported faster and farther than is possible with the legacy helicopters..."
MV-22s deployed to Afghanistan in November 2009 with VMM-261; it saw its first offensive combat mission, Operation Cobra's Anger, on 4 December 2009. V-22s assisted in inserting 1,000 USMC and 150 Afghan troops into the Now Zad Valley of Helmand Province in southern Afghanistan to disrupt Taliban operations. On 18 February 2011, General James Amos stated that Afghanistan's MV-22s had surpassed 100,000 flight hours, calling it "the safest airplane, or close to the safest airplane" in the USMC inventory.
In January 2010, the MV-22 was sent to Haiti as part of Operation Unified Response relief efforts after an earthquake, the type's first humanitarian mission. In March 2011, two MV-22s from Kearsarge helped rescue a downed USAF F-15E crew member during Operation Odyssey Dawn. On 2 May 2011, following Operation Neptune's Spear, the body of Osama bin Laden, founder of the al-Qaeda terrorist group, was flown by a MV-22 to the aircraft carrier Carl Vinson in the Arabian Sea, prior to his burial at sea.
In 2013, several MV-22s received communications and seating modifications to support the Marine One presidential transport squadron due to the urgent need for CH-53Es in Afghanistan. On 11 August 2013, two MV-22s from Marine Helicopter Squadron One (HMX-1) made their debut ferrying Secret Service agents, White House staff, and press members from CGAS Cape Cod to Martha's Vineyard during the President's vacation. In May 2010, Boeing announced plans to submit the V-22 for the VXX presidential transport replacement.
Several Japanese politicians and Okinawa residents opposed a V-22 deployment to Japan in July 2012, mainly due to several high-profile accidents. On 14 June 2013, an MV-22 landed on JS Hyūga off the coast of California, the first time a V-22 had landed on a Japan Maritime Self-Defense Force vessel. In January 2014, a MV-22 landed aboard the French Mistral-class amphibious assault ship Dixmude. A MV-22 landed on ROKS Dokdo on 26 March 2015, the first such landing on a Republic of Korea Navy amphibious ship.
From 2 to 5 August 2013, two MV-22s completed the longest distance Osprey tanking mission to date. Flying from Marine Corps Air Station Futenma in Okinawa alongside two KC-130J tanker aircraft, they flew to Clark Air Base in the Philippines on 2 August, then to Darwin, Australia on 3 August, Townsville, Australia on 4 August, and finally rendezvoused with Bonhomme Richard on 5 August.
In 2013, the USMC formed an intercontinental response force, the Special Purpose Marine Air-Ground Task Force - Crisis Response - Africa (SPMAGTF-CR-AF), using V-22s outfitted with specialized communications gear. In 2013, following Typhoon Haiyan, 12 MV-22s of the 3rd Marine Expeditionary Brigade were deployed to the Philippines for disaster relief operations; its abilities were described as "uniquely relevant", flying faster and with greater payloads while moving supplies throughout the island archipelago. In 2014, the SPMAGTF-CR-AF supported a time-critical effort against the Ebola virus epidemic in Liberia, flying 1,200 people and 78,000 lb (35 t) of cargo in V-22s.
The V-22 deployment to Afghanistan was set to conclude in late 2013 with the drawdown of combat operations; however, VMM-261 was directed to extend operations for a new role, casualty evacuation, being better suited than helicopters as its speed better enabled casualties to reach a hospital within the 'golden hour'; they were fitted with medical equipment such as heart-monitors and basic triage supplies.
In November 2014, three MV-22Bs were placed on alert at Al Jaber Air Base in Kuwait to be ready within 30 minutes to recover downed pilots during the Military intervention against ISIL. On 29 occasions between 1 November and 24 April 2015, two V-22s and a KC-130J tanker spent 145 flight hours standing by for rescue missions; however, the only downed pilot landed too close to ISIL forces and lacked a radio.
In January 2017, during a special forces raid in Yemen, two MV-22s helped to evacuate ground troops. One suffered a hard landing after an engine failure, injuring two of the crew; a bomb later destroyed it. In December 2018, Melania Trump became the first First Lady of the United States to fly in the V-22, from Anacostia–Bolling to Langley–Eustis and from there to the USS George H.W. Bush supercarrier.

U.S. Air Force

The USAF's first operational CV-22 was delivered to the 58th Special Operations Wing (58th SOW) at Kirtland Air Force Base, New Mexico on 20 March 2006. Early aircraft were delivered to the 58th SOW and used for training personnel for special operations use. On 16 November 2006, the USAF officially accepted the CV-22 in a ceremony conducted at Hurlburt Field, Florida. It first used the CV-22 on a non-training mission to perform search and rescue from Kirtland Air Force Base on 4 October 2007.
The USAF's first operational deployment sent four CV-22s to Mali in November 2008 in support of Exercise Flintlock. The CV-22s flew nonstop from Hurlburt Field, Florida with in-flight refueling. AFSOC declared that the 8th Special Operations Squadron reached Initial Operational Capability on 16 March 2009, with six CV-22s in service.
In June 2009, CV-22s of the 8th Special Operations Squadron delivered 43,000 pounds (20,000 kg) of humanitarian supplies to remote villages in Honduras that were not accessible by conventional vehicles. In November 2009, the 8th SO Squadron returned from a three-month deployment in Iraq.
In August 2012, the USAF found that "CV-22 wake modeling is inadequate for a trailing aircraft to make accurate estimations of safe separation from the preceding aircraft."
On 21 December 2013, three CV-22s came under small arms fire while trying to evacuate American civilians in Bor, South Sudan during the 2013 South Sudanese political crisis; the aircraft flew 500 mi (800 km) to Entebbe, Uganda after the mission was aborted. South Sudanese officials stated that the attackers were rebels. The CV-22s had flown to Bor over three countries across 790 nmi (910 mi; 1,460 km). The formation was hit 119 times, wounding four crew and causing flight control failures and hydraulic and fuel leaks on all three aircraft. Due to fuel leaks, multiple air-to-air refuelings were performed en route. After the incident, AFSOC developed optional armor floor panels.
On 3 July 2014, V-22s carried Delta Force commandos to a campsite in eastern Syria where Islamic State militants had held American and other hostages. The militants were eliminated, but the hostages had been moved elsewhere, thus the commandos returned empty handed.
In 2015, the USAF sought to configure the CV-22 to perform combat search and rescue in addition to its long-range special operations transport mission. It would complement the HH-60G Pave Hawk and planned HH-60W rescue helicopters, being employed in scenarios where high speed is better suited to search and rescue than more nimble but slower helicopters. On 5 April 2018, the USAF announced that it is to deploy five CV-22s to Yokota Air Base in Japan earlier than planned to "address regional security concerns".

U.S. Navy

The V-22 program originally included Navy 48 HV-22s, but none were ordered. In 2009, it was proposed that it replace the C-2 Greyhound for carrier onboard delivery (COD) duties. One advantage of the V-22 is the ability to deliver supplies and people between non-carrier ships beyond helicopter range. Proponents said that it is capable of similar speed, payload capacity, and lift performance as the C-2, and can carry greater payloads over short ranges, up to 20,000 lb, including suspended external loads. The C-2 can only deliver cargo to carriers, requiring further distribution to smaller vessels via helicopters, while the V-22 is certified for operating upon amphibious ships, aircraft carriers, and logistics ships. It could also take some helicopter roles by fitting a 600 lb hoist to the ramp and a cabin configuration for 12 non-ambulatory patients and 5 seats for medical attendants. Bell and P&W designed a frame for the V-22 to transport the Pratt & Whitney F135 engine of the Lockheed Martin F-35.
On 5 January 2015, the Navy and USMC signed a memorandum of understanding (MOU) to buy the V-22 for the COD mission, and was confirmed in the Navy's FY 2016 budget. Initially designated HV-22, four aircraft would be bought each year from 2018–2020. It incorporates an extended-range fuel system for an 1,150 nmi (1,320 mi; 2,130 km) unrefueled range, a high-frequency radio for over-the-horizon communications, and a public address system to communicate with passengers; the range increase comes from extra fuel bladders through larger external sponsons, the only external difference from other variants. Its primary mission is long-range logistics, other conceivable missions include personnel recovery and special warfare. In February 2016, the Navy officially designated it as the CMV-22B. The Navy's program of record originally called for 48 aircraft, it later determined that only 44 were required. Production begun in FY 2018 and deliveries start in 2020.
Bell Boeing have pitched the V-22 as a platform for various missions, such as communications, electronic warfare, or aerial refueling; the Navy has a known gap in tactical aerial refueling. Other roles include search and rescue and anti-submarine warfare.
The Navy ordered the first 39 CMV-22Bs in June 2018; initial operating capability is anticipated to be achieved in 2021, with fielding to the fleet by the mid-2020s. The first CMV-22B made its initial flight in December 2019, which was announced publicly on 21 January 2020.

Japan Self-Defense Forces

In 2012, former Defense Minister Satoshi Morimoto ordered an investigation of the costs of V-22 operations. The V-22 exceeds current Japan Self-Defense Forces helicopters in terms of range, speed, and payload. The ministry anticipated deployments to the Nansei Islands and the Senkaku Islands, as well as in multinational cooperation with the U.S. Japan considered plans to have V-22s in service in a maritime role by as early as 2015. On 21 November 2014, the Japanese Ministry of Defense officially decided to procure 17 V-22s, with deliveries planned from FY 2014 to FY 2019. In January 2015, Japan's parliament approved a defense budget with funding for five V-22s. The first V-22 for Japan was delivered in August 2017.
In September 2018, the Japanese Ministry of Defense decided to delay the deployment of the first five MV-22B aircraft it had received amid opposition and ongoing negotiations in the Saga prefecture, where the aircraft are to be based.

Potential operators

India

In 2015 the Indian Aviation Research Centre (ARC) became interested in acquiring four V-22s for personnel evacuation in hostile conditions, logistic supplies, and deployment of the Special Frontier Force (SFF) in border areas. India had seen it perform in relief operations of the April 2015 Nepal earthquake. Elements of the Indian Navy have also looked at the V-22 rather than the E-2D for Airborne early warning and control to replace the short-range Kamov Ka-31. India is interested in purchasing six attack version V-22s for rapid troop insertion in border areas.

Israel

Israel had shown interest in the V-22. In 2009, Israel reportedly favored the Sikorsky CH-53K over the V-22. In 2011, Israel was interested in using the V-22 to support special operations and search and rescue missions. In 2013, Israel was interested in a possible lease of six to eight aircraft for special operations missions; the type is not to act as a replacement for existing rotorcraft.
On 22 April 2013, an agreement was finalized to sell six V-22 to the Israel Air Force. However, in October 2014, media reports implied Israel's deferment or cancelling of its V-22 procurement due to budget restraints and changing policies. In December 2014, the Letter of Agreement offering a $400 million discount and early delivery formally expired, the Defense Minister decided to wait until elections in March 2015 to push for approval from a new cabinet. By the end of 2016, Israel had not ordered the V-22; Israel is instead showing interest in buying the C-47 Chinook helicopter or the CH-53K helicopter. As of 2017, Israel had frozen its evaluation of the V-22 Osprey, "with a senior defence source indicating that the tiltrotor is unable to perform some missions currently conducted using its Sikorsky CH-53 transport helicopters.”

South Korea

In February 2015, the South Korean army showed interest in the V-22 for delivering special forces to islands in the Yellow Sea near North Korean territory; talks were held during 2015 on the topic.

United Arab Emirates

In May 2012, it was reported that the United Arab Emirates was in the final negotiation stages to purchase several V-22s. It was reported that the UAE intended to use it to support special forces. Both the UAE and the Pentagon sought a $58 million unit cost. On 10 November 2015, UAE selected a variant of the AgustaWestland AW609 tiltrotor for search and rescue duties, and denied that there were current negotiations regarding the V-22.

Variants

V-22A

Pre-production full-scale development aircraft used for flight testing. These are unofficially considered A-variants after the 1993 redesign.

CV-22B

U.S. Air Force variant for the U.S. Special Operations Command (USSOCOM). It conducts long-range special operations missions, and is equipped with extra wing fuel tanks, an AN/APQ-186 terrain-following radar, and other equipment such as the AN/ALQ-211, and AN/AAQ-24 Nemesis Directional Infrared Counter Measures. The fuel capacity is increased by 588 gallons (2,230 L) with two inboard wing tanks; three auxiliary tanks (200 or 430 gal) can also be added in the cabin. The CV-22 replaced the MH-53 Pave Low.

MV-22B

U.S. Marine Corps variant. The Marine Corps is the lead service in the V-22's development. The Marine Corps variant is an assault transport for troops, equipment and supplies, capable of operating from ships or expeditionary airfields ashore. It replaced the Marine Corps' CH-46E and CH-53D fleets.

CMV-22B

U.S. Navy variant for the carrier onboard delivery (COD) role. Similar to the MV-22B but includes an extended-range fuel system, a high-frequency radio, and a public address system.

EV-22

Proposed airborne early warning and control variant. The Royal Navy studied this AEW variant as a replacement for its current fleet of carrier-based Sea King ASaC.7 helicopters.

HV-22

The U.S. Navy considered an HV-22 to provide combat search and rescue, delivery and retrieval of special warfare teams along with fleet logistic support transport. It chose the MH-60S for this role in 2001. Naval Air Systems Command's 2011/2012 V-22 Osprey Guidebook lists the HV-22 for the U.S. Navy with the USAF and USMC variants.

SV-22

Proposed anti-submarine warfare variant. The U.S. Navy studied the SV-22 in the 1980s to replace S-3 and SH-2 aircraft.

(Web, Google, Wikipedia, You Tube)































































giovedì 4 giugno 2020

Il radar di difesa aerea navale Raytheon AN / SPY-6V1 "SPY-6"



La società statunitense Raytheon ha ultimato i test operativi del suo nuovo radar di difesa aerea navale AN / SPY-6V1 SPY-6.


In data 1° giugno 2020, la società Raytheon ha completato i test operativi del radar AN / SPY-6 (V) 1 chiamato anche “SPY-6” dall’US NAVY. 
Questo nuovo radar offrirà nuove funzionalità per rilevare: 
  • missili balistici, 
  • missili da crociera
  •  e altre minacce come gli aerei.


La famiglia di radar navali avanzati “SPY-6” consente alle unità navali di rilevare e contrastare simultaneamente una serie di minacce aeree e navali. Sarà utilizzato soprattutto per la difesa aerea e missilistica su sette classi di navi. Il radar avanzato “SPY-6” offre agli operatori e ai comandanti più tempo per reagire identificando più minacce più rapidamente ed a distanze maggiori.
La famiglia SPY-6 è integrata, il che significa che consente di difendersi contemporaneamente da missili balistici, missili da crociera, aerei ostili e navi di superficie ed offre numerosi vantaggi rispetto ai radar tradizionali, tra cui: 
  • un intervallo di rilevamento significativamente maggiore, 
  • una maggiore sensibilità
  • e una discriminazione più accurata.


Raytheon Missiles & Defense, una delle quattro aziende che formano Raytheon Technologies, ha iniziato da tempo la costruzione in serie dei radar SPY-6 ed ha completato i test operativi con il primo array modulare 14'x14'. Ciò avvicina il sistema all'installazione sul primo cacciatorpediniere missilistico di flight III della Us Navy, l'USS Jack H. Lucas (DDG-125). Il radar sarà imbarcato su sette tipi di navi della Marina statunitense.
La Raytheon Missiles & Defense ha sotto contratto nove cacciatorpediniere classe DDG-51 Arleigh Burke per il programma SPY-6 e costruirà più sistemi per soddisfare la domanda della Marina USA.


La società ha investito oltre 500 milioni di $ in infrastrutture e miglioramenti delle capacità dell’SPY-6, compresa la tecnologia di automazione avanzata nel suo impianto di sviluppo radar di 30.000 piedi quadrati. La costruzione di aree di produzione ampliate per componenti radar chiave dovrebbe essere completata nel 2020. La Raytheon Company costruirà due ulteriori navi munite di radar SPY-6 per la Marina degli Stati Uniti con un contratto da $ 250 milioni. La compagnia è ora incaricata di consegnare un totale di nove navi radar ai cacciatorpediniere di flight III DDG-51. 
Il sistema radar AESA SPY-6 offre una portata e una sensibilità notevolmente migliorate rispetto ai sensori tradizionali con antenna passiva e offre alle navi disperse geograficamente la possibilità di condividere e agire sui dati dei sensori in modi mai prima utilizzati e offre alle Marine occidentali una flessibilità operativa senza precedenti per difendersi dai missili balistici e da crociera, nonché dalle minacce avanzate di superficie e aeree.
Fin dalla sua istituzione nel gennaio 2014, il programma SPY-6 ha raggiunto tutti e 20 i traguardi, in anticipo o nei tempi previsti. Il radar ha un track record di prestazioni, dimostrando le sue capacità multi-missione contro una serie di bersagli singoli e multipli, simultanei durante l'ampio programma di test della Marina. Ora in produzione presso l'avanzato Radar Development Facility di Raytheon, AN / SPY-6 (V) rimane in programma per la consegna al primo DDG 51 Flight III, il futuro USS Jack H Lucas (DDG 125). La prima consegna di AN / SPY-6 (V) 2 alla LHA-8, la nave da assalto anfibia classe America, in programma per il 2021.
SPY-6 è la famiglia di radar della Marina americana che esegue la difesa aerea e missilistica su sette classi di navi.




I DDG 51 Flight III Destroyer sono navi da combattimento equipaggiate con:

  • Radar multifunzione tridimensionale (portata, altitudine e azimut) AMDR
  • 
Aegis Combat System,

  • AN / SQQ-89 Suite ASW,

  • AN / SQS -53 sonar,

  • elicottero MH-60R,

  • Close-In Weapon System,

  • Cannone da 127/62 mm,

  • Sistema di lancio verticale in grado di lanciare Tomahawk,
Missili standard (SM-2, -3 e -6) 
  • e Evolved SeaSparrow Missiles (ESSMs).

Il radar AMDR (Air and Missile Defense Radar, ora ufficialmente chiamato AN / SPY-6) è un radar 3D  la difesa aerea e missilistica in avanzata fase di sviluppo per la Marina degli Stati Uniti. 


Il sistema AESA fornirà difesa Aerea missilistica integrata; sono in fase di sviluppo varianti per il retrofit dei caccia Burke Flight IIA e per l'installazione a bordo delle nuove fregate di Fincantieri FFG (X), per le portaerei classe FORD e per le LPD classe San Antonio.


Sviluppo

Il 10 ottobre 2013, "Raytheon Company (RTN) si aggiudicò un contratto cost-plus-di-incentivazione di $ 385.742.176 per la progettazione, lo sviluppo, l'integrazione, il collaudo e la consegna di Air and Missile Defence dello sviluppo di ingegneria e produzione (EMD) Radar S-band (AMDR-S) e Radar Suite Controller (RSC).  Nel settembre 2010, l’Us Navy assegnò contratti di sviluppo tecnologico alla Northrop Grumman, alla Lockheed Martin ed alla Raytheon per lo sviluppo del radar in banda S e del controller suite radar (RSC). Secondo quanto riferito, lo sviluppo del radar in banda X sarà oggetto di contratti separati. A far data dal 2016, la Marina USA sta installando l’AMDR sui caccia flight III della classe Arleigh Burke: le navi attualmente montano il sistema di combattimento Aegis, prodotto dalla Lockheed Martin. 
Nel 2013, la Marina ha tagliato quasi $ 10 miliardi dal costo del programma adottando un sistema meno voluminoso capace di affrontare le "minacce future". Il programma comprende la fornitura di 22 radar per un costo totale di 6.598 milioni di $; i sistemi costeranno $ 300 milioni / unità nella produzione in serie. I test saranno ultimati per il 2021 e la capacità operativa iniziale è prevista per il marzo 2023. 



Tecnologia

Il sistema AMDR è costituito da due radar primari e da un controller suite radar (RSC) per coordinare i sensori. 

Un radar in banda S deve fornire:
  • ricerca volumetrica, 
  • tracciamento, 
  • discriminazione della difesa antimissile balistica, 
  • comunicazioni missilistiche, 

mentre il radar in banda X:
  • deve fornire ricerca all'orizzonte, 
  • tracciamento di precisione, 
  • comunicazione missilistica 
  • e illuminazione terminale degli obiettivi. 

I sensori in banda S e X condivideranno anche funzionalità tra cui: 
  • la navigazione radar, 
  • il rilevamento di periscopi, 
  • la guida e la comunicazione missilistica. 



L’AMDR è inteso come un sistema scalabile; la tuga Burke può ospitare solo una versione da 4,3 m (14 piedi) ma l'USN afferma di aver bisogno di un radar di almeno 6,1 m (20 piedi) per far fronte alle future minacce relative ai missili balistici. Ciò richiederebbe un nuovo design della nave; i cantieri Ingalls hanno proposto la classe SAN ANTONIO come base per un incrociatore per la difesa antimissile balistica con AMDR da 6,1 m (20 piedi). Per ridurre i costi, i primi dodici set AMDR avranno un componente in banda X basato sul radar rotante SPQ-9B esistente, che sarà sostituito da un nuovo radar in banda X nel set 13 che sarà più capace contro le minacce future. I moduli di trasmissione e ricezione utilizzeranno la nuova tecnologia dei semiconduttori al nitruro di gallio. Ciò consentirà una maggiore densità di potenza rispetto ai precedenti moduli radar all’arseniuro di gallio. 
Il nuovo radar richiederà il doppio della potenza elettrica rispetto alla generazione precedente, generando oltre 35 volte più potenza radar.
Sebbene non fosse un requisito iniziale, l'AMDR potrebbe essere in grado di eseguire attacchi elettronici utilizzando la sua antenna AESA. Sistemi radar Airborne AESA, come l' APG-77 utilizzato sul F-22 Raptor, e l'APG-81 e APG-79 utilizzato sul F-35 Lightning II, e l'F / A-18 Super Hornet / EA-18G Growler che, rispettivamente, hanno dimostrato la loro capacità di condurre attacchi elettronici. 
I contendenti per il Next Generation Jammer della Marina hanno utilizzato i moduli al nitruro di gallio per i moduli di trasmissione-ricevitore (GaN) per i loro sistemi EW. La precisa direzionalità del raggio consentirebbe di attaccare le minacce aeree e di superficie con raggi strettamente diretti di onde radio ad alta potenza verso i velivoli, navi e missili ostili.
Il radar è 30 volte più sensibile e può gestire contemporaneamente oltre 30 volte gli obiettivi dell'attuale AN / SPY-1 D (V) al fine di contrastare i raid complessi e di grandi dimensioni. 

Versioni:
  • AN / SPY-6 (V) : AMDR con 37 RMA per DDG di classe Arleigh Burke Flight III.
  • AN / SPY-6 (V) 2: Altrimenti noto come Enterprise Air Surveillance Radar (EASR). Versione rotante e ridotta con 9 RMA per LPD Flight II classe San Antonio.
  • AN / SPY-6 (V) 3: versione fissa EASR per portaerei classe Gerald R. Ford e FFG (X).
  • AN / SPY-6 (V) 4: AMDR con 24 RMA da installare sul DDG di classe Ile Arleigh Burke flight IIA.


ENGLISH

The AMDR (Air and Missile Defense Radar, now officially named AN/SPY-6) is an active electronically scanned array air and missile defense 3D radar under development for the United States Navy

It will provide integrated air and missile defense, and even periscope detection, for the Flight III Arleigh Burke-class destroyers; variants are under development for retrofitting Burke Flight IIA, and installation aboard FFG(X), Ford-class aircraft carriers and San Antonio-class LPDs.

Development

On October 10, 2013, "Raytheon Company (RTN) [was] awarded a $385,742,176 cost-plus-incentive-fee contract for the Engineering and Manufacturing Development (EMD) phase design, development, integration, test and delivery of Air and Missile Defense S-band Radar (AMDR-S) and Radar Suite Controller (RSC)."  In September 2010, the Navy awarded technology development contracts to Northrop Grumman, Lockheed Martin, and Raytheon to develop the S-band radar and radar suite controller (RSC). X-band radar development reportedly will come under separate contracts. The Navy hopes to place AMDR on Flight III Arleigh Burke-class destroyers, possibly beginning in 2016. Those ships currently mount the Aegis Combat System, produced by Lockheed Martin.
In 2013, the Navy cut almost $10 billion from the cost of the program by adopting a smaller less capable system that will be challenged by "future threats". As of 2013 the program is expected to deliver 22 radars at a total cost of $6,598m; they will cost $300m/unit in serial production.Testing is planned for 2021 and Initial operating capability is planned for March 2023. The Navy then was forced to halt the contract in response to a challenge by Lockheed. Lockheed officially withdrew their protest on January 10, 2014, allowing the Navy to lift the stop work order.

Technology

The AMDR system consists of two primary radars and a radar suite controller (RSC) to coordinate the sensors. An S-band radar is to provide volume search, tracking, ballistic missile defense discrimination and missile communications while the X-band radar is to provide horizon search, precision tracking, missile communication and terminal illumination of targets. The S-band and X-band sensors will also share functionality including radar navigation, periscope detection, as well as missile guidance and communication. AMDR is intended as a scalable system; the Burke deckhouse can only accommodate a 4.3 m (14 ft) version but the USN claim they need a radar of 6.1 m (20 ft) or more to meet future ballistic missile threats. This would require a new ship design; Ingalls have proposed the San Antonio-class amphibious transport dock as the basis for a ballistic missile defense cruiser with 6.1 m (20 ft) AMDR. To cut costs the first twelve AMDR sets will have an X-band component based on the existing SPQ-9B rotating radar, to be replaced by a new X-band radar in set 13 that will be more capable against future threats. The transmit-receive modules will use new gallium nitride semiconductor technology. This will allow for higher power density than the previous gallium arsenide radar modules. The new radar will require twice the electrical power as the previous generation while generating over 35 times as much radar power.
Although it was not an initial requirement, the AMDR may be capable of performing electronic attacks using its AESA antenna. Airborne AESA radar systems, like the APG-77 used on the F-22 Raptor, and the APG-81 and APG-79 used on the F-35 Lightning II, and F/A-18 Super Hornet/EA-18G Growler respectively, and have demonstrated their capability to conduct electronic attack. The contenders for the Navy's Next Generation Jammer all used Gallium Nitride-based (GaN) transmit-receiver modules for their EW systems, which enables the possibility that the high-power GaN-based AESA radar used on Flight III ships can perform the mission. Precise beam steering could attack air and surface threats with tightly directed beams of high-powered radio waves to electronically blind aircraft, ships, and missiles.
The radar is 30 times more sensitive and can simultaneously handle over 30 times the targets of the existing AN/SPY-1D(V) in order to counter large and complex raids.

Versions:
  • AN/SPY-6(V)1: AMDR with 37 RMAs for Flight III Arleigh Burke-class DDG.
  • AN/SPY-6(V)2: Otherwise known as the Enterprise Air Surveillance Radar (EASR). Rotating and scaled-down version with 9 RMAs for Flight II San Antonio-class LPD.
  • AN/SPY-6(V)3: Fixed version EASR for Gerald R. Ford-class aircraft carrier and FFG(X).
  • AN/SPY-6(V)4: AMDR with 24 RMAs to be retrofitted to Flight IIA Arleigh Burke-class DDG.


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