M270 Multiple Launch Rocket System

M270 Multiple Launch Rocket System (MLRS)

M270 MLRS
Type Multiple rocket launcher
Place of origin United States
Service history
In service Since March 31, 1983
Used by See Operators
Wars Gulf War
War in Afghanistan
Iraq War
Production history
Designer Vought Corporation
Designed 1977
Manufacturer Lockheed Martin, Diehl BGT Defence, Aérospatiale
Produced 1980–2003
Variants

M270A1

M270B1
Specifications
Weight 55,000 lb (24,950 kg)
Length 22 ft 6 in (6.85 m)
Width 9 ft 9 in (2.97 m)
Height 8 ft 6 in (2.59 m)
Crew 3

Rate of fire

Rockets: 12 rounds in < 40 sec

Missiles: 2 rounds in 10 sec
Effective firing range M26: 32 km (20 mi)
M26A1/A2: 45 km (28 mi)
M30/31: 70 km (43 mi)
GMLRS+: 120 km (75 mi)[1][2][3]
Maximum firing range ATACMS: 165 or 300 km (103 or 186 mi)

Main
armament
M269 Launcher Loader Module
Engine Cummins Diesel
500 hp (368 kW)
Operational
range
400 miles (640 km)
Speed 40 mph (64.3 km/h)

The M270 Multiple Launch Rocket System (M270 MLRS) is an armored, self-propelled, multiple rocket launcher; a type of rocket artillery.

Since the first M270s were delivered to the U.S. Army in 1983, the MLRS has been adopted by several NATO countries. Some 1,300 M270 systems have been manufactured in the United States and in Europe, along with more than 700,000 rockets. The production of the M270 ended in 2003, when a last batch was delivered to the Egyptian Army.

Overview

The weapon can fire guided and unguided projectiles up to 42 km (26 mi). Firing ballistic missiles, such as the U.S. Army Tactical Missile System (ATACMS), it can hit targets 300 km (190 mi) away; the warhead in such shots reaches an altitude of about 50 km (164,000 ft). The M270 can be used in shoot-and-scoot tactics, firing its rockets rapidly, then moving away to avoid counter-battery fire.

MLRS was developed jointly by the United Kingdom, United States, Germany, France and Italy. It was developed from the older General Support Rocket System (GSRS). The M270 MLRS weapons system is collectively known as the M270 MLRS Self-propelled Loader/Launcher (SPLL). The SPLL is composed of three primary subsystems: the M269 Loader Launcher Module (LLM), which also houses the electronic Fire Control System, is mated to the M993 Carrier Vehicle. The M993 is a derivative of the Bradley Fighting Vehicle chassis.[4][5]

The rockets and ATACMS missiles are contained in interchangeable pods. Each pod contains six standard rockets or one guided ATACMS missile; the two types cannot be mixed. The LLM can hold two pods at a time, which are hand-loaded using an integrated winch system. All twelve rockets or two ATACMS missiles can be fired in under a minute. One launcher firing twelve rockets can completely blanket one square kilometer with submunitions. For this reason, the MLRS is sometimes referred to as the "Grid Square Removal System" (metric maps are usually divided up into 1 km grids).[6] A typical MLRS cluster salvo consisted of three M270 vehicles each firing all 12 rockets. With each rocket containing 644 M77 grenades, the entire salvo would drop 23,184 grenades in the target area. However, with a two percent dud rate, that would leave approximately 400 undetonated bombs scattered over the area, which would endanger friendly troops and civilians.[7]

In 2006, MLRS was upgraded to fire guided rounds. Phase I testing of a guided unitary round (XM31) was completed on an accelerated schedule in March 2006. Due to an Urgent Need Statement, the guided unitary round was quickly fielded and used in action in Iraq.[8] Lockheed Martin also received a contract to convert existing M30 DPICM GMLRS rockets to the XM31 unitary variant.[9]

The M31 GMLRS Unitary rocket transformed the M270 into a point target artillery system for the first time. Due to GPS guidance and a single 200 lb (91 kg) high-explosive warhead, the M31 could hit targets accurately with less chance of collateral damage while needing fewer rockets to be fired, reducing logistical requirements. The unitary warhead also made the MLRS able to be used in urban environments. The M31 had a dual-mode fuse with point detonation and delay options to defeat soft targets and lightly fortified bunkers respectively, with the upgraded M31A1 equipped with a multi-mode fuse adding a proximity airburst mode for use against personnel in the open; proximity mode can be set for 3 or 10 metres (9.8 or 32.8 ft) height of burst (HOB). The GMLRS has a minimum engagement range of 15 km (9.3 mi) and can hit a target out to 70 km (43 mi), impacting at a speed of Mach 2.5.[10][11]

A German developmental artillery system, called the Artillery Gun Module, has used the MLRS chassis on its developmental vehicles.[12]

In 2012, a contract was issued to improve the armor of the M270s and improve the fire control to the standards of the HIMARS.[13] In June 2015, the M270A1 conducted tests of firing rockets after upgrades from the Improved Armored Cab project, which provides the vehicle with an enhanced armored cab and windows.[14]

Service history

The M270 MLRS conducts a rocket launch.

When first deployed with the U.S. Army, the MLRS was used in a composite battalion consisting of two batteries of traditional artillery (howitzers) and one battery of MLRS SPLLs (self-propelled loader/launchers). The first operational organic or "all MLRS" unit was 6th Battalion, 27th Field Artillery.[15]

The 6th Battalion, 27th Field Artillery was reactivated as the Army's first Multiple Launch Rocket System (MLRS) battalion on 1 October 1984, and became known as the "Proud Rockets". In March 1990, the unit deployed to White Sands Missile Range, New Mexico to conduct the Initial Operational Test and Evaluation of the Army Tactical Missile System. The success of the test provided the Army with a highly accurate, long range fire support asset.

On 2 September 1990, the 6th Battalion, 27th Field Artillery deployed to Saudi Arabia in support of Operation Desert Shield. Assigned to the XVIII Airborne Corps Artillery, the unit played a critical role in the early defense of Saudi Arabia. As Desert Shield turned into Desert Storm, the Battalion was the first U.S. Field Artillery unit to fire into Kuwait. Over the course of the war, the 6th Battalion, 27th Field Artillery provided timely and accurate rocket and missile fires for both U.S. corps in the theater, the 82nd Airborne Division, the 6th French Light Armored Division, the 1st Armored, 1st Infantry Division, the 101st Airborne Division, and the 24th Infantry Division (Mechanized).

A Battery 92nd Field Artillery (MLRS) was deployed to the Gulf War in 1990 from Ft.Hood Texas. 3/27th FA (MLRS) out of Fort Bragg deployed in support of Operation Desert Shield in August 1990. A/21st Field Artillery (MLRS) – 1st Cavalry Division Artillery deployed in support of Operation Desert Shield in September 1990. In December 1990, A-40th Field Artillery (MLRS) – 3rd Armored Division Artillery (Hanau), 1/27th FA (MLRS) part of the 41st Field Artillery Brigade (Babenhausen) and 4/27th FA (MLRS) (Wertheim) deployed in support of Operation Desert Shield from their bases in Germany and 1/158th Field Artillery from the Oklahoma Army National Guard deployed in January 1991.

MLRS-System with launch vehicle, loader and a command center inside an M113-APC

In early February 1991, 1/27th FA launched the biggest MLRS night fire mission in history.[16] It has since been used in numerous military engagements, including the 2003 invasion of Iraq. In March 2007, the British Ministry of Defence decided to send a troop of MLRS to support ongoing operations in Afghanistan's southern province of Helmand; they will use newly developed guided munitions.

In April 2011, the first modernized MLRS II and M31 GMLRS rocket were handed over to the German Army's Artillery School in Idar Oberstein. The German Army operates the M31 rocket up to a range of 90 km.[17]

Versions

Two British M270 MLRS in 2008 in Camp Bastion, Afghanistan
British M270 firing at Otterburn Training Area in 2015
A MARS (MLRS) of the German Army

MLRS rockets and missiles

"Steel Rain" - M77 DPICM submunition of type used by MLRS M26 rocket. 644 M77s per rocket. The M77 was developed from the M483A1 that was developed for artillery shells.

The M270 system can fire MLRS Family Of Munition (MFOM) rockets and artillery missiles, which are manufactured and used by a number of platforms and countries. These include:

Foreign rockets

Selected rocket specifications

Name Weight Range (max) Guidance Warhead
M26 306 kg (675 lb) 32 km (20 mi) 644 M77 DPICM submunitions
M26A1/A2 296 kg (650 lb) over 45 km (28 mi) M26A1: 518 M85 DPICM submunitions
M26A2: 518 M77 DPICM submunitions
M30/M31 84 km (52 mi)[21] GPS/INS M30: 404 M85 DPICM submunitions
M31: 90 kg (200 lb) unitary HE
AT2 SCATMIN 254 kg (561 lb) 39 km (24 mi)
PARS SAGE-227 F over 300 kg/160 kg 70 km (43 mi)

Alternative Warhead Program

In April 2012, Lockheed Martin received a $79.4 million contract to develop a GMLRS incorporating an Alliant Techsystems-designed alternative warhead to replace DPICM cluster warheads. The AW version is designed as a drop-in replacement with little modification needed to existing rockets. An Engineering and Manufacturing Development (EMD) program was to last 36 months, with the alternative warhead GMLRS expected to enter service in late 2016.[22] The AW warhead is a large airburst fragmentation warhead that explodes 30 ft (9.1 m) over a target area to disperse penetrating projectiles. Considerable damage is caused to a large area while leaving behind only solid metal penetrators and inert rocket fragments[23] from a 90 kg (200 lb) warhead containing approximately 160,000 preformed tungsten fragments.[24]

On 22 May 2013, Lockheed and ATK test fired a GMLRS rocket with a new cluster munition warhead developed under the Alternative Warhead Program (AWP), aimed at producing a drop-in replacement for DPICM bomblets in M30 guided rockets. It was fired by an M142 HIMARS and traveled 35 km (22 mi) before detonating. The AWP warhead will have equal or greater effect against materiel and personnel targets, while leaving no unexploded ordnance behind.[25]

On 23 October 2013, Lockheed conducted the third and final engineering development test flight of the GMLRS alternative warhead. Three rockets were fired from 17 kilometres (11 mi) away and destroyed their ground targets. The Alternative Warhead Program then moved to production qualification testing.[26] The fifth and final Production Qualification Test (PQT) for the AW GMLRS was conducted in April 2014, firing four rockets from a HIMARS at targets 65 kilometres (40 mi) away.[27]

On 28 July 2014, Lockheed successfully completed all Developmental Test/Operational Test (DT/OT) flight tests for the AW GMLRS. They were the first tests conducted with soldiers operating the fire control system, firing rockets at mid and long-range from a HIMARS. The Initial Operational Test and Evaluation (IOT&E) exercise was to be conducted in fall 2014.[28]

On 15 September 2015, Lockheed received a contract for Lot 10 production of the GMLRS unitary rocket, which includes the first order for AW production.[29]

M993 Launcher specifications

An Israeli upgraded version of the M270 MLRS used by the Israel Defense Forces Artillery Corps

Operators

Map of M270 operators in blue with former operators in red

Current operators

Former operators

Nicknames

US military operators refer to the M270 as "the commander's personal shotgun" or as "battlefield buckshot". It is also commonly referred to as the "Gypsy Wagon", because crews store additional equipment, such as camouflage netting, cots, coolers, and personal items, on top of the vehicle as the launcher itself lacks adequate storage space for the crew. Within the British military, a common nickname is "Grid Square Removal System", a play on the initialism GSRS (from the older General Support Rocket System). With the adoption of the new M30 GPS guided rocket, it is now being referred to as the "70 kilometer sniper rifle".[40] During the 1991 Gulf War, the Iraqis referred to the small M77 submunitions rockets as the "Steel Rain".

See also

References

  1. https://www.youtube.com/watch?v=SjzvNo7bmt0
  2. Lockheed Martin receives MLRS follow-on order - Shephardmedia.com, 20 July 2012
  3. Additional GMLRS rockets ordered by US Army from Lockheed - Army-Technology.com, 4 February 2013
  4. 1 2 John Pike. "M270 Multiple Launch Rocket System - MLRS". Globalsecurity.org. Retrieved 2013-10-23.
  5. "M270 Multiple Launch Rocket System - MLRS". Fas.org. Retrieved 2013-10-23.
  6. Ben Rooney, "Tank-busting helicopters ready for action", Daily Telegraph, April 21, 1999.
  7. After Cluster Bombs: Raining Nails - Wired.com, 30 May 2008
  8. "Guided MLRS Unitary Rocket Successfully Tested", Microwave Journal, Vol. 49, No. 3 (March 2006), page 39.
  9. "Lockheed Gets $16.6M to Convert MLRS Rockets, Asked to Speed Up GMLRS Production (updated)". Defense Industry Daily. August 2, 2006. Retrieved 2013-10-23.
  10. M31 GMLRS Unitary - Globalsecurity.org
  11. Precision Fires Rocket & Missile Systems - MSL.Army.mil
  12. "Defense & Security Intelligence & Analysis: IHS Jane's | IHS". Janes.com. Retrieved 2013-10-23.
  13. "USA Moves to Update Its M270 Rocket Launchers". Defenseindustrydaily.com. 2012-07-01. Retrieved 2013-10-23.
  14. Improved Multiple Launch Rocket System tested at White Sands Missile Range - Army.mil, 31 July 2015
  15. "History for 6th Battalion, 27th Field Artillery (1960s to Present)". Military.com. Retrieved 2013-10-23.
  16. "C-1/27th FA MLRS". YouTube. 2009-11-26. Retrieved 2013-10-23.
  17. "Rollout MARS II und GMLRS Unitary" (in German). Bwb.org. 2012-07-26. Retrieved 2012-08-06.
  18. http://www.lockheedmartin.com/us/products/GuidedUnitaryMLRSRocket.html
  19. http://www.dsca.mil/major-arms-sales/finland-guided-multiple-launch-rocket-system-gmlrs-m31a1-unitary-and-gmlrs-m30a1
  20. Israel's new guided missiles system Romah will soon be operational - Armyrecognition.com, 15 January 2016
  21. (French) Fabrice Fayet, Détachement de Liaison, Observation et Coordination, p. 15, Joint Centre of concepts, doctrines and experiments, French army, 8 june 2015
  22. GMLRS to Get a New Warhead - Defense-Update.com, 24 April 2012
  23. Army tests safer warhead - Armytechnology.Armylive.DoDlive.mil, 2 September 2014
  24. Guided Multiple Launch Rocket System (GMLRS) Alternative Warhead (GMLRS-AW) XM30A1 - Office of the Director, Operational Test & Evaluation. 2014
  25. "US Army searches for cluster munitions alternatives". Dmilt.com. Retrieved 2013-10-23.
  26. Alternative GMLRS Warhead Completes Third Successful Fight Test - Deagel.com, 23 October 2013
  27. Lockheed Martin GMLRS Alternative Warhead Logs Successful Flight-Test Series, Shifts To Next Testing Phase - Lockheed news release, 16 April 2014
  28. Lockheed Martin Completes Successful Operational Flight Tests of GMLRS Alternative Warhead - Deagel.com, 28 July 2014
  29. Lockheed Martin GMLRS Alternative Warhead Gets First Order - Marketwatch.com, 15 September 2015
  30. Archived March 9, 2008, at the Wayback Machine.
  31. Archived August 23, 2004, at the Wayback Machine.
  32. 1 2 3 4 "Atacms". Deagel.com. Retrieved 2 June 2015.
  33. 1 2 "Lockheed Martin Receives $45.3 Million Contract to Upgrade Finland's Precision Fires Capability". PR Newswire. Lockheed Martin. 18 May 2011. Retrieved 2 June 2015.
  34. "M270 (MLRS)". Armyvehicles.dk. 2014. Retrieved 2 June 2015.
  35. 1 2 "La DGA commande 13 Lance-roquettes unitaires (LRU)". Defense.gouv.fr. Direction générale de l'armement. 7 Oct 2011. Retrieved 2 June 2015.
  36. 1 2 3 "Sagem's Sigma 30 navigation and pointing system chosen to modernize M270 Multiple Launch Rocket Systems for three European armies". Safran. Sagem. 18 Jan 2012. Retrieved 2 June 2015.
  37. 1 2 "MLRS Improved". Krauss-Maffei Wegmann. Retrieved 2 June 2015.
  38. "GMLRS" (PDF). Lockheed Martin. Retrieved 2 June 2015.
  39. 1 2 3 4 "MLRS® M270 Series Launchers" (PDF). Lockheed Martin. Retrieved 2 June 2015.
  40. Archived December 23, 2009, at the Wayback Machine.

External links

Wikimedia Commons has media related to Multiple Launch Rocket System.
This article is issued from Wikipedia - version of the Sunday, May 01, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.