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LRAC F1

The LRAC F1, officially designated as the Lance-Roquettes AntiChar de 89 mm modèle F1, is a lightweight, reusable 89 mm anti-tank developed in , beginning in 1964, to replace the aging M20A1 Super Bazooka. Developed by the Société Technique de Recherches Industrielles et Mécaniques (STRIM) in cooperation with Luchaire Défense SA and the Manufacture Nationale d'Armes de , the LRAC F1 entered service with the in 1972 as the standard portable anti-armor weapon for units. It was selected over competing designs like the 80 mm LCD-APX due to its superior armor penetration and lower production costs, featuring a and construction that reduced its weight to approximately 5 kg—over 2 kg lighter than its predecessor. The launcher measures 1.17 m in length (collapsed) and fires 89 mm rockets, including (HEAT) warheads capable of penetrating up to 400 mm of rolled homogeneous armor (RHA) at 0° obliquity, with an effective range of 500 m against stationary targets (300 m for moving ones) and a maximum range of 2,300 m. Additional ammunition types include multi-purpose, smoke, and illumination rounds, supporting a of 3-4 rounds per minute, while the reusable tube has a service life of up to 100 shots. The LRAC F1 was marketed internationally by Hotchkiss-Brandt (later part of GIAT Industries) and saw export to allies such as , with limited use reported in some former French colonies in Africa as of the . It equipped French forces through the end of the but was phased out in French service during the in favor of more advanced systems like the CS disposable launcher and the Eryx due to evolving armored threats. The weapon's simple design, including the APX M309 optical sight (with optional passive ), emphasized portability for a single operator, often assisted by a loader, making it a key tool in anti-tank tactics during its era.

Development and production

Background and requirements

Following , the sought a modern, lightweight, man-portable anti-tank weapon to replace the American M20A1 Super Bazooka, which weighed approximately 6.5 kg unloaded and had an effective range limited to about 300 meters against armored targets. This need arose amid the escalating tensions in , where French infantry required enhanced mobility and firepower to counter the growing threat of Soviet armored formations, emphasizing portable systems that could be carried and operated by a single soldier without compromising tactical flexibility. The initial requirements specified a reusable launcher weighing under 5.5 kg, an 89 mm caliber for improved armor penetration over earlier systems like the 73 mm LRAC, and an effective range of at least 300 meters. The shaped-charge was designed to penetrate at least 400 mm of rolled homogeneous armor, addressing the limitations of post-war anti-tank munitions against increasingly thicker Soviet plating. These specifications prioritized portability while ensuring sufficient lethality, with the launcher's construction contributing to the reduced weight target. In the evaluation process, the 89 mm LRAC design was selected over the competing 80 mm ACL-APX recoilless rifle, which used rocket-assisted projectiles but proved more expensive to produce and offered marginally less penetration efficiency against contemporary armor. The choice of 89 mm caliber balanced improved armor defeat capabilities with cost-effectiveness, making it suitable for widespread infantry deployment in NATO-aligned forces. Development began in 1964 under the French Ministry of Defence, with research led by the STRIM technical institute, leading to the weapon's adoption in the 1970s.

Design process

The development of the LRAC F1 was initiated in 1964 when the Société technique de recherches en industries mécaniques (STRIM) received a contract from the French Ministry of Defence to research and develop a lightweight anti-tank as a replacement for the aging M20A1 Super Bazooka. This effort aimed to address the need for a portable, effective capable of engaging armored threats. A key innovation in the design was the adoption of fiberglass and plastic composites for the launch tube , which reduced the overall weight to 5 kg—approximately 1.5 kg lighter than the Super Bazooka—while ensuring sufficient durability for repeated use. The launcher featured an aluminum bore liner within the composite tube to withstand the stresses of firing, and it was engineered for reusability, with a of up to 100 shots per tube. These choices prioritized for a single operator without compromising structural integrity. In the early , the conducted comparative trials between the STRIM's 89 mm LRAC F1 and the competing 80 mm ACL-APX design. Testing against armor plates confirmed the LRAC F1's shaped-charge warhead could penetrate 400 mm of rolled homogeneous armor (RHA), establishing its effectiveness against contemporary tanks. The system achieved a of 295 m/s, contributing to its flat trajectory and accuracy up to 500 m. The LRAC F1 was ultimately selected over the ACL-APX due to its superior penetration performance, higher velocity, reusability, and lower production costs, marking the culmination of iterative prototyping to refine stability and backblast safety protocols. Following these successful evaluations, the weapon entered service in the mid-1970s.

Manufacturers and production history

The LRAC F1 launcher was primarily manufactured by the Manufacture Nationale d'Armes de , France's national arms factory, while the rockets and were produced by Luchaire Défense SA. The Société technique de recherches en industries mécaniques (STRIM) contributed significantly to the initial development and early production phases through its expertise in mechanical and prototyping. These entities collaborated closely under government contracts to meet military specifications for a lightweight, reusable anti-tank system. Production of the LRAC F1 commenced in the early following its selection over competing designs like the 80 mm ACL-APX recoilless rifle, with initial output focused on equipping and units to replace aging M20A1 Super Bazooka stocks. Manufacturing peaked during the to fulfill domestic demands and international orders, leveraging the launcher's durable construction for cost-effective scalability. By the late , production began to wind down as advancements in guided anti-tank missiles reduced the need for unguided rocket systems, leading to full cessation in the early 1990s. The LRAC F1 saw extensive export production, distributed to over a dozen nations with historical ties to France, particularly in , including , , , , , , , , , , , , , , , , and . These exports supported local defense needs in post-colonial contexts, though exact production volumes remain classified and are estimated in the tens of thousands of units combined for launchers and rockets. Licensed manufacturing was limited, with no widespread foreign production lines established beyond French oversight.

Design and specifications

Launcher construction

The LRAC F1 launcher features a lightweight construction centered around a fiberglass-reinforced plastic tube, which provides structural strength while enabling reusability for up to 100 shots per unit. This tube incorporates a metal firing and sights for enhanced precision and longevity, with the overall measuring 89 mm. The launcher's dimensions include a length of 1.17 m and an empty weight of 5 kg, facilitating easy transport by . Key components of the launcher include the APX M309 optical sight calibrated for ranging targets up to 500 m, a for stable handling, an adjustable shoulder stock to accommodate the firer, and a that directs backblast safely rearward. These elements are integrated into the framework, with metal reinforcements where necessary to withstand operational stresses. Ergonomically, the design supports one-man carry through foldable and compact features, yet it is optimized for two-person firing teams to enable efficient positioning and support during engagement. The quick-assembly configuration allows for straightforward rocket integration without complex tools, prioritizing mobility in combat scenarios. The launcher's durability is tailored for rugged field conditions, resisting environmental wear while limiting sustained fire to 3-4 rounds per minute to manage buildup in the tube. This balance ensures reliability across multiple uses without risking structural failure.

Ammunition and rocket

The LRAC F1 is designed to fire 89 mm rockets housed in disposable transport and launch containers that insert directly into the reusable launch tube. These rockets feature a (HEAT) shaped-charge as the standard munition, optimized for penetrating armored vehicles. The employs a metallic liner to form a focused upon , capable of defeating up to 400 mm of rolled homogeneous armor (RHA) at 0° obliquity. The itself weighs 2.2 kg and utilizes a solid-fuel motor for , which fully combusts within the launch to minimize backblast hazards. This configuration imparts a of 295 m/s (967 ft/s) to the . The motor's design ensures reliable ignition and acceleration in a closed-breech , enhancing during firing. While the primary variant in service was limited to the round for anti-armor roles, additional types such as multi-purpose (with fragmentation effects), , and illumination were developed and made available, particularly for markets. These variants maintain with the standard container packaging, which seals the for transport and storage. No dedicated practice rounds were issued in standard configurations.

Performance characteristics

The LRAC F1 demonstrates effective engagement s of 300 to 500 meters against point and area targets, respectively, with a theoretical maximum of 2,300 meters for uncontrolled flight. This performance positions it as a short-to-medium-range anti-armor suitable for support in defensive or scenarios, though the unguided nature limits precision at extended distances. Penetration capabilities are provided by its high-explosive anti-tank (HEAT) , which can defeat more than 400 mm of rolled homogeneous armor (RHA) at perpendicular impact or up to 1 meter of , making it viable against light armored vehicles, bunkers, and fortifications. However, effectiveness diminishes against modern main battle tanks equipped with composite armors, ceramics, or reactive armor, as the 's lack of guidance and standoff defeat mechanisms renders it vulnerable to countermeasures. The is constrained to 3-4 rounds per minute, primarily due to the 15-20 second reload time required for inserting a new canister into the reusable tube. Accuracy is supported by the integrated 3x APX M309 optical sight, which includes range estimation markings from 100 to 1,000 meters and lead adjustments for moving targets at speeds up to 30 km/h, achieving a typical dispersion suitable for static targets within 300 meters; an optional passive night sight extends low-light utility. A critical operational limitation is the backblast danger zone extending approximately 10 meters to the rear, necessitating a clear firing position to avoid injury to nearby personnel or equipment.

Operation

Crew roles and procedures

The LRAC F1 is operated by a standard two-person crew consisting of a , who is responsible for aiming and firing the , and a loader or assistant, who carries additional rockets and handles reloading during sustained engagements. To maintain mobility in operations, the typically carries the empty launcher, which weighs 5.5 kg including the sight, while the assistant transports 2 to 3 rockets in their sealed containers, each weighing 3.2 kg, resulting in a total crew load of under 15 kg. Training for LRAC F1 crews emphasizes basic skills, with focused instruction on backblast hazards to ensure clear firing zones and precise sight alignment for effective target engagement. The setup procedure is straightforward and requires no complex arming steps: the extends the flip-up , the assistant inserts a container into the rear breech, and the then shoulders the launcher to acquire the target. In doctrine, LRAC F1 teams were integrated into platoons as platoon-level assets to provide close-range anti-tank defense.

Firing

The LRAC F1 employs a rear-loading for its 89 mm , which is housed in a disposable and launch container. To load, the assistant inserts the rocket module into the rear breech of the launch tube, decaps the forward end, pushes it forward until seated, and rotates it clockwise to engage locking lugs, thereby completing part of the electrical firing circuit. The assistant then removes the moisture-proof back cap from the module to finalize the circuit connection. Aiming is facilitated by the detachable APX M290 optical sight, mounted above the pistol grip and offering 3x magnification with adjustable range lines calibrated for targets from 100 to 1,000 meters, though optimal use is between 300 and 500 meters for anti-tank engagements. The sight includes lead marks for moving targets at speeds of 10 to 30 km/h. Elevation and traverse adjustments are performed manually by the operator. Backup provide a fixed 300-meter zero for emergency use. Firing is initiated electrically via a battery-powered . The operator squeezes the to close the initial , then pulls the to activate the , igniting the rocket's and launching it from the tube at a of 295 m/s. The assistant gunner must confirm a clear behind the launcher before firing to avoid injury from exhaust gases and . The rocket motor burns out within the tube, minimizing . Reloading involves removing the spent launch container from the rear breech after firing, then inserting a new module following the same loading steps. The supports a maximum of 3 to 4 rounds per minute, corresponding to a cycle time of approximately 15 to 20 seconds per shot with a trained .

Safety and maintenance

The LRAC F1 requires strict safety measures to mitigate risks associated with its backblast and firing process. A mandatory 10 m clear rear zone must be established behind the launcher to protect personnel and equipment from the high-velocity exhaust gases and generated upon firing. Firing from enclosed spaces is prohibited to prevent dangerous pressure buildup and potential structural failure or injury to the crew. The is armed only after complete loading into the , ensuring it remains inert during handling and transport. Field maintenance for the LRAC F1 focuses on preserving the reusability of the tube and associated components. The tube must be cleaned after firings using appropriate solvents to remove residue, which can otherwise accumulate and lead to firing malfunctions. Sights and the are inspected periodically for , , and charge levels to maintain accuracy and reliability during operations. Storage protocols emphasize environmental protection to extend component longevity. The launcher is stored in dry, temperature-controlled conditions to avoid degradation of the structure and electrical contacts, while rockets are kept in sealed, moisture-proof containers positioned away from heat sources or ignition risks. The itself is rated for up to 100 firings before requiring replacement. Common issues with the LRAC F1 primarily involve residue buildup in the , which can cause misfires or incomplete ignition; this is effectively resolved through routine solvent wipes during cleaning. No major recalls or systemic defects have been recorded for the in military service. Crew training underscores the importance of safety compliance. These sessions reinforce protocols briefly referencing reloading steps from operational procedures, ensuring crews maintain proficiency without risking accidents.

Operational history

French military service

The LRAC F1 entered service with the in the 1970s as a standard-issue light anti-tank weapon for and units, replacing the aging M20A1 Super Bazooka. This adoption marked a shift toward lighter, more portable shoulder-fired systems suitable for rapid deployment in diverse terrains. It saw early combat use by French paratroopers in the in in 1978. During the 1980s, the LRAC F1 became a mainstay in ground forces, equipping frontline units for anti-armor engagements and general support roles. It saw deployment during the intervention in in 1982–1983 as part of multinational efforts, though often misidentified in reports as the missile. The weapon was also employed by troops in in 1986 and the 1991 , where it provided light anti-armor capability against Iraqi vehicles during ground operations in Operation Daguet. In service, the LRAC F1 was praised for its portability and ease of use by individual soldiers or small teams, enabling quick setup in maneuvers. However, it faced criticism for its unguided nature, which limited effectiveness against advanced armored threats like tanks, and its visible smoke trail that exposed firers to counterfire. regimens focused on direct-fire tactics in both urban and open environments to mitigate these limitations. The LRAC F1 began to be gradually phased out from active French Army units starting in the 1990s and 2000s, supplanted by guided systems like the Eryx missile for precision anti-tank roles and the AT4 for disposable launchers, with limited use continuing into the 2010s including Operation Serval in Mali in 2013. Replacement continued gradually, with the French Foreign Legion retiring it in the late 2010s in favor of the AT4 CS.

Export users and conflicts

The LRAC F1 was exported to numerous countries, particularly those with historical ties to France, including , , , , , , , , , , , , , , , , , , and (now ). These sales occurred primarily during the 1970s and 1980s, with the weapon adopted by infantry and units for anti-tank roles. In , the integrated the LRAC F1 into its arsenal, with evidence of continued training use by as late as 2016. Indonesia's , including and , employed the launcher for its portability in counter-insurgency operations, such as in . African operators such as the armed forces of , , and maintained it as a lightweight shoulder-fired option suitable for their security needs. The LRAC F1 proved battle-tested in international service, demonstrating effectiveness against light armored vehicles in asymmetric engagements by users. While specific combat instances are limited in public records, its deployment by forces in regional operations highlighted its utility in rugged terrains. In , it saw use in conflicts such as the , , and various low-intensity border security operations. Many export nations retain limited reserve stocks today, with no ongoing production; it was also supplied to forces in 2016.

Replacement and legacy

Successor systems

The began transitioning away from the LRAC F1 in the with the adoption of the (Anti-Personnel Infantry Light Atomic System) 112 mm as an interim solution, selected in 1984 for its superior armor penetration capabilities against emerging threats like composite armor. This reusable system addressed the LRAC F1's limitations in penetrating modern tank armor while serving as a bridge to more advanced weapons. By the mid-1980s, the disposable 84 mm AT4 entered French service for light anti-armor roles, offering simplicity and reduced logistical demands compared to the maintenance-intensive reusable LRAC F1. The AT4's single-use design eliminated the need for reloading and cleaning, making it ideal for infantry units, though initial variants were later upgraded to the confined-space (CS) model in the 1990s for indoor firing capability. Concurrently, the Eryx wire-guided anti-tank missile was developed in the late 1970s specifically to replace the LRAC F1's short-range unguided role, entering service in 1994 with a 600 m effective range and improved guidance for engaging moving targets. These successors provided enhanced lethality—Eryx with precision wire-guided SACLOS options and AT4 with reliable penetration up to 400 mm of rolled homogeneous armor—over the LRAC F1's unguided 400 mm penetration, while reducing operator training and sustainment burdens. The transition culminated in the phased withdrawal of the LRAC F1 by the late 1990s, with AT4 CS and Eryx fully integrating into infantry sections for complementary roles: AT4 for rapid, close-range engagements and Eryx for deliberate anti-tank strikes. Among export users, parallels emerged as Greece, a former LRAC F1 operator, shifted to Rafael's Spike missile family in 2023 for multi-role guided anti-armor capabilities up to 2.5 km. In contrast, many African nations, including Benin, Burkina Faso, and Chad, retained the LRAC F1 into the 21st century due to its low cost and availability of surplus ammunition, avoiding the expense of guided systems. The LRAC F1's lightweight, shoulder-fired design influenced subsequent portable launchers, notably the Yugoslav 90 mm developed in the , which adopted similar construction and sighting mechanics for enhanced portability and accuracy in use.

Current status and evaluations

The LRAC F1 has been fully retired from active service in the , with replacement by the AT4-CS and Eryx systems beginning in the and completing by the late . Globally, residual stocks remain in use for training or reserves in over ten countries, primarily former French colonies in and allies such as , with no new production or procurements reported since the . Modern evaluations assess the LRAC F1 as effective against armored threats typical of the , such as lightly protected vehicles, but inadequate for contemporary main battle tanks equipped with explosive reactive armor (), due to its () warhead's penetration limited to approximately 400 mm of rolled homogeneous armor (RHA). It retains value in low-intensity conflicts for its relatively low cost and simplicity, making it suitable for irregular forces or resource-constrained militaries. Since 2016, no major conflicts involving the LRAC F1 have been documented, though occasional reports note its presence in surplus markets and among insurgents, including in regions like where have employed it. The system's strengths, including high portability at around 5 when loaded and reusability of the fiberglass launcher, continue to be highlighted in historical analyses, contrasted with weaknesses such as its unguided ballistic trajectory and insufficient penetration against modern defenses. In 2024, the announced plans to replace the Eryx with the Swedish (Next generation Light Anti-tank Weapon) by 2025-2026, further evolving the anti-tank capabilities that succeeded the LRAC F1. Examples of the LRAC F1 are preserved for archival and educational purposes in various military museums, underscoring its role in Cold War-era infantry anti-tank doctrine.

References

  1. [1]
    LRAC 89 [Lance Roquette Antichar 89mm] - GlobalSecurity.org
    Mar 9, 2013 · The LRAC F1, officially called anti-tank rocket launchers of 89 mm model F1, is a reusable rocket launcher which served in the French army.
  2. [2]
    LRAC - Weaponsystems.net
    The LRAC is a Cold War era rocket launcher of French origin. It was developed in the late 1960's to replace the M20 Super Bazooka.
  3. [3]
    LRAC 89-F1 (Lance-Roquettes AntiChar de 89mm modele F1)
    The LRAC 89-F1 was developed for the French Army to replace the aging M20A1 Super Bazooka rocket launcher. The M20A1 was an improved form of the World War ...
  4. [4]
    M20 Super Bazooka - Weaponsystems.net
    The maximum effective range is 150 meters. A rate of fire of 6 rounds per minute can be achieved. Users. The primary user of the M20 was the USA. Many ...
  5. [5]
    LRAC F1: 89MM SHOULDER FIRED LAUNCHER
    Feb 1, 2010 · The basic LRAC rocket is High Explosive Anti-Tank using a shaped charge that will penetrate more than 400mm (15.75 inches) of Rolled Homogenous ...
  6. [6]
    LRAC F1 - Guns in Movies, TV and Video Games
    The launcher's basic sight is the APX M309, a simple 3x telescope with a ranging ladder reticle marked in 100m increments out to 1,000m, but it can also mount ...
  7. [7]
    89mm lrac rocket - CAT-UXO
    The launch container with rocket weighs 3.2kg (7.1lbs). The rocket alone weighs 2.2kg (4.9lbs) before firing and 1.9kg (4.2lbs) after firing.Missing: F1 weight
  8. [8]
    LRAC F1 | Gun Wiki - Fandom
    The LRAC F1 is a French reloadable infantry rocket launcher, an anti-tank rocket launcher, using encased rockets with a reloadable launch unit.
  9. [9]
    Resurrected Weapons: LRAC F1 - The Soapbox
    Sep 24, 2016 · The LRAC F1 is a reusable 89mm rocket launcher. The tube is mostly fiberglass, which keeps the weight down. It's a 1970s-vintage design, but the ...
  10. [10]
    Infantry Platoon (TFR702) - WWIII: Team Yankee
    Jul 26, 2023 · The unit is also armed with a pair of short range anti-tank weapons, usually the 89mm LRAC (Lance-Roquettes AntiChar de 89 mm modèle F1) ...Missing: doctrine | Show results with:doctrine
  11. [11]
    [PDF] Lance roquette antichar de 89 mm Mle F1 (1975).
    Notice technique d'emploi du LRAC 89 Mle F1 et du TR: MAT 1114. Guide technique du LRAC 89 Mic F1: MAT 1050. Manuel de réparation du LRAC 89 Mle F1: MAT 1169.
  12. [12]
    French Foreign Legion Equipment
    The French Army received the first AT4 in the mid-1980s. In the Foreign Legion, the upgraded CS version finally replaced the older 89 mm LRAC anti-tank gun (in ...Missing: background | Show results with:background
  13. [13]
    File:LRAC Lebanon.jpg - Wikimedia Commons
    Aug 19, 2024 · French troops and US Marines have been deployed in Lebanon as part of a multi-national peacekeeping force following confrontation between ...
  14. [14]
    LRAC F1 - laststandonzombieisland
    Feb 28, 2025 · The LRAC F1 is a French 89mm rocket launcher, capable of penetrating 400mm of armor, used by the French Foreign Legion in Iraq. It was ...Missing: trials plates RHA
  15. [15]
    [PDF] French Orders of Battle & TO&Es 1980-1989 v2.2
    (b) There is some suggestion that 1st French Army might have become a new SOUTHAG in wartime; controlling operations in the Austrian and Czech border regions.
  16. [16]
    File:LracF1greeksfsea.jpg - Wikimedia Commons
    English: Greek special forces personnel aiming an Lrac F1 during an amphibious exercise. Date, 9 November 2016. Source, Greek army general staff.
  17. [17]
    RAC 112 APILAS - GlobalSecurity.org
    Mar 16, 2023 · In 1984, the APILAS grenade launcher was adopted by the French army, and its production was established at the MATRA Manurhin enterprise ...
  18. [18]
    [PDF] ARCHIVED REPORT APILAS - Forecast International
    In the French Army's initial 1984 procurement contract, the APILAS carried a unit price of $2,400. In 2023 U.S. dollars, the APILAS reportedly maintains a ...Missing: adoption | Show results with:adoption
  19. [19]
    French army purshases more AT4 CS weapons - Saab
    The order value is approximately USD 46 million. The order was booked in Q3 2025. Marcus Wandt landscape. 24.Missing: 1984 | Show results with:1984
  20. [20]
    ERYX French Anti-Tank Guided Missile (ATGM) - ODIN
    May 9, 2025 · It entered service in 1994. The Eryx began as a project in the late 1970s by the French Ministry of Defense to replace the short-range Luchaire ...
  21. [21]
    Eryx Anti-Armour Missile - Army Technology
    Feb 15, 2001 · The Eryx missile system has a range of 50m to 600m. Eryx can be mounted on a tripod as well as being shoulder-launched. The Eryx short-range ...
  22. [22]
    Greek naval vessels to be fitted with SPIKE missiles - Naval News
    Feb 8, 2023 · Greece will proceed with the procurement of SPIKE fire-and-forget missiles from Rafael Advanced Defense Systems to equip eight naval vessels ...
  23. [23]
    M79 Osa (Wasp) Shoulder-Fired Anti-Tank Rocket Launcher
    The rocket is of a shaped-charge warhead design which allows for penetration up to 15" of armor - giving it good performance against most combat tank armor - ...
  24. [24]
    89mm LRAC 89 F-1 Anti-Tank Rocket Launcher - Ordnance.com
    The 89mm LRAC 89 F-1 was a French Cold War anti-tank weapon with a 500m range, 400mm armor penetration, and used in conflicts across Africa, the Middle East, ...
  25. [25]
    LRAC F1 - War on West Papua
    The LRAC F1, officially called Lance-Roquettes AntiChar de 89 mm modèle F1 (89 mm anti-tank rocket launcher model F1) is a reusable rocket launcher which ...Missing: fiberglass tube