mercoledì 26 febbraio 2020

Il semovente anti-aereo ZSU-23-4 "Shilka" o Zenitnaya Samokhodnaya Ustanovka (in russo: Зенитная Самоходная Установка)



Lo ZSU-23-4 Shilka è un semovente antiaereo entrato in linea nell'Armata rossa dai tardi anni sessanta, ed è un veicolo puramente contraereo, con la sua efficacia a breve distanza persino contro aerei militari ad elevatissime prestazioni. L'acronimo "ZSU" sta per Zenitnaya Samokhodnaya Ustanovka (Russo: Зенитная Самоходная Установка).



Il mezzo ha esordito negli anni 60, quando l'esigenza di disporre di armi antiaerei semoventi con prestazioni adeguate alla minaccia di aerei ad alte prestazioni ed in condizioni ognitempo vide l'affermarsi di questo progetto semplice e leggero, con una produzione successiva di oltre 6.500 veicoli.



Caratteristiche

Essi hanno ciascuno una larga e piatta torretta con 4 cannoni da 23mm APV-23, ciascuno con 500 colpi pronti al tiro, sparabili in raffiche fino a 50 colpi l'una, ed un radar Gun Dish da ricerca ed attacco sui bersagli aerei incombenti in un raggio di 20 km. Anche se il radar è nominalmente vulnerabile alle ECM più sofisticate, essendo un modello a scansione conica, nondimeno lo Shilka è frequentemente capace di colpire in maniera letale chiunque si avvicini a meno di 2,5 km, anche con apparati ottici di mira per bersagli aerei e terrestri. La combinazione del quartetto di cannoni, raffreddati ad acqua per mantenere almeno 400 colpi al minuto di cadenza effettiva, radar leggero di acquisizione e tiro, computer analogico (gli ultimi modelli ne hanno uno digitale) è stata estremamente pericolosa per attacchi aerei a bassa quota.
I limiti sono una velocità non proprio eccelsa, così come la protezione, a causa dell'utilizzo dello scafo del PT-76, e un gittata insufficiente contro gli elicotteri che hanno missili anticarro e magari sono capaci di volare abbastanza bassi per evitare anche i SAM.



Utilizzi operativi

Il primo impiego operativo dello Shilka è stato nella guerra del Vietnam, dove fu largamente usato dall'esercito regolare nordvietnamita, abbattendo numerosi aerei statunitensi. È stato utilizzato poi con successo nella guerra del Kippur nel 1973 abbattendo qualche jet israeliano, anche se il numero di aerei abbattuti addebitabili allo Shilka è tuttora poco chiaro.
Un aspetto poco noto di tale sistema è che può essere impiegato anche contro obiettivi terrestri, specialmente se poco corazzati (quali APC o truppe di fanteria): grazie all'elevata cadenza di fuoco rappresenta infatti una minaccia concreta anche a terra, spesso sottovalutata.
I russi (sovietici, al tempo) lo utilizzarono contro postazioni fortificate dei mujaheddin nel territorio afghano.
Durante la prima guerra del Golfo esso ha operato nelle file irachene, non riportando risultati significativi.
Con questo sistema d'arma è stato abbattuto il Tornado italiano, pilotato dal maggiore Gianmarco Bellini e dal capitano Maurizio Cocciolone, impiegato nell'"operazione locusta", il 18/01/1991. Il velivolo al momento dell'abbattimento volava ad una quota di 150 piedi circa, "agganciato" dal radar del Shilka, l'equipaggio nel tentativo di "chaffare" ha potuto fare ben poco.



Problemi

Lo Shilkha non è comunque esente da problemi, più volte segnalati, quali la inefficienza del suo sistema di raffreddamento ad acqua (perdite, malfunzionamenti): a causa di queste noie si possono verificare problemi di surriscaldamento nei cannoni che a volte continuano a fare fuoco anche quando l'operatore rilascia l'apposito comando.



Anni recenti

Anche se attualmente il peso dell'età si fa sentire (soprattutto in termini di jamming in un contesto EW), esso è rimasto verosimilmente il sistema migliore e più efficace della sua categoria (contraerea di corto raggio) fino all'avvento del Gepard.



Operatori:
  •  Afghanistan
  •  Angola
  •  Armenia
  •  Bielorussia
  •  Bulgaria
  •  Cuba
  •  Repubblica Ceca
  •  Germania
  •  Egitto
  •  Etiopia
  •  Ungheria
  •  India
  •  Iran
  •  Iraq
  •  Giordania
  •  Libia
  •  Marocco
  •  Mozambico
  •  Mongolia
  •  Nigeria
  •  Corea del nord
  •  Perù
  •  Polonia
  •  Romania
  •  Russia
  •  Serbia
  •  Slovacchia
  •  Somalia
  •  Siria
  •  Ucraina
  •  Vietnam
  •  Yemen
  •  (non più esistente) Jugoslavia.



ENGLISH

The ZSU-23-4 "Shilka" is a lightly armored Soviet self-propelled, radar guided anti-aircraft weapon system (SPAAG).

Etymology

The acronym "ZSU" stands for Zenitnaya Samokhodnaya Ustanovka (Russian: Зенитная Самоходная Установка), meaning "anti-aircraft self-propelled system"; the "23" signifies the bore diameter in millimeters; the "4" signifies the number of gun barrels. It is named after the Shilka River in Russia. Afghan soldiers nicknamed it the "sewing machine" due to the sound of firing guns. It is also referred to by its nickname of "Zeus", derived from the Russian acronym.



History

The previous Soviet self-propelled anti-aircraft gun (SPAAG), the ZSU-57-2, was armed with two 57 mm autocannons; it was aimed optically using a basic tracking and lead calculating system. The ZSU-57-2 was not particularly successful despite its very powerful autocannons; it could only carry a relatively small amount of ammunition, was inaccurate as it lacked radar and could not fire while on the move.
The ZPU series armed with 14.5 mm heavy machine guns carried on a towed mount for stationary, point air defence had a much higher rate of fire. The 23 mm version of this weapon system was known as the ZU-23-2, a towed mount carrying two 23 mm cannons. However, these towed or improvised truck-mounted weapons had similar disadvantages.
The development of the ZSU-23-4 "Shilka" began in 1957 along with ZSU-37-2 "Yenisei" and the vehicle was brought into service in 1965, replacing all ZSU-57-2s in air defense units toward the beginning of the 1970s. The ZSU-23-4 was intended for AA defense of military facilities, troops, and mechanized columns on the march; originally, the more powerful guns of "Yenisei" were judged to be effective at covering the inner dead-zone of Soviet surface-to-air missile systems despite the increased weight of the vehicle, but commonality prevailed. Initially, tank regiments should have had the anti-aircraft artillery battalion of "Shilka" (consisting of two batteries, four ZSU-23-4s in each). At the end of the 1960s, one battery was equipped with ZSU-23-4s and the other with ZSU-57-2s. Motorized rifle and tank regiment standard anti-aircraft batteries consisted of two platoons later (one platoon was equipped with four ZSU-23-4s and another with four mobile surface-to-air missile systems 9K31 Strela-1 or 9K35 Strela-10). The ZSU-23-4 combined a proven radar system, the non-amphibious chassis based on GM-575 tracked vehicle, and four 23 mm autocannons. This delivered a highly effective combination of mobility with heavy firepower and considerable accuracy. The ZSU-23-4 outclassed all NATO anti-aircraft guns at the time, and it is still regarded as posing a major threat for low-flying fixed-wing aircraft and helicopters.
The system was widely fielded throughout the Warsaw Pact and among other pro-Soviet states. Around 2,500 ZSU-23-4s, of the total 6,500 produced, were exported to 23 countries. The Soviet Union's successor states continue to manufacture and supply variants of the ZSU-23-4, notably the Ukrainian "Donets" and Polish "Biala" variants.
ZSU-23-4 units saw active service in the Yom Kippur War (1973) and other Arab-Israeli conflicts, the Iran–Iraq War (1980–1988), and the First Gulf War (1990). During the 1973 Yom Kippur War, the system was particularly effective against the Israeli Air Force. Israeli pilots attempting to fly low in order to avoid SA-6 missiles were often shot down by ZSU-23-4s as in Operation Doogman 5. During the Soviet–Afghan War ZSU-23-4 units were used widely and to great effect against mujahideen positions in the mountains, the ZSU-23-4's guns being able to elevate much higher than the weapons on BMPs, BTRs, T-55s, or T-62s. They were also used to suppress defensive positions around the presidential palace during the initial coup in Kabul at the start of the Soviet-Afghan war. The Russian Army used the ZSU-23-4 for mountain combat in Chechnya.
Initially fielded by the loyalist forces of the Syrian Arab Army as a fire support vehicle, a number of them were captured by different factions in the Syrian Civil War and they are normally fielded in a fire support role by all sides. There were no (or at most very limited) attempts by the different opposing forces to use the Shilka in its original anti aircraft role against loyalist and international air forces operating in the area.



Description

The radar-guided ZSU-23-4 "Shilka" SPAAG, with its four 23 mm (0.90") autocannons, was a revolutionary SPAAG, proving to be an extremely effective weapon against enemy attack aircraft and helicopters under every weather and light condition. The ZSU-23-4 has a very high density, rate and accuracy of fire, as well as the capability for each of the four autocannons to fire its own type of projectile from separate belts. While it is technically possible that each cannon shoots different type of ammunition, there were two types commonly used in late 1970s: OFZT incendiary fragmentation and BZT armour-piercing tracer, which were to be loaded in 3:1 ratio—three OFZT, then one BZT, every 10th BZT round equipped with so-called "copper remover" and marked. Operators were strongly discouraged from shooting from a single barrel.
The appearance of the "Shilka" caused significant changes in NATO tactics in aircraft use at low altitude over the battlefield. Despite its present obsolescence as a modern short-range anti-aircraft weapon, the ZSU-23-4 is still deadly for enemy light armoured vehicles, infantry and firing points as an infantry-support vehicle. With its high rate of accurate fire, the ZSU-23-4 can even neutralize tanks by destroying their gun sights, radio antennas, or other vulnerable parts. ZSU-23-4s, especially late models, have excellent performance and good systems reliability.
Based on the GM-575 tracked vehicle chassis, which used components from the PT-76 light amphibious tank, the ZSU-23-4 mounts an armored turret holding four liquid-cooled 23 mm (0.9") 2A7 autocannons linked to an RPK-2 "Tobol" radar (NATO designator: "Gun Dish"). The vehicle weighs 19 tonnes (late modifications up to 21 tonnes), has a movement range of 450 km (280 mi) and a top speed of 50 km/h (31 mph). Additional firepower of late modifications can be supplied by a roof-mounted pod of six short-range SA-18 SAMs, or side mounted SA-16s.
The crew numbers four: driver, commander, gunner and radar operator. The driver's compartment is located in the nose part of the vehicle. The fighting compartment is in the center, and the engine compartment is in the rear part of the vehicle.
The transmission consists of a multi-plate metal-contact main clutch, a manual gearbox with five forward gears, two planetary two-step steering gears with locking frictions and two final drive groups. The vehicle chassis has six single rubber tired road wheels, a rear drive sprocket with detachable sprocket rings (lantern-wheel gear) and one idler wheel per side. The first and fifth left, and sixth right road wheels have hydraulic shock absorbers. The track is 11.904 m long, 382 mm (15") wide and has 93 links.
Because of a large number of different pipes and tubes to detach during maintenance, the repair procedure for some of the vehicle's mechanisms is hard (for example, replacement or repair of a starter). The electric drive of an air outlet hatch of a gas turbine engine (part of the vehicle's electric power supply system) has an inconvenient location (at the bottom of the hull) which causes overheating and sometimes, jamming of the electric drive. On the other hand, the construction of the electric power supply system is very reliable. Changing the main engine oil and coolant is easy, as is replacement of fuel and oil filters, and sections of the air filter.
The ZSU-23-4 can cross vertical obstacles 0.7 m (2.3') high, trenches 2.5 m (8.2') wide, has a 1.0 m (3.3') fording depth and can climb 30° gradients. The ZSU-23-4 has good maneuverability and cross-country ability, but its diesel engine's power is insufficient for a vehicle of its weight. As a result, off-road acceleration capabilities are sub-par, and the vehicle lags behind MBTs and IFVs on up-hill terrain.
The ZSU-23-4 is equipped with an NBC system with an air filtration unit, fire-fighting equipment, TNA-2 navigational system, infrared vision device, R-123 radio set, R-124 intercom and electric power supply system consisting of a DGChM-1 single-shaft gas turbine engine (70 hp at 6,000 rpm) and a direct-current generator (which provides 27 V and 54 V direct current or 220 V 400 Hz alternating current).



Weapons and fire control

Turret and guns

Each water-cooled 23 mm 2A7 autocannon has a cyclic rate of 850–1,000 rounds per minute for a combined rate of fire of 3,400–4,000 rounds per minute. The welded turret has a race ring transplanted from a T-54 medium tank with a 1,840 mm (6') diameter. The 360° rotating turret is fully stabilised and capable of firing on the move. The turret rotation and autocannon elevation mechanisms provide very good speed and guidance accuracy. The hydraulically driven aiming mechanisms have been proven to be very reliable. Manual aim is used against ground targets. The quad automatic anti-aircraft gun AZP-23 "Amur" has a range of elevation from −4° to +85°. The GRAU designation for ZSU-23-4 turret with 23 mm (0.9") AZP-23 "Amur" quad automatic gun is 2A10. An armoured plate inside the turret protects crew members from fire and explosive gas during intense firing.

Ammunition

Ammunition capacity is 2,000 rounds stowed aboard (520 rounds per each upper autocannon and 480 rounds per each lower autocannon) loaded in 50-round or shorter belts.
The water-cooled 2A7 23mm guns of ZSU-23-4 fire the same 23×152B mm caliber ammunition as the 2A14 guns of the twin-barrel ZU-23-2 towed gun. While the 23mm Volkov-Yartsev VYa-23 aircraft gun used in the Second World War era Il-2 Sturmovik also fired ammunition of the same cartridge case dimensions, the rounds differed in loading and primer, and are thus not interchangeable with the post-war AA gun ammunition.[14] Compared to the VYa and its ammunition, the air defence guns have slightly higher muzzle velocity, and explosive rounds also have slightly larger HE fillings. The VYa ammunition has brass cases, while 2A7/2A14 ammunition has steel cases.
Three main types of 23mm anti-aircraft ammunition were manufactured post-war: API-T, HEI and HEI-T. In addition to the original Soviet rounds, a number of ammunition manufacturers have since begun to produce ammunition for what is still a widely used caliber; these include new ammunition types such as sub-caliber armor-piercing rounds and frangible ammunition.
A typical loading of each ammunition belt contains 40 OFZT and 10 BZT rounds. They can be fired to a maximum horizontal range of 7 km (4.3 mi), and a vertical range of 5.1 km (3.2 mi). The effective vertical range is 1.5 km (0.93 mi) at a direct range to target of 2.5 km (1.6 mi) and target speed of 250 m/s (up to 500 m/s if a modern fire control system is used). The usual autocannon burst consists of 3–10 projectiles and target lead angle is calculated for each burst (fire without adjustment) by computer. In attacking targets on the ground, its effective range is around 2.5 km (1.6 mi). The short range of its 23 mm autocannons and relatively low explosive effect of its small-calibre projectiles mean it is less able to engage threats such as jet attack aircraft and cruise missiles than modern systems like the 2K22 Tunguska armed with more powerful 30 mm autocannons and integrated missile armaments. A special 23 mm round with composite projectiles was developed for a modern variant of SPAAG (ZSU-23-4M4) to be used against cruise missiles.

Radar

The RPK-2 "Tobol" a.k.a. 1RL33 radar operates in the J band and can detect aircraft up to 20 km (12 mi) away. It has excellent target tracking capability and is relatively hard to detect by the enemy. However, the radar picks up many false returns (ground clutter) under 60 m (200 ft) of altitude. The radar antenna is mounted on collapsible supports in the top rear of the turret. There is an optical alignment sight. The RPK-2 radar proved to have good protection against enemy passive electronic radar counter-measures. Nevertheless, the radar system of the ZSU-23-4 has a short detection range during target search, depending on weather conditions (mainly dependent on rain and snow conditions). It is hard to automatically track the target at ranges less than 7–8 km (4.3–5.0 mi) because of the high angular speed of the target at close distances. The radar needs to be reset quite often because of the unstable parameters of electronic cathode-ray tubes of the target selection system. The absence of an automatic laser range finder requires a skillful commander and gunner.

Limitations and problems

Early versions of the ZSU-23-4 sometimes had problems with "runaway guns": after prolonged periods of firing, the guns would get so hot that chambered rounds would "cook off" even if the operator was not pulling the trigger—discharging the weapon and chambering a new round, which would then also cook off, and continue to do so. This would sometimes continue until the entire belt of ammunition had been expended. Overheating barrels could jam and even break away from the vehicle. The problem resulted from a deficient cooling system and made the early ZSU-23-4s dangerous even to friendly troops standing nearby if this happened. Despite the fact that this seldom happened, Soviet operators learned to give these machines a wide berth.(Perrett 1987:100) It was not recommended to perform continuous fire (bursts longer than 15 seconds without pause) on earlier models until the problem with autocannon reliability and overheating during intense fire was solved on ZSU-23-4M (welded tubes of coolant outlet were replaced with flexible pipes). After the autocannon cooling system was improved, the autocannons became extremely reliable.
The ZSU-23-4 has an 1A7 SRP electro-mechanical fire solution calculator, weighing 180 kg, that occupies all of the space before the Commander. It contains 60 electric motors driving 110 axles over different potentiometers, shafts, rods, cams, gears and linkages to mechanically calculate ammunition flight time till impact, elevation lead angle, and azimuth lead angle using the target parameters received from the 1RL33 RPK-2 (gun dish) radar, and the correction angle received from the GAG (gyroscope) unit.

Deployment

Soviet doctrine supplied the vehicle since 1965 in an anti-aircraft artillery battery of two, four-vehicle platoons for anti-aircraft defence of motor rifle and tank regiments. At the end of the 1960s one platoon was equipped with ZSU-23-4 SPAAGs while another one was still equipped with ZSU-57-2 SPAAGs. ZSU-57-2 was completely replaced with ZSU-23-4 by the beginning of the 1970s. In the 1970s, Soviet motor rifle and tank regiments were equipped with an anti-aircraft missile artillery battery consisting of two platoons, one equipped with four ZSU-23-4 SPAAGs and the other with four 9K31 Strela-1 (SA-9 Gaskin) or later with four 9K35 Strela-10 (SA-13 Gopher) short-range surface-to-air missile systems which cover the dead zones of 2K12 Kub (SA-6 Gainful) surface-to-air missile systems belonging to the divisional level. Since the 1980s Soviet motor rifle and tank regiments were equipped with an anti-aircraft artillery battalion of three batteries (one was equipped with ZSU-23-4 or 9K22 Tunguska SPAAGs, the second one was equipped with 9K35 Strela-10 (SA-13 Gopher) short-range surface-to-air missile systems and the third battery with 9K38 Igla man-portable surface-to-air missiles on IFVs or APCs.
The ZSU-23-4 is very vulnerable to enemy anti-tank missiles, cannons and heavy machine guns; the armour is thin (not exceeding 15 mm) and the exposed wheels, tracks, radar, and gun barrels can easily be damaged in combat. Firing positions of ZSU-23-4 SPAAGs are typically placed near the forward edge of the battle area (FEBA) but behind the main forces, usually 600–1000 m behind objectives when on the defensive or 400–600 m behind the leading tanks on the offensive. ZSU-23-4 SPAAGs are divided evenly along the troop columns on the march.
At first each ZSU-23-4 operated in combat autonomously, without target marking from regimental or divisional air defence. In 1978, the PPRU-1 (mobile reconnaissance and control post) was passed into service of the Soviet Army. The PPRU-1 ("Ovod-M-SV") vehicle is based on MT-LBu armoured tracked chassis and it was intended for control of motor rifle or tank regimental anti-aircraft unit equipped with ZSU-23-4 SPAAGs and 9K31 "Strela-1M" mobile surface-to-air missile systems. The PPRU-1 is equipped with "Luk-23" radar and an automatic fire control system associated with the divisional air defence system.
The guns are useful against low-flying aircraft and lightly protected ground targets. Due to its effectiveness against ground targets, ZSU-23-4s have been used in urban environments (e.g., Afghanistan, Abkhazia, Chechnya, Syria and Lebanon). This is primarily because the guns can elevate much higher than a tank or APC cannon, enabling armored units equipped with ZSU-23-4s to return fire against ambushes from above.
A small number of ZSU-23-4 SPAAGs are still in use by the Russian Naval Infantry (specifically the 61st and 175th brigades of the Northern Fleet and the 336th brigade of the Baltic Fleet).

Variants

Soviet Union:

ZSU-23-4 "Shilka" (1964): pre-production and then initial production models.
ZSU-23-4V "Shilka" (1968): modernized variant with enhanced reliability of some details, ventilation system case located on the hull. Commander vision device was added.
ZSU-23-4V1 "Shilka" (1970): modernized variant with enhanced reliability of radar system and other details, ventilation system cases located on front bilges of the turret. Guidance-system computer was improved (as well as accuracy and efficiency of anti-aircraft fire on the move at 40 km/h). It is fitted with a slightly improved diesel engine V-6R-1.
ZSU-23-4M1 (1973): armed with modernized autocannons 2A7M. The pneumatic loading was replaced with pyrotechnic loading (unreliable compressor was removed), welded tubes of coolant outlet were replaced with flexible pipes which increased autocannon barrel life from 3500 rounds to 4500 rounds.
ZSU-23-4M3 "Biryusa" (1977): equipped with identification friend-or-foe system "Luk". All ZSU-23-4M were upgraded to ZSU-23-4M3 level during scheduled repairs. Army unofficially continued to use the name "Shilka" for all variants of ZSU-23-4.
ZSU-23-4M2 (1978): so-called "Afghan" variant. Reequipment performed during the Soviet–Afghan War for mountain combat. The radar system was removed and a night-sight was added. Ammunition increased from 2,000 to 4,000 rounds.

Russian Federation and Belarus

ZSU-23-4M4 and ZSU-23-4M5 (1999): modernized variants, armed with two additional paired man-portable air-defense systems "Igla" on each side of the turret and equipped with 81mm smoke grenade launchers, laser emission sensors, electro-optical vision devices (including television system for driver) and improved weapon radar system. The mechanical transmission was replaced with hydrostatic transmission, hydraulic boosters were installed. Mobility increased to the level of main battle tanks. This upgrade was first shown during the exhibition MAKS-99 in Zhukovsky and was carried out by the Minotor Service Enterprise and Peleng Joint Stock Company from the Republic of Belarus, and the Ulyanovsk Mechanical Plant of Russia. The Ulyanovsk Mechancial Plant is also offering ZSU-23-4 upgrade packages independently.

Ukraine

Donets (1999): This is a Ukrainian modernization developed by Malyshev Tank Factory in Kharkov. It has the modified turret from the ZSU-23-4, armed with two additional paired man-portable air-defense systems "Strela-10" installed on the hull of the T-80UD main battle tank. Ammunition capacity for its 23 mm autocannons is doubled.
ZSU-23-4M-A (2017): A modernisation package developed by the Arsenal Factory in Kyiv, this system features a new Rokach-AS radar, laser rangefinder, and four automatic Igla missiles.

Poland

ZSU-23-4MP Biała (2000): Polish modernized upgrade with Grom anti-aircraft missiles and fully digital passive aiming devices instead of the radar.

India

ZSU-23-4 upgrade: This version was developed by Bharat Electronics Ltd (BEL) of India in cooperation with Israel Aircraft Industries (IAI). These Anti Aircraft Tanks(AAT) were first used in the Indo-Pak War of 1971. These proved to be effective against Pakistani Mirage-III's. The upgraded systems will feature an advanced AESA radar and computers, electro-optical fire control systems, a new Caterpillar 359 BHP diesel engine and a new APU. The upgraded systems are able to operate despite enemy jamming, are able to pick up targets from more than 15 km away, and functions in temperatures between 55° Celsius and minus 40° Celsius. The gun is able to shoot down targets flying at 450 miles per hour up to 1,500 meters and out to 2,500 meters. The purpose of the upgrade is to extend the life of the air defence system by 15 years. In December 2004 it was reported that the Indian Army awarded a US$104 million contract to upgrade 48 ZSU-23-4 air defence systems of the Indian Army.

Netherlands

ZSU-23-4 upgrade (1998): As a private venture, Hollandse Signaalapparaten company (now Thales Nederland) of the Netherlands, obtained a number of ex-East German Army ZSU-23-4V1s and developed an upgrade package. The main part of this upgrade is the modernisation of the radar and fire-control system. The first prototype was completed in mid-1998. The upgraded vehicle is equipped with the ASADS Ka-band target tracking radar and the PAGE I-band surveillance radar.

(Web, Google, Wikipedia, You tube)













































































martedì 25 febbraio 2020

Orca XLUUV: la “balena” della Boeing è un sottomarino senza equipaggio



Orca XLUUV: la “balena” della Boeing è un sottomarino senza equipaggio

L’US NAVY ha assegnato alla Boeing contratti per un totale di 274,4 milioni di dollari per la produzione di cinque veicoli sottomarini Orca Extra Large Unmanned Undersea Vehicles (XLUUUV) basati sul prototipo UUV Echo Voyager della Boeing; il sommergibile di 15,5 m di lunghezza potrebbe essere utilizzato per:
  • contromisure mine, 
  • guerra ASW, 
  • guerra elettronica,
  • missioni “hunter killer”.



Quando si tratta di sottomarini robot, la Marina degli Stati Uniti crede nel principio "go big or go home". Ha bisogno di sottomarini robot molto grandi, di maggior tonnellaggio e maggior resistenza per operare nelle vastità oceaniche in modo completamente autonomo.
La visione statunitense è quella di farli partire:
  • dal porto verso una zona operativa, 
  • farli vagare, 
  • stabilire comunicazioni criptate, 
  • dispiegare carichi utili,
  • Tornare verso la base in porto. 

Gli UUV tattici più piccoli che l’Us Navy utilizza attualmente possono rivelarsi costosi in quanto hanno bisogno di una nave di supporto con equipaggio nelle vicinanze e hanno una resistenza limitata.



Nell'ottobre 2017 la Marina statunitense ha selezionato Boeing e Lockheed Martin per partecipare alla fase di progettazione del suo “Orca XLUUUV” e a maggio 2018 ha assegnato alla Boeing una modifica del contratto per la consegna di cinque dei suoi XLUUUV e dei relativi elementi di supporto.
L'Orca XLUUUV sarà un'acquisizione accelerata in più fasi che prevede un concorso completo e aperto all'industria per progettare, fabbricare, testare e consegnare sistemi alla Marina Militare degli Stati Uniti. La marina ha selezionato il miglior valore in termini di prezzo e capacità tecniche.
Come già detto, la Boeing basa il suo progetto sul suo Echo Voyager, un prototipo XLUUUV che l'azienda ha finanziato e progettato per scopi sperimentali. Boeing afferma che le lezioni apprese da Echo Voyager sono state incorporate nel progetto Orca per migliorare l'affidabilità e ridurre i rischi.
Il veicolo ha più di 2.500 ore di test in mare. Echo Voyager ha completato la sua prima fase di test in mare - o prove in mare Alpha - nel 2017, quando ha operato al largo della costa della California meridionale per circa tre mesi per sottoporsi alle valutazioni e ai test del sistema. Durante quel periodo, il team di test di Echo Voyager ha condotto una serie di test funzionali per verificare la capacità di Echo Voyager di operare in superficie, appena sotto la superficie e sotto il mare. I test oceanici hanno incluso la ricarica della batteria, il controllo del veicolo nelle correnti e nell'azione delle onde, l'immersione del veicolo e il ritorno in superficie. Echo Voyager è tornato in mare dal 2018 per le prove in mare di Bravo, progettate per espandere l'ambito operativo della serie di test iniziali.



Il design modulare per l'Orca XLUUUV iniziale consentirà di integrare: 
  • i carichi utili, 
  • i sensori, 
  • l’autonomia, 
  • altri sistemi attuali e futuri nel corso del ciclo di vita dei veicoli.

Il Sea Voyager avrebbe un'autonomia di 6.500 miglia nautiche e mesi di funzionamento su un unico modulo di carburante. Poiché il funzionamento del GPS è possibile solo in superficie, utilizza un'unità di navigazione inerziale filtrata di Kalman aiutata da una serie di registri di velocità doppler e sensori di profondità per navigare sott'acqua.
L'imbarcazione da 45,4 tonnellate offre una capacità di carico utile modulare fino a 56,6 metri cubi e 7,3 tonnellate di peso a secco su una lunghezza massima di 10,4 metri, e i carichi utili della missione sono alimentati da una batteria da 18kW.
Il design modulare per l'Orca XLUUUV iniziale consentirà di integrare i carichi utili attuali e futuri, i sensori, l'autonomia e altri sistemi per tutto il ciclo di vita dei veicoli.

I più grandi sottomarini XLUUV del mondo

Mentre il Boeing “Orca XLUUUV” è destinato a svolgere una varietà di missioni, la Marina degli Stati Uniti non ha rivelato le specifiche delle operazioni previste o le capacità stealth.
La consegna delle cinque unità avverrà in sequenza, con la prima prevista per la fine dell'anno finanziario 2020 e il contratto dovrebbe essere completato entro dicembre 2022. Gli XLUUUV ORCA saranno sottoposti a un rigoroso piano di integrazione e test con il contraente e a un test governativo indipendente e a una valutazione degli utenti militari prima dell'uso operativo.
L'Orca della Marina degli Stati Uniti potrebbe non essere il più grande pesce autonomo dell'oceano per molto tempo. 



Il Laboratorio di Scienza e Tecnologia della Difesa del Ministero della Difesa del Regno Unito (Dstl) ha lanciato in aprile un concorso a due fasi da 2,5 milioni di sterline alla ricerca di soluzioni che informino le capacità future e la comprensione dell'utilità degli XLUUUV. La prima fase condurrà la ricerca e lo sviluppo di un sistema di controllo autonomo utilizzando una piattaforma esistente, e la seconda fase li testerà per la durata di due anni. In definitiva anche il MOD britannico sta cercando una soluzione per effettuare la raccolta di informazioni segrete e fornire una ulteriore barriera di guerra antisommergibile. Dovrà operare in modo indipendente per un minimo di tre mesi a distanze fino a 3.000 miglia nautiche dal luogo del primo dispiegamento e trasportare e dispiegare carichi utili fino a due metri cubi e due tonnellate.



IL NUOVO "ROBOT WOLFPACK" DELLA MARINA MILITARE DI ORCA SARÀ PRONTO PER LA GUERRA

In uno sforzo di modernizzazione, la Marina degli Stati Uniti sta aggiungendo una flotta di sommergibili autonomi.
Il servizio sta mettendo a punto "robot wolfpack" o navi telecomandate per condurre missioni di guerra antisommergibile, di guerra elettronica, di contromisure contro le mine e di caccia “hunter killer”.
"Siamo soddisfatti della decisione della Marina Militare di assegnare a Boeing un contratto per la costruzione e la consegna di quattro veicoli sottomarini Orca Extra Large Unmanned Undersea Vehicles, e ci impegniamo a fornire questa importante capacità autonoma sottomarina per soddisfare le esigenze uniche della Marina Militare", ha dichiarato l'azienda in un comunicato di giovedì a USNI News.
L'Orca è un sottomarino diesel-elettrico completamente autonomo lanciato e recuperato da un porto navale. Con un raggio d'azione di 6.500 miglia nautiche, l'imbarcazione può navigare per settimane. Il sottomarino è enorme, in qualità di sottomarino robot, misura 51 per 8,5 per 8,5 piedi e pesa 50 tonnellate. E’ dotato di un sistema di navigazione inerziale ad alta tecnologia, sensori di profondità, e può emergere per trasmettere i dati alla base. L'imbarcazione può immergersi fino ad una profondità massima di 11.000 piedi e ha una velocità massima di otto nodi.
Un pezzo cruciale del sottomarino è il sistema di carico utile che gli permette di trainare fino a otto tonnellate in una stiva di carico interna che misura 34 piedi.
Il design modulare del sottomarino e il prezzo economico rendono il sottomarino un potenziale elemento di cambiamento per la Marina Militare statunitense.
Orca può anche imbarcare un siluro leggero Mk. 46 e lanciarlo contro un sottomarino nemico. Trasporterà siluri Mk. 48 pesanti per attaccare le navi di superficie, o anche, forse, missili anti-nave. L'Orca è in grado lanciare carichi sul fondo del mare, rilevare, o anche posare mine. Il sistema modulare di carico utile hardware e il software ad architettura aperta garantiscono che Orca possa essere rapidamente configurato in base alle necessità.
Questo tipo di versatilità in un unico pacchetto a basso costo è piuttosto inusuale nella spesa militare. L'equivalente approssimativo più vicino sono le Navy's Littoral Combat Ship, che costano 584 milioni di dollari cadauna ed hanno un equipaggio di 40 persone. Mentre la LCS è più veloce, ha il vantaggio di un equipaggio a bordo e trasporta un carico utile maggiore, l’XLUUV Orca è autonomo e più economico per ordini di grandezza.
L'acquisto di questi sottomarini robotizzati avviene in mezzo a una spinta verso navi autonome per la Us Navy. Il mese scorso, la nave autonoma Sea Hunter della Marina Militare statunitense, ha condotto la sua prima missione di sorveglianza da San Diego a Pearl Harbor, Hawaii, e ritorno senza equipaggio a bordo.
Secondo l'USNI, la Marina potrebbe potenzialmente dispiegare l'Orca da navi esistenti per condurre "contromisure contro le mine, guerra antisommergibile, guerra antisommergibile, guerra elettronica e missioni di caccia".
Il design modulare dell'Orca e il prezzo relativamente basso rendono i robot-sottomarini un potenziale fattore di cambiamento per una Marina che sta lottando per arrivare a 335 unità combattenti.
Il sistema modulare di carico utile hardware e il software ad architettura aperta garantiscono che Orca possa essere rapidamente configurato in base alle necessità.
L'acquisto avviene nel mezzo di una spinta verso navi autonome per la Marina Militare, e non solo grazie alla ritrovata attenzione del presidente Donald Trump per l'intelligenza artificiale. All'inizio di quest'anno, il trimarano autonomo Sea Hunter della Marina, progettato per il dragamine e la caccia ai sottomarini, ha viaggiato da San Diego alle Hawaii e ritorno senza un solo marinaio a bordo in un viaggio storico.



ENGLISH

Orca XLUUV: Boeing’s whale of an unmanned sub

The US Navy has awarded Boeing contracts worth a total of $274.4m to produce five Orca Extra Large Unmanned Undersea Vehicles (XLUUVs). Based on Boeing’s Echo Voyager prototype UUV, the 15.5m-long submersible could be used for mine countermeasures, anti-submarine warfare, anti-surface warfare, electronic warfare and strike missions. Berenice Baker finds out more.
The US Navy awarded a contract modification for the delivery of five Boeing Orca XLUUV and associated support elements. Credit: Boeing.
When it comes to robot submarines, the US Navy believes in the principle of go big or go home. It needs much larger, longer-range and longer-endurance robot submarines to operate across vast tracts of ocean entirely autonomously.
Its vision is to have them swim from port to an area of operation, loiter there, establish communications, deploy payloads then navigate home. The smaller tactical UUVs the navy currently uses can prove expensive as they need a manned support vessel nearby and have limited endurance.
In October 2017 the US Navy selected Boeing and Lockheed Martin to participate in the design phase of its Orca XLUUV and in May awarded Boeing a contract modification to deliver five of its XLUUVs and associated support elements.
US Naval Sea Systems Command spokesperson Alan Baribeau said of the selection: “The Orca XLUUV is a multi-phased accelerated acquisition featuring a full and open competition to industry to design, fabricate, test and deliver systems to the US Navy. The navy selected the best value of price and technical capabilities.”
Echo Voyager to Orca: Boeing’s XLUUV
Boeing is basing its design on its Echo Voyager, a prototype XLUUV the company funded and designed itself for testing purposes only. Boeing says lessons learned from Echo Voyager have been incorporated into the Orca design to improve reliability and reduce risk.
A Boeing spokesperson said: “The vehicle has more than 2,500 hours of ocean testing. Echo Voyager completed its first phase of sea testing – or Alpha sea trials – in 2017 when it operated off the coast of Southern California for about three months to undergo system evaluations and testing.
“During that time, the Echo Voyager test team conducted a series of functional tests to verify Echo Voyager’s ability to operate on the surface, just beneath the surface and undersea. Ocean testing tasks included charging the battery, controlling the vehicle in currents and wave action, submerging the vehicle and returning to the surface. Echo Voyager returned to sea in 2018 through early this year for Bravo sea trials, designed to expand the operational envelope from the initial test series.”
“The modular design for the initial Orca XLUUV will enable current and future payloads, sensors, autonomy and other systems to be able to be integrated over the vehicles’ life cycle.”
According to Boeing, Sea Voyager offers a range of 6,500 nautical miles and months of operation on a single fuel module. As GPS operation is only possible at the surface, it uses a Kalman filtered inertial navigation unit aided by a set of doppler velocity logs, and depth sensors to navigate underwater.
The 45.4 tonne vessel offers a modular payload capacity of up to 56.6 cubic metres and 7.3 tonne dry weight over a maximum length of 10.4m, and mission payloads are powered by an 18kW battery.
Baribeau says: “The modular design for the initial Orca XLUUV will enable current and future payloads, sensors, autonomy and other systems to be able to be integrated over the vehicles’ life cycle.”

The world’s biggest submarines

While the Boeing Orca XLUUV is intended to perform a variety of missions, the US Navy has not revealed specifics of its intended operations or any stealth capabilities.
Delivery of the five units will take place sequentially, with the first planned for the end of financial year 2020 and the contract expected to be completed by December 2022. According to Baribeau, the Orca XLUUVs will undergo a rigorous integration and test plan with the contractor and an independent government testing and military user assessment before operational use.
XXL across the pond
The US Navy’s Orca may not be the biggest autonomous fish in the ocean for long. The UK Ministry of Defence’s Defence Science and Technology Laboratory (Dstl) launched a two-stage £2.5m competition in  April seeking solutions that inform future capability and understanding of the utility of XLUUVs. The first stage will carry out research and development of an autonomous control system using an existing platform, and the second stage will test these over the duration of two years.
Ultimately the MOD is looking for a solution to carry out covert intelligence gathering and provide an anti-submarine warfare barrier. It will need to operate independently for a minimum of three months at distances of up to 3,000 nautical miles from where it is first deployed, and carry and deploy payloads of up to two cubic metres and two tonnes.

US NAVY’S NEW “ROBOT WOLFPACK” OF ORCA SUBMARINES WILL BE READY FOR WAR

In a modernization effort, the US Navy is adding a fleet of autonomous submarines with the purchase of four of Boeing’s Orca Extra Large Unmanned Undersea Vehicles (XLUUVs) that will become multi-mission for the service, according to the US Naval Institute.
Last Wednesday, the Navy awarded Boeing a $43 million deal to manufacture four of the 51-foot Orca XLUUVs capable of traveling 6,500 nautical miles unaided.

The service is eyeing the submarine for “robot wolfpacks” of remotely-operated vessels to conduct anti-submarine warfare, electronic warfare, mine countermeasures, and strike missions.
“We are pleased with the Navy’s decision to award Boeing a contract to build and deliver four Orca Extra Large Unmanned Undersea Vehicles, and are committed to providing this important autonomous undersea capability to meet the Navy’s unique mission needs,” the company said in a Thursday statement to USNI News.
The Orca is a fully autonomous diesel-electric submarine launched and recovered from a naval port. With a range of 6,500 nautical miles, the vessel can run for weeks at a time. The sub is enormous, in terms of a robot submarine, measures 51 by 8.5 by 8.5 feet and weighs 50 tons.
The sub features a high-tech inertial navigation system, depth sensors, and can surface to transmit data back to base. The vessel can dive to a maximum depth of 11,000 feet and has a top speed of eight knots.
One crucial piece of the sub is the payload system that allows it to haul up to eight tons in an internal cargo bay that measures 34 feet.
Popular Mechanics points out, the sub’s modular design and cheap price tag make the vessel a potential game-changer for the Navy.
Orca could even pack a  Mk. 46 lightweight torpedo to take a shot at an enemy sub itself. It could also carry heavier  Mk. 48 heavyweight torpedoes  to attack surface ships, or even conceivably anti-ship missiles. Orca could drop off cargos on the seabed, detect, or even lay mines. The modular hardware payload system and open architecture software ensures Orca could be rapidly configured based on need.
This sort of versatility in a single, low-cost package is fairly unheard of in military spending. The nearest rough equivalent is the Navy’s Littoral Combat Ship, which costs $584 million each  and has a crew of 40. While LCS is faster, has the benefit of an onboard crew, and carries a larger payload, Orca is autonomous—and cheaper by orders of magnitude.
The purchase of these robot subs comes amid a push into autonomous vessels for the service. Last month, the Navy’s autonomous Sea Hunter ship, conducted its first surveillance mission from San Diego to Pearl Harbor, Hawaii, and back without a crew onboard.

The Navy just bought a fleet of robot submarines to prowl the oceans and mess with adversaries

The Navy is bulking up its fleet of autonomous robot vessels with the purchase of a cadre of four of Boeing's extremely large and incredibly grandiose unmanned Orca submarines.
On Feb. 13, the Navy awarded Boeing a $43 million contract to produce four of the 51-foot Orca Extra Large Unmanned Undersea Vehicles (XLUUVs) that are capable of traveling some 6,500 nautical miles unaided, the U.S. Naval Institute reported.
According to USNI, the Navy could potentially deploy the Orcas from existing vessels to conduct "mine countermeasures, anti-submarine warfare, anti-surface warfare, electronic warfare and strike missions."
But as Popular Mechanics points out, the Orca's modular design and relatively inexpensive price tag make the robo-subs a potential game-changer for a Navy that's struggling to grow to 335 hulls:
Orca could even pack a Mk. 46 lightweight torpedo to take a shot at an enemy sub itself. It could also carry heavier Mk. 48 heavyweight torpedoes to attack surface ships, or even conceivably anti-ship missiles. Orca could drop off cargos on the seabed, detect, or even lay mines. The modular hardware payload system and open architecture software ensures Orca could be rapidly configured based on need.
This sort of versatility in a single, low-cost package is fairly unheard of in military spending. The nearest rough equivalent is the Navy's Littoral Combat Ship, which costs $584 million each and has a crew of 40. While LCS is faster, has the benefit of an onboard crew, and carries a larger payload, Orca is autonomous—and cheaper by orders of magnitude.
The purchase comes amid a push into autonomous vessels for the Navy, and not just because of President Donald Trump's newfound focus on artificial intelligence. Earlier this year, the Navy's autonomous Sea Hunter trimaran, engineered for minesweeping and sub-hunting, traveled from San Diego to Hawaii and back again without a single sailor aboard in a historic voyage.
More broadly, the service is eyeing potential unmanned systems for "robot wolfpacks" of remotely-operated surface vessels to function as scouts, decoys, and forward electronic warfare platforms, as Breaking Defense reported in January.
The Navy has pulled all the stops in "the last six or seven months," Navy surface ship executive Rear Adm. William Galinis told Breaking Defense. "We've got a set of RFIs we're going to be putting out here probably in the next few days to industry to really start that process, put some proverbial meat on the bones."

(Web, Naval-technology, Soutfront, Taskandpurpose, Covertshores,  Wikipedia, You tube)