9K32 Strela-2
NATO reporting name: SA-7 Grail
KBM Kolomna 9K32 Strela-2 missile and canister
TypeMan portable surface-to-air missile launcher
Place of origin Soviet Union
Service history
In service1968- present
Used bySee Operators
Production history
DesignerKBM (Kolomna)
Designed1964 approx
VariantsSee versions
Specifications
Mass9.2 kg (Strela-2 missile)[1]
4.17 kg (launcher)
Length1.25 m
Diameter70 mm
Wingspan0.3 m

Effective firing range45 to 3,500 m (Strela-2)
45 to 5600 m (Strela-2M)[2]
Warhead weight1.18 kg HE warhead (Strela-2)
2.5 kg HE warhead (Strela-2M)[2]
Detonation
mechanism
non-delay impact and grazing fuzes, 14–17 second delay self-destruct.

Flight altitude150–1,500 m (Strela-2)
25–4,300 m (Strela-2M)[2]
Maximum speed Mach 1.5 (Strela-2)
Mach 1.95 (Strela-2M)[2]
Guidance
system
Infra-red passive homing
For the STRELA computer, see Strela computer.
For the Apollo test mission see A-102 (SA-7)

The 9K32 “Strela-2” (Russian 9К32 “Cтрела-2” — arrow, (NATO reporting name SA-7 Grail) is a man-portable, shoulder-fired, low-altitude surface-to-air missile system with a high explosive warhead and passive infrared homing guidance. Broadly comparable to the US Army FIM-43 Redeye, it was the first generation of Soviet man portable SAMs, entering service in 1968, with series production starting in 1970 [3].

Described by one expert as being "...the premier Russian export line"[1], the Strela and its variants have seen widespread use in nearly every regional conflict since 1968.

Development

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The end of World War II saw a major shift in Soviet defense policy. The advent of long range, high altitude, nuclear-armed American bombers, capable of penetrating Soviet airspace at heights and speeds unreachable and unmatchable by all existing anti-aircraft guns and most interceptors, at a stroke appeared to render every conventional weapon obselete. To counter this large vulnerability, numerous long-range, high-altitude SAM systems, such as the SA-1 "Guild" and SA-2 "Guideline", were rapidly developed and fielded, but due to the apparent 'obselescence' of conventional arms, relatively little development took place to field mobile battlefield air defences.

This direction was soon to change, however, with the beginning of the Korean war. An entirely conventional conflict, it proved that nuclear weapons were not the be all and end all of warfare. In the face of a powerful and modern American air force, carrying non-nuclear payloads, the Soviet Union invested heavily in a multi-tier air defense system, consisting of several new mobile SAMs, to cover all altitude ranges and protect ground forces. The new doctrine listed 5 requirements:

  • Front-level medium to high altitude area defence system 9K8 Krug (NATO designation SA-4 “Ganef”)
  • Army-level low to medium-range area defence system 3K9 Kub (NATO designation SA-6 “Gainful”)
  • Division-level low altitude short-range system 9K33 Osa (NATO designation SA-8 “Gecko”)
  • Regiment-level all-weather radar-guided gun system ZSU-23-4 “Shilka”
  • Battalion-level very short range systems Strela-1 (NATO designation SA-9 "Gaskin")
  • Platoon level[2] Strela-2 (NATO SA-7 “Grail”)
 
A soviet soldier posing with a Strela launcher.

Both Strela-1 and Strela-2 were initially intended to be man-portable systems. However, as the Strela-2 proved to be a considerably smaller and lighter package, the role of the Strela-1 was changed, becoming a heavier, vehicle-mounted system with increased range and performance, to better support the ZSU-23-4 in the regimental air defense role.

As development began in the Turopov OKB (later changed to Kolomna), detailed information on the design of the US FIM-43 Redeye became available. While it was by no means a simple reverse-engineered copy, in many ways the Strela design borrowed heavily from the Redeye, which had started development a few years earlier. Due to the comparatively primitive Soviet technical base, development was protracted, and many problems arose, especially in designing a sufficiently small seeker head and rocket. Eventually the designers settled for a simpler seeker head than that of the Redeye, allowing the initial version, the 9K32 “Strela-2” (US DoD designation SA-7A, missile round 9M32) to finally enter service in 1968, 5 years behind schedule.

Improvements

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As with many Soviet systems, the Strela-2 was quickly followed by an improved version, the “Strela-2M” (NATO reporting name SA-7b). Introduced in 1971[4], it proved vastly more capable then its predecessor; the use of higher thrust propellant[5] resulted in increases not only to range, speed and altitude, but allowed the size of its warhead to double. Improvements were also made to the guidance and detection systems, allowing the missiles to engage transport planes and helicopters head-on, unless the aircraft were flying faster than 540 km/h.[6] Finally, improved filters were added, increasing resistance to flares and other countermeasures.[5].

The Strela (2M version) was also procured for use on-board Warsaw Pact warships[5]; installed on four round pedestal mounts[5] aboard Soviet amphibious warfare vessels and various smaller combatants, the weapon remained unchanged, but was assigned the NATO reporting name SA-N-5 'Grail'[5].

Description

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The closest foreign analogue to the original Strela, in function and operation, is the American Redeye missile system. Both weapons consist of a reusable firing tube and missile round, the Strela coming preloaded.[nb 1]

Like other early shoulder launched SAM systems, the SA-7a was primarily a tail-chase missile system; its effectiveness depending on the ability of the seeker head to lock on to the heat source of aircraft within its sphere of engagement. Due to the lack of sophistication in filter design, the original Strela's simple infra-red seeker mechanism was easily overwhelmed by anything generating more heat; this included countermeasures such as simple flares, pulsing “hot brick” jammers, and even environmental effects like infra-red reflections from clouds or the sun. The Strela-2 has a small directed-energy blast fragmentation warhead with impact and grazing fuzes. The impact fuze detonates the warhead immediately upon impact, while the grazing fuze reacts to the slightest bending of the missile fuselage. The warhead weighs 1.1 kg, including 370 g HE content in a pre-fragmented casing.

The small warhead had the drawback of low kill probability against jet and especially multi-engine targets; as the missile homed in on the hottest spot, it typically hit only the afterburner nozzles, and due to the small size and instantaneous fuzing was not unusual that it failed to destroy even the engine that was hit. Although the basic warhead design remained the same in all Soviet MANPAD systems from Strela-2/2M through Strela-3 and Igla-1 to the final Igla, the later missiles had much-improved lethality with little extra warhead weight due to better terminal homing aimed at hitting the aircraft fuselage, delayed fusing allowing the missile to penetrate into the target before detonation, and in later variants also a 20 g secondary charge to set off remaining rocket fuel.

 
Damage caused by an Iraqi SA-7, 1990


The missile launcher system consists of the green missile launch tube containing the missile, a grip stock and a cylindrical thermal battery. The launch tube is reloadable at depot, but missile rounds are delivered to fire units in their launch tubes. The device can be reloaded up to five times.[7] The operator points the missile in the direction of the target, applies half-trigger, and observes the internal light. When this light turns from red to green it is locked onto the target. Full trigger is then applied, and the missile is fired.

After visual spotting a target, the Strela-2 operator put the system in the launch position (on his shoulder) and turned the power on. The system’s reaction time from power on was about five seconds. Then the operator aimed the launcher at the target so the missile’s seeker could acquire it. After the missile locked onto the target, a sound and light signal informed the operator. Subsequently, he pushed the trigger to half-position, enabling the gyro to measure the track data. When the missile was ready for launch, the operator was informed by another sound and light signal. He then pushed the trigger fully, and the missile took off from the launcher

Manufacturer lists reaction time measured from carrying position (missile carried at soldier's back with protective covers) to missile launch to be 13 seconds, a figure that is achievable but requires considerable training and skill in missile handling. With launcher on the shoulder, covers removed and sights extended, reaction time from fire command to launch reduces to 6–10 seconds, depending greatly on target difficulty and shooter's skill.

After activating the power supply to the missile electronics, the gunner waits for electricity supply and gyros to stabilize, puts the sights on target and tracks the it smoothly with the launch tube's iron sights, and pulls the trigger on the grip stock. This activates the seeker electronics and the missile attempts to lock onto the target. If the target is producing a strong enough signal and the angular tracking rate is with acceptable launch parameters, the missile alerts the gunner that the target is locked on by illuminating a red light in the sight mechanism, and producing a constant buzzing noise. The operator then has 0.8 seconds to provide lead to the target while the missiles on-board power supply is activated and the throw-out motor ignited.

Should the target be outside acceptable parameters then the light cue in the sight and buzzer signal tell the gunner to re-aim the missile.

On launch, the booster burns out before the missile leaves the launch tube at 32 m/s, and rotating the missile at approximately 20 revolutions per second. As the missile leaves the tube the two forward steering fins unfold, as do the four rear stabilizing tail fins. The self-destruct mechanism is then armed, which is set to destroy the missile after between 14 and 17 seconds to prevent it hitting the ground if it should miss the target.

Once the missile is five and half meters away from the gunner, approximately 0.3 seconds after leaving the launch tube it activates the rocket sustainer motor. The sustainer motor takes it to a velocity of 430 meters per second, and sustains it at this speed. Once it reaches peak speed at a distance of around 120 meters from the gunner, the final safety mechanism is disabled and the missile is fully armed. All told, the booster burns for 0.5 second and the driving engine for another 2.0 seconds.[7]

The missile's uncooled lead sulphide passive infra-red seeker head detects heat emissions between 0.2 and 1.5 μm in wavelength. It has a 1.9 degree field of view and can track at 9 degrees per second. The seeker head tracks the target with an amplitude-modulated spinning reticle (spin-scan or AM tracking), which attempts to keep the seeker constantly pointed towards the target.

The guidance system tracks the movement of the seeker relative to missile body, and uses proportional convergence logic, also known as angle rate tracking system, to guide the missile towards the target on the basis of this information. In practice this means monitoring the seeker's angular velocity, and issuing steering commands to turn the missile towards the direction where the seeker is turning to (not necessarily where it is pointed at), in an attempt to bring the seeker-to-body angle rate to zero. Given constant missile and target velocities and non-maneuvering target, the angle rate is zero when the missile is headed straight towards the intercept point.

Combat use

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As a consequence of their widespread availability and large numbers, the Strela system has seen use in conflicts across the globe.

Middle East

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Jane's credits the first combat use of the missile as being in 1969 during the War of Attrition by Egyptian soldiers. Between this first firing and June 1970 the Egyptian army fired 99 missiles resulting in 36 hits.The missile proved to have poor kinematic reach against combat jets, and also poor lethality as many aircraft that were hit managed to return safely to base.

South-East Asia

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The Strela-2 system was also given to North Vietnam forces, where along with the more advanced Strela-2M it achieved 204 hits out of 589 firings against US aircraft between 1972 and 1975. These produced a total of approximately 40–50 kills, all but one TA-4 Skyhawk against helicopters and propeller-driven aircraft; US fixed-wing losses are listed in the following table. As in the War of Attrition, the missile's kinematic performance proved insufficient against fast jets and results were very poor, although at least one South Vietnamese F-5 was also shot down by a Strela in addition to the US Skyhawk. Against helicopters, however, the system was lethal until the use of decoy flares became common. The United States lost at least 10 AH-1 Cobras and several UH-1 Hueys to Strela-2/2M hits in SEA.

Date Type Unit Altitude
when hit (ft)
Casualties Mission Location
01-05-1972 O-2A 20th TASS ? 0 FAC Quang Tri
01-05-1972 A-1H 1 SOS 3500 0 SAR Quang Tri
02-05-1972 A-1E 1 SOS 5500 0 SAR Quang Tri
02-05-1972 A-1G 1 SOS 6500 1 WIA SAR Quang Tri
14-05-1972 O-1 4000 0 FAC An Loc
26-05-1972 TA-4F H&MS-15 4500 0 armed recce Hue
18-06-1972 AC-130A 16 SOS 12 KIA armed recce A Shau
29-06-1972 OV-10A 20 TASS 6500 1 KIA FAC Quang Tri
02-07-1972 O-1 0 FAC Phum Long (Cambodia)
19-12-1972 OV-10A 20 TASS 1 KIA FAC Quang Tri
27-01-1973 OV-10A 23 TASS 6000 2 MIA FAC Quang Tri

The table shows heavy losses particularly in the beginning of May, with especially lethal results on 1st-2nd of May, where the shootdown of the O-2 FAC led to further losses when rescue operation was attempted. After the initial success, changes in tactics and widespread introduction of decoy flares helped to counter the threat, but a steady flow of attrition and necessity of minimizing time spent in Strela envelope nonetheless continued to limit the effectiveness of US battlefield air operations until the end of US involvement in South-East Asia.

In the late 1980s, Strela-2s were used against Royal Thai Air Force aircrafts by Laotian and Vietnamese forces during the numerous border clashes of that period. A RTAF F-5E was damaged on 4 March 1987 and another F-5E was shot down on 4 February 1988 near the Thai-Cambodian border.

Afghanistan

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An Afghan Mujahideen with a Strela 2

Strela-2M was used also in Afghanistan during the Soviet invasion by the Mujahiddeen. The missiles were obtained from various sources, some from Egypt and China (locally manufactured Sakr Eye and HN-5 versions of the SAM), and the CIA also assisted the guerrillas in finding missiles from other sources.

Results from combat use were not dissimilar from experiences with the Strela-2/2M from SEA: while 42 helicopters were shot down by various Strela-2 variants, apparently including also a few Mi-24s until exhaust shrouds made them next to invisible to the short-wavelength Strela-2 seeker, only 5 fixed-wing aircraft were destroyed with the weapon. Due to its poor kinematic performance and vulnerability to even the most primitive infra-red countermeasures, the guerrillas considered the Strela-2 suitable for use against helicopters and prop-driven transports, but not combat jets.

Rhodesia

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During the Rhodesian Bush war (1964–1979) terrorists utilised the Strela against unarmed civilian aircraft and brought down two Vickers Viscount passenger aircraft belonging to Air Rhodesia. There was great loss of life in both instances as the flights were returning from Kariba, a well known tourist attraction.

Vickers Viscount, Flight RH825, 3 September, 1978 — shot by down Strela missile near Kariba Dam. 18 of the 56 passengers survived the crash, but ten of them were executed on the ground by ZIPRA guerrillas.[1] Vickers Viscount, Flight RH827, 12 February, 1979 — shot by down Strela missile near Kariba Dam; all 59 people on board killed.

In the first incident the terrorists followed up the crashed aircraft and systematically murdered survivors from the aircrash as they lay in the wreckage. The Archbishop of Mashonaland described this act as the most barbaric act of the war in a well publicised sermon that subsequently saw him removed from his post.

 
Confiscated Serbian SA-7s awaiting destruction

Other use

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Strela-2M missiles were available to Argentinian troops in the Falkland Islands during the 1982 war. A handful of missiles were fired, but no kills were scored.

The system was used on a large scale during wars in former Yugoslavia by all Yugoslav successor states and factions engaged in air defence operations.

Two missiles were fired during the 2002 Mombasa attacks both missing a Boeing 757. [8][9] It was said that had the attackers waited until the plane had reached a higher altitude, they would have had a better chance of hitting it.[10]

A missile was fired on a DHL airbus leaving Baghdad in 2003, striking and forcing it to crash land. [9]

They are used with other MANPAD systems in the ongoing Iraqi and Afghan wars, however with limited success [1], while al Qaeda is said to have produced an hour-long training video on how to use SA-7s.[11][12]

In 2006, an Apache helicopter was reportedly downed by an SA-7; the helicopters were designed to be able to withstand such hits, but this one did not.[13]

Versions

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  • 9K32M Strela-2M — "SA-7b Grail"
  • Strela 2M2J Sava — Yugoslav version
  • CA-94 and CA-94M — Romanian versions
  • HN-5 — Hongying 5, Chinese version
  • Anza MKI — Pakistani version
  • Ayn al Saqr (Known as Sakr Eye)  — Egyptian version[14]
  • Hwasung-Chong — North Korean version

Operators

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Egyptian jeep mounted Strelas
 
Mongolian operated Strela

Former Operators

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References

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  1. ^ a b Twentieth Century Artillery (ISBN 1-84013-315-5), 2000, Ian Hogg, Chapter 6, P226.
  2. ^ a b c d e Weapons of the Gulf War (ISBN 0-86101-615-7), 1991, Ian Hogg-Doug Richardson-Bill Gunston, Land Weapons-P121.
  3. ^ Jane's Land Based Air Defence 2005-2006.
  4. ^ Jane's Air Launched Weapons, Issue 44
  5. ^ a b c d e War Machine, Issue 64 (Magazine), 1984, Orbis Publications, P1274.
  6. ^ http://www.fas.org/programs/ssp/asmp/MANPADS.html
  7. ^ a b c http://www.bellum.nu/armoury/SA7Grail.html
  8. ^ Proliferation of MANPADS and the threat to civil aviation - Jane's Security News
  9. ^ a b Microsoft PowerPoint - présentation bolkcom
  10. ^ http://technology.newscientist.com/channel/tech/aviation/dn3127
  11. ^ http://home.nycap.rr.com/mismedia/SAM/SAM%20Use%20in%20Current%20Terrorist%20Operations.htm#BS
  12. ^ http://edition.cnn.com/2002/WORLD/africa/11/28/missiles/index.html
  13. ^ http://abcnews.go.com/WNT/International/story?id=1515168
  14. ^ http://www.aoi.com.eg/aoi_eng/milit_new/rocket/sakreye.htm
  15. ^ http://en.rian.ru/world/20081208/118747764.html

Notes

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  1. ^ It is reloadable at depot, but missile rounds are delivered to fire units in their launch tubes. The device can be reloaded up to five times.[7]
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Category:Surface-to-air missiles of the Soviet Union Category:Falklands War guided missiles Category:Vietnam War guided missiles