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Soviet variable-sweep wing fighter-bomber From Wikipedia, the free encyclopedia
The Sukhoi Su-17 (izdeliye S-32; NATO reporting name: Fitter) is a variable-sweep wing fighter-bomber developed for the Soviet military. Developed from the Sukhoi Su-7, the Su-17 was the first variable-sweep wing aircraft to enter Soviet service and featured updated avionics. The aircraft also has variants which were designed to be exported to non-Soviet states such as the Sukhoi Su-22 and the less popular Su-20.
Su-17/-20/-22 | |
---|---|
General information | |
Type | Fighter-bomber |
National origin | Soviet Union |
Manufacturer | Sukhoi |
Status | In limited service |
Primary users | Soviet Air Forces (historical) |
Number built | 2,867 |
History | |
Manufactured | 1969–1990 |
Introduction date | 1970 |
First flight | 2 August 1966 |
Developed from | Sukhoi Su-7 |
It was produced from 1967–1990. The Su-17/20/22 series had a long career and has been operated by many air forces, including those of the Russian Federation, former Soviet republics, former Warsaw Pact, countries in the Arab world, Angola, and Peru. The Russian Federation retired its fleet in 1998.
Although the Su-17 was capable of carrying nuclear weapons, it was used in roles ranging from close-air support to ground attack.
Shortly after the Su-7 fighter-bomber was put into service, the Sukhoi Design Bureau was ordered to develop a modernization program. The program would be aimed primarily at updating on-board avionics and takeoff/landing characteristics. The concept of variable-geometry wings - something gaining wider attention at that time - was adopted. The program was to be led by Sukhoi's head designer, Nikolay Zyrin.[citation needed]
In 1963, the Sukhoi OKB with input from TsAGI created a variable-sweep wing technology demonstrator. The S-22I (also known as the Su-7IG, NATO designation "Fitter-B"), converted from a production Su-7BM, had fixed inner portions of the wing with movable outer segments that could be swept to 28°, 45°, or 62°.[1] The S-22I first took off (with Vladimir Ilyushin at the controls) on 2 August 1966. It was later demonstrated at the air parade in Domodedovo in July 1967.
Flight testing revealed that the configuration improved both take-off/landing characteristics, range and endurance. Handling was generally better than the fixed wing Su-7, with the exception that buffeting at high angles of attack to warn of imminent stall no longer occurred.
The aircraft was sent into serial production in 1969 by a joint resolution of the Central Committee of the Communist Party of the Soviet Union and the Council of Ministers.[2][3] The design of the Su-7IG was modified further, eventually with enough difference to justify the S-32 internal designation. The S-32 first took off on July 1, 1969, with Yevgeny Kukushev at the controls.[citation needed]
Serial production started at Yuri Gagarin Aviation Factory (now KnAAPO) in 1969. The 523rd Aviation Regiment, of the Far East Military Okrug, was the first to receive the Su-17. The Su-17 was produced until 1990, producing 2867 units.[citation needed]
The Su-17 resembles its predecessor, the Su-7, with weight-saving measures added at the cost of combat survivability, an example of which is the removal of pilot protection armor.[citation needed]
The prototype S-22I differed little from the Su-7 except for the wing, essentially a technology demonstrator for the variable-geometry wing. It was later lost in an accident.[citation needed]
Following the S-22I, two pre-production prototypes were constructed, designated S32-1 and the S32-2. The two aircraft mounted updated avionics, and replaced the older AP-28I-2 autopilot with the newer SAU-22 automatic control system.[citation needed]
The next series of prototypes were the Su-7-85, with 85 indicating the batch number. The batch of ten aircraft incorporated a redesigned fuselage, a streamlined cockpit (similar to the Su-7U), extra, more accessible maintenance hatches, and an upward-opening canopy. The front of the cockpit was protected with a windshield and two electrically heated side windows. The first three aircraft of the 86th batch incorporated clear windshields with warm air blown at them, taken from the 9th stage of the engine compressor. However, this windshield was dropped in favor of the more traditional glazed windshield following tests by the 4th Combat Use and Retraining of Air Force Personnel Center in Lipetsk.[citation needed]
The Su-7-85 was equipped with a modified KS4-S32 ejection seat, capable of safely ejecting the pilot at speeds above 140–170 km/h.[citation needed]
The fuel system was modified from the Su-7, as well; fuel was stored in three lightweight tanks, with provisions for up to four disposable auxiliary tanks each with 600 litres of capacity (itself used on the Su-7B), or two PTB-1150 tanks with 1150 litres each, mounted on "wet" pylons under the fuselage.[citation needed]
The wing was largely unmodified from the S-22I. The stationary part of the wing was half as long as the rotating part. With wings at maximum sweep, the Su-17 would look virtually identical to the Su-7. A slide-out flap was installed on the stationary part of the wing, while a slat, a rotating flap and aileron were mounted on the rotating part. The sweep angle could be configured between 30° and 63°. The horizontal and vertical tails were swept at 55°.[citation needed]
Flight control was assisted by non-reversing hydraulic boosters, the BU-220DL2 and -220DP2 for the left and right ailerons, the BU-250L and -250P for the stabilizers and the BU-250DRP for the rudder. The flight control systems were spring-loaded to provide feedback on the stick and the rudder pedals.[citation needed]
Three independent hydraulic systems are installed on the Su-17—an actuating system and two booster systems, each with a hydraulic pump. The actuating hydraulic system was responsible for adjusting the sweep angle of the wing, deploying/retracting the landing gear, the flaps and slats, adjusting the intake ramps, the flight control mechanisms used by the SAU-22 autopilot, and the steering front wheel. The booster systems control the flight surfaces. The systems operate in parallel to ensure safe operation in the event of a failure. The remaining operational system would provide power to the flight surfaces, albeit at half the power. The Nr 1 booster system feeds the GM-40 hydraulic motor driving the rotary parts of the wing. All hydraulic systems are fed with the AMG-10 hydraulic fluid, with a standard operating pressure of 215 kgf/cm2 for the booster systems and 210 for the actuating system.[citation needed]
A pneumatic system with a 150kgf/cm2 pressure operates the normal and emergency brakes on the landing gear as well as the emergency landing gear/flaps deployment system, and was responsible for charging the two NR-30 cannons mounted on the aircraft, pressurizing the cockpit, opening/closing the canopy and pressurizing the hydraulic fluid tanks.[citation needed]
The Su-17 was powered by a modified Lyulka AL-7F1-250 with a slightly uprated thrust of 9600 kgf on afterburners. It was equipped with a compressor actuator with redundancy, and a system for intake adjustment. The aircraft would need to be disassembled into two halves to replace its engine. Jettisonable SPRD-110 RATO boosters are available to facilitate take-off on short runways, providing a momentary thrust of up to 3000 kgf.[citation needed]
On-board electronics are fed by a 28V DC circuit and a 115V, 400 Hz single-phase AC circuit, fed by two GS-12T DC generators, an SGO-8TF AC generator and a 20NKBN25 nickel–cadmium battery.[citation needed]
The Su-17 has the ability to carry free-fall nuclear bombs with a BDZ-56FNM bomb rack. A special code device would be installed in the cockpit, mandating a correct code input before the bomb could be armed and released, to prevent unauthorized uses of nuclear weaponry. The aircraft also has a toss bombing capability for nuclear weapon delivery, with which it could approach the target, initiate a steep climb and release the bomb when pointing almost upright, and then activate afterburners to escape the blast radius. A special IAB-500 bomb was made specifically for practicing such a bombing technique.[citation needed]
The Su-17 was used during the Soviet-Afghan war during Operation South and launched air strikes a mujahideen base at Robat Jaali near the Iranian Afghan border.
The Su-17M3/4 were used during the First Chechen War alongside Sukhoi Su-24s and Sukhoi Su-25s in ground attack and reconnaissance missions.[4]
In a move to eliminate single-engine strike aircraft from its inventory, the Russian Air Force retired its last Su-17M4 along with its fleet of MiG-23/27s in 1998.
The Soviets supplied the communist government of Angola with 12 Su-20Ms in 1982 or 1983, which formed the basis of the 15th FS. The squadron suffered a swift loss of at least six aircraft – most in mishaps – by 1985, and three more by 1988, and had only two aircraft left when it was reinforced with batch of 14 Su-22M-4Ks and two Su-22UM-3Ks in 1989–90 (incorporated into the 26th Air Regiment, based in Moçâmedes).[5]
From 22 September 1980 to 20 August 1988, during the Iran–Iraq War, Iraq used Su-17 export versions (Su-20 and Su-22) alongside older Su-7s. They were mostly used in ground-attack and close air support roles. Iranian Grumman F-14 Tomcats shot down 21 Su-20/-22s, that have been confirmed by western sources. Eighteen Su-20/-22s were also shot down by Iranian McDonnell Douglas F-4 Phantom IIs.[6] and three by Iranian Northrop F-5s.[7] On 20 October 1980 an Iraqi Su-20 shot down an Iranian F-4E with its 30 mm cannons.[6]
Official Iraqi accounts show no loss of Su-20 aircraft throughout the war against the Kurds and Iran. Twenty Su-22M2s, two Su-22M3s and seven Su-22M4s were lost during the war with Iran, the majority to anti-aircraft fire sustained during low-level bombing raids against Iranian front lines.[8]
In 1991, during the Gulf War, Iraqi Su-22s saw limited active service because the Iraqi regime distrusted the Iraqi Air Force (IQAF). On 7 February 1991, two Su-20/22s and one Su-7 were shot down by United States Air Force McDonnell Douglas F-15 Eagles using AIM-7 air-to-air missiles[9] when the IQAF was moving its aircraft to Iran.
On 20 and 22 March 1991, two other Su-22s were downed by USAF F-15s in an attempt to protect Kurdish civilians before the start of Operation Provide Comfort to provide humanitarian aid and the establishment of a no-fly zone north of 36th parallel.[10]
Two Libyan Su-22s were shot down in the Gulf of Sidra incident by United States Navy Grumman F-14 Tomcats on 19 August 1981. One Su-22 launched a K-13 missile head-on at one of the F-14s from an estimated 300-meter (984-foot) closing distance, however the missile was evaded. Both were then downed by AIM-9 Sidewinder missiles.
On 8 October 1987, in the aftermath of the Chadian–Libyan conflict, an Su-22 was shot down by a FIM-92A Stinger launched by Chadian forces. The pilot, Capt. Diya al-Din, ejected and was captured. He was later granted political asylum by the French government. During the recovery operation, a Libyan Mikoyan-Gurevich MiG-23MS was shot down by a Stinger.[11]
A Libyan Su-22 crashed near Benghazi on 23 February 2011. The crew members, Captain Attia Abdel Salem al Abdali and his copilot, Ali Omar Gaddafi, were ordered to bomb the city in response to the Libyan Civil War. They refused, bailing out of the aircraft.[12][13] Su-22s were heavily used by Libyan loyalist forces against insurgent forces from mid-February to mid-March 2011, when the international mission started and the no fly zone was imposed. Among other missions, Su-22s attacked Anti-Gaddafi positions in Bin Jawad in early March 2011 as government forces retook the town.[14][15]
One Libyan Air Force Su-22 was destroyed on the ground by a Belgian Air Force F-16AM on 27 March.[16]
Peru was the only export customer of the type in the Americas.
On 24 April 1992, in a context of diplomatic and political tensions between Peru and the US after the autocoup orchestrated by Peruvian President Alberto Fujimori 19 days before, Peruvian Su-22s attacked a Lockheed C-130H Hercules of the United States Air Force's 310th Airlift Squadron which was intercepted at sea, northwest of Lima, injuring six of the 14 crew members. Master Sergeant Joseph C. Beard Jr. was killed when he was sucked from the cabin at 18,500 feet, and crew member Ronald Hetzel sustained severe injuries.[17][18]
The Hercules' pilot barely managed to land the crippled plane, with one engine damaged and three blown landing tires, at a Peruvian Air Force base near the city of Talara, where the crew was detained, and the bullet-ridden plane impounded, before being freed after US government pressure.[19] The incident caused an almost year-long interruption to the US anti-drug Air Bridge Denial Program and the establishment of a Joint Air Operation Center at Howard Air Force Base in Panama, from where the C-130 had been operating.[20][21]
During the brief 1995 Cenepa War between Peru and Ecuador, two Peruvian Sukhoi Su-22s were lost, on 10 February when two Ecuadorian Air Force Mirage F1JAs, piloted by Maj. R. Banderas and Capt. C. Uzcátegui, were directed over five targets approaching the disputed Cenepa valley. After making visual contact, the Mirages launched their missiles, however the Ecuadorian Air Force never showed the HUD videos of the fighters confirming the shootdowns, claiming two Peruvian Su-22As shot down, while a Kfir claimed a further Cessna A-37 Dragonfly.[22][23][24][25] Peru, however, denied that the two Su-22As were shot down by Mirages, stating that one was struck by Ecuadorian anti-aircraft artillery during a low flying ground-attack mission and the second crashed because of an engine fire.[26][27][28]
The Su-22s flew 45 sorties into the combat zone. A 20-strong force of Su-22s was established at El Pato as a retaliatory force should Ecuador decide to attack the coastal port.[29]
On 19 August 2003, a Polish Air Force Su-22M4K was accidentally shot down by friendly fire during an exercise by a Polish 2K12 Kub missile battery. The aircraft was flying 21 km from the coast over the Baltic Sea near Ustka. The pilot ejected and was rescued after two hours in the water.[30] In 2012, Poland was investigating the replacement of its Su-22s with three squadrons of unmanned aerial vehicles.[31]
As of 2014 the Polish Air Force was planning to retain the Su-22s in service. The decision was hoped to have a positive impact on Polish industry, as the WZL nr 2 repair facility in Bydgoszcz would maintain the remaining aircraft under contract to the Air Force. The decision would also allow the Air Force to retain the well-trained ground crews and pilots operating the aircraft. The Poles consider the Su-22 easier to maintain and repair than the other main combat aircraft types currently in Polish service (mainly the MiG-29 and the F-16). They suffer from fewer malfunctions and other problems (high, 70–75% non-error index). It is the only aircraft in Polish inventory equipped for electronic intelligence, warfare, and support of ground systems. The Polish Air Force retained a large stockpile of air-to-ground weapons for use with the Su-22. By some estimates, the cost of destroying these resources would be higher than the projected cost of continuing Su-22 operations.[32]
It was decided that starting from 2015, only 12 Su-22M4s and 4-6 Su-22UM3Ks out of 32 remaining would undergo a refit, extending their lifespan by ten years.[33] For economic reasons the aircraft are not modernized, apart from fitting an additional RS-6113-2 C2M radio with a blade antenna on the top, but they received a grey multishade camouflage, similar to other Polish aircraft.[33][34] Several Polish Su-20s and Su-22s were donated to various museums, including the Polish Army Museum in Warsaw, the Armament Museum in Poznań, the Museum of Polish Arms in Kołobrzeg and the Polish Aviation Museum in Kraków.[35] Other were placed on monuments or donated to schools as technical aids.
Following the acquisition of 48 KAI T-50 Golden Eagle aircraft from South Korea in 2022, the Su-22 fleet was to be retired.[36]
The Syrian Air Force (SyAAF) used Su-20/-22s to attack Israeli forces in the Yom Kippur War[4] and 1982 Lebanon War. Several Su-20/-22s were shot down by the Israeli Air Force.[37][38] From mid-2012, in the Syrian Civil War, Syrian Air Force Su-22s were involved in combat operations against Syrian insurgents.[39] Videos showed Su-22s using unguided munitions like other SyAAF fixed-wing aircraft; mostly general-purpose bombs, cluster bombs and incendiary bombs and unguided rockets. Attack tactics were low to medium-altitude flat bombing runs with pull up after rocketing or bombing, deploying decoy flares for self-defense.[40] As of the end of 2015, the SyAAF Su-22s suffered fewer losses compared to the SyAAF MiG-21 and MiG-23. The first confirmed loss of an SyAAF Su-22 was recorded on 14 February 2013, when rebel forces shot it down using MANPAD.[41][unreliable source?] On 18 June 2017, a US F/A-18E Super Hornet engaged and shot down an SyAAF Su-22[42] for dropping munitions on US-backed forces.[43] According to the wingman of the Super Hornet that made the kill, the Syrian pilot was able to eject[44] and was later returned to the Syrian government. On 24 July 2018, an SyAAF Su-22 that entered Israeli airspace was shot down by two Israeli Patriot missiles.[45][46] Other Syrian Su-22 jets were downed during the ongoing civil war.
On 11 August 2009, Yemeni armed forces started Operation Scorched Earth in northern Yemen to fight Houthi rebels. The Yemeni Air Force backed the army with air raids on rebel positions. On 5 October 2009, a Yemeni Su-22 crashed, with the rebels claiming to have shot it down.[47] Earlier on 2 October, the Yemeni revolutionaries said they shot down a "MiG-21" while the military insisted technical problems caused the crash.[48] On 8 November, a third Yemeni fighter aircraft, reported to be a Sukhoi, was destroyed. Again the military alleged technical problems, while the Yemeni rebels claimed they shot it down.[49] The pilot ejected and was recovered by friendly forces. The Yemeni Air force used Sukhoi aircraft during the Arab Spring uprising. On 28 September 2011, a Yemeni Air Force Su-22 was shot down by tribesmen opposed to the rule of President Saleh. The government confirmed that rebels were responsible for the shoot-down, and that the pilot had been captured.[50] On February 19, 2013, a Yemeni Su-22 on a training mission crashed for unknown reasons into Sana'a, killing 12 civilians.[51] On May 13, 2013, another Yemen Su-22 on a training mission crashed in Sana'a, killing the pilot.[52]
Multiple Su-17 variants were examined.[53]
Fitter-C was the initial production version, with a dorsal spine similar to that of the Su-7U (carrying wiring and equipment).[56] It was powered by the same Lyulka AL-7F-1 engine as the Su-7.[57] It was manufactured between 1969 and 1973,[53] with a total of 224 built.[58]
This version used the Lyulka AL-21F-3 engine, and an updated navigation and attack computer. The Su-7BMK's SRD-5M ranging radar was retained. Twin pitot tubes, angle of attack vane, single brake parachute. The variable-position intake centerbody provided maximum speed of Mach 2.1. This version was first flown on 28 December 1971 by V. S. Soloviev. The export version was designated Su-20, and was first flown on 15 December 1972 by A. N. Isakov. The Su-17M was manufactured between 1972 and 1975, and entered service in 1973. The Su-20 was exported to Egypt, Poland, and Syria. The Su-17M was fitted with a modified fuselage and wing-sweep mechanism (without driveshafts). The fuel system consisted of a central tank, three interconnected, pressurized follower tanks feeding the central tank, and two additional follower tanks in the fixed part of the wing. The Su-17M was fitted with the SPO-10 Sirena-ZM radar warning receiver and the ARK-15 Tobol radio compass.[citation needed]
Testbed for Kh-28 (AS-9 Kyle) anti-radiation missile
Small number of Su-17M aircraft equipped to carry reconnaissance pods. Equivalent export version designated Su-20R.
The nose extended 38 cm (15 in), with removed ranging radar and 'drooping' to improve pilot visibility. It was equipped with the Fon-1400 laser rangefinder/marked-target seeker (LRMTS), ASP-17 and PBK-3-17s aiming avionics, RSBN-6S short-range navigation and instrument landing system. It featured an undernose fairing for a DISS-7 Doppler navigation radar. The Su-17M2 first flew on 20 December 1973 with V. S. Ilyushin at the controls. It was manufactured between 1974 and 1977, and it entered service in 1975. GMRThe design of the Su-17M was further modified into what would become the Su-17M2, with three pre-production aircraft used as prototypes. The KN-23 navigation system taken from the MiG-23 was installed, with an IKV inertial attitude indicator, a DISS-7 Doppler velocity sensor, air signal systems, and a V-144 analog computer with its own input panel. With the RSBN-6S Romb-K navigation system and the SAU-22M autopilot, the KN-23 provided the capability of automatically navigating along a route defined by three turning points before heading for the target location. The V-144 stored four sets of coordinates for landing airfields, and made it possible for the aircraft to automatically approach the airfield for landing and descend to an altitude of 50-60 meters prior to manual landing. The SOD-57M transponder was replaced with the newer SO-69. During its service, the SRO-2M transponder was replaced with the newer Parol (Russian for "Password") system. A Fon-1400 laser rangefinder was installed under the inlet cone. The Delta NG missile control system, designed to send command signals to the Kh-23 Grom missile, was integrated into a pod under the wing. The Su-17M2 was fitted with the ASP-17S gunsight and a PBK-3-17S bombsight. The fuel system received a nitrogen pressurizer with a 200 kg capacity increase. Starting from aircraft Nr 03909 a central fuel feed system was introduced with the installation of the ETsN-45 fuel pump. The Su-17M2 was capable of carrying the Kh-25 air-to-ground missile, fitted with the 24N1 laser seeker. This was first tested by retrofitted Su-7BMs and Su-17Ms, designated Su-17MKG. The Su-17M2 could carry two such missiles, one each under the wing, mounted on an APU-68U or UM rack. The missiles were guided using a Prozhektor-1 laser-designator pod. The Su-17M2 had an unofficial nickname, s borodoy, which means "with a beard" in Russian.[citation needed]
This model was a test-fit of the Tumansky/Khatchaturov R-29BS-300 engine (shared with some MiG-23s), with 112.7 kN (25,335 lbf) afterburning thrust, in a bulged rear fuselage. Due to lack of performance advantage and decreased range due to higher fuel consumption, this engine was for export only. This version first flew on 31 January 1975 with A. N. Isakov at the controls. The export variant was designated Su-22 (factory code S-32M2K, NATO "Fitter-F"). It was manufactured between 1977 and 1978.
This was the first two-seat trainer version, based on the Su-17M2. It featured a deeper fuselage with a windscreen moved forward. It was the same length as the Su-17M. The internal fuel capacity was reduced and the port cannon deleted, but the aircraft retained full avionics and armament. The Su-17UM first flew on 15 August 1975 with V. A. Krechetov at the controls. Test flights revealed longitudinal instability at high angles of attack which was remedied by enlarging the tail fin. The export version with the R-29 engine was designated Su-22U. The Su-17UM was manufactured between 1976 and 1978, and entered service in 1976.
The Su-17M3 and its export versions represented the most numerous variant, with almost 1,000 built. The M3 was based on the revised airframe of the Su-17UM, adding an avionics bay and an additional fuel tank in place of the rear cockpit. The internal fuel capacity grew to 4850 L (1,280 U.S. gal). The Doppler radar was moved internally, and the fairing was removed. The M3 was equipped with the Klen-P laser rangefinder/target designator. A launch rail for Vympel K-13 or Molniya R-60 air-to-air missiles was added between the two pylons on each wing. GMRThe Su-17M3 first flew on 30 June 1976 with V. A. Krechetov at the controls. Its export version with the R-29 engine and downgraded avionics (equivalent to those of the Su-17M2) was designated Su-22M (factory designation S-52K, NATO "Fitter-J") and first flew on 24 May 1977 with E. S. Soloviev at the controls. An export version with Su-17M3 avionics was designated Su-22M3 (factory S-52MK). The Su-17 was manufactured from 1976 to 1981, and the Su-22M from 1978 to 1984. The Su-17M3 was planned at the same time as the UM trainer. Fuel capacity was increased by 260kg. Starting from the 38th batch the tailfin was raised with a radiotransparent guide and a fin was added on the underside of the tail to improve high-speed stability. A new KN-23-1 navigation system, the SAU-22M1 autopilot and the RV-15 (A-031) radio altimeter were added. Some aircraft later received an RSDN-10 Skip-2 (A-720) long-range radio navigation system, with its antenna installed on the tailfin's leading edge. The SARPP-12GM flight recorder was replaced with the Tester-UZ recorder, and the SPO-10 radar warning receiver was replaced with the SPO-15A (izdeliye L006L) Beryoza. A Klyon-PS combined laser rangefinder/designator was installed, alongside the ASP-17BTs sight. The Su-17M3 could carry an SPS-141 (or the 142-143) Siren or an SPS-141MVG Gvozdika ECM pod. Infrared countermeasures could be deployed via KDS-23 launchers. The BSPPU fire-control system was used, which would control SPPU-22-01 gun pods suspended on the wings to automatically stay on target up to a depression angle of 30°. Two additional hardpoints were placed under the fuselage, with S-52-8812-300 pylons, on which BDZ-57MT or MTA racks could hold APU-68UMs, which in turn could carry Kh-23M or Kh-25 missiles. These hardpoints would be capable of carrying the Kh-25ML or MR missiles, as well as the Kh-29L, mounted on an AKU-58 ejector rack. Some of the Su-17M3s were modified to the Su-17M3P standard, which would enable them to carry up to four Kh-27PS, two on the wings and two under the fuselage, or two Kh-58 anti-radiation missiles, which could be carried only on the fuselage pylons. A Vyuga-17 (L-086) target designator pod could be installed under the fuselage, with its receiver integrated into the nose. The BDZ-57MT racks could also hold ordinary ordnance, such as the UB-16, -32 or the B-13L rocket pods, free-fall bombs, KMGU submunition containers, and the SPPU-22-01 gun pods. In a somewhat unconventional manner, the S-52-8307-200 pylons could be mounted on the aircraft, on which the gun pods would be installed in a rearwards-facing manner, pointed downwards at 23°, and fired as the aircraft flew away from ground targets. The first Su-17M3s were unpainted with the silver color from the anodized duralumin. Later Su-17M3s, as well as all variants that followed, were painted with a green camouflage pattern on the top, and blue on the bottom. This camouflage pattern eventually found its way to all Su-17s in service, and the paint jobs were done at repair plants. The camouflage pattern - the locations of the paint dots - was not standardized, thus each aircraft had its own "unique" camouflage. The Su-17M3 would also have a trainer variant designated the Su-17UM3.[citation needed]
The initial trainer version with the same avionics suite as the Su-17M. The export version was designated Su-22UM3 with R-29 engine, and Su-22UM3K with the AL-21 engine. It was manufactured from 1978 to 1982.
This was a revised trainer with the same avionics suite as the Su-17M3. The Su-17UM3 first flew on 21 September 1978 with Yu. A. Yegorov at the controls. The export version was designated Su-22UM3 with R-29 engine, and Su-22UM3K with the AL-21 engine. It was manufactured between 1978 and 1982.
This was the final production version, with upgraded avionics, including RSDN navigation (similar to LORAN), beacon navigation, inertial navigation, radio compass, and SPO-15LE radar warning receiver. It featured additional fuselage inlets (including a ram-air inlet at the base of the fin) to improve engine cooling airflow, and a fixed air intake shock cone. Many aircraft were equipped for the use of video-guided missiles and BA-58 Vjuga pod for anti-radiation missiles. The Su-17M4 was equipped with the AL-21F-3 engine, and its export version was designated Su-22M4 (factory S-54K). The Su-17M4 first flew on 19 June 1980 with Yu. A. Yegorov at the controls. The Su-17M4 was manufactured from 1981 to 1988, and the Su-22M4 from 1983 to 1990. GMRThe Su-17M4 differed from the Su-17M3 in the removal of the inlet cone control system, which restricted the maximum allowable flight speed to Mach 1.75. The inlet cone housed the more powerful Klyon-54 laser rangefinder. The avionics differed significantly from its predecessors - a new A-312 Radikal NP close- and A-720 Skip-2 long-range navigation systems, an ARK-22 radio compass, an MRP-66 radio beacon receiver, an RV-21 Impuls (A-035) radio altimeter, and the DISS-7 Doppler velocity sensor, air signal systems, the IKV-8 inertial attitude indicator inherited from the Su-17M2. The Vyuga target designator pod could be carried in a BA-58 pod under the fuselage, which would enable the use of the Kh-27PS and Kh-58U or E missiles. Some Su-17M4s were fitted with the IT-23M indicator, which would transmit video from the Tubus-2 seeker on the Kh-29T missile to facilitate target acquisition.[citation needed]
This was a proposed upgraded variant with a new fixed wing based on the swing wing at 45 degrees sweep,[59] new avionics, and an AL-31F turbofan. It was not built.
This was the initial export version of the Su-17M (S-32MK).
This was a Russian-French upgrade package offered for existing aircraft with modernized cockpit, HOTAS, improved avionic systems, and laser rangefinder replaced by Phazotron/Thomson-CSF radar.[citation needed]
The S-52U two-seat combat-trainer, export version of the Su-17UM, with a completely re-designed nose housing the tandem cockpits for student and instructor. Gun pods such as the GSh-23 based UPK-23 and SPPU-22 were utilized by the Su-17, Su-20, and Su-22. The SPPU-22 ground attack variant featured 30 degrees of traverse.
An experimental version of the Su-20 was built with fixed wings attached to an Su-17M fuselage, in an effort to increase Payload/range performance by eliminating the weight of the wing sweep system. Good results were obtained in flight tests in 1973, but further development was cancelled.
Tactical Reconnaissance versions of all variants could be made by fitting the KKR (Kombinirovannyi Konteiner Razvedky – combined reconnaissance pod) on the centre-line hardpoint.
Data from Sukhoi,[83] Wilson,[84] deagel.com[85]
General characteristics
Performance
Armament
Related development
Aircraft of comparable role, configuration, and era
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