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CBU-55

The CBU-55 is a United States cluster bomb unit incorporating fuel-air explosive (FAE) submunitions designed to generate enhanced blast overpressure via aerosolized fuel dispersion and ignition, primarily for area denial and target neutralization.^[1] Developed at the Naval Air Weapons Station China Lake during the Vietnam War era, it weighs approximately 210 kg (460 lb) and employs an SUU-49/B dispenser to release three BLU-73A/B submunitions fueled by propylene oxide, which form a vapor cloud detonated to produce a large-radius shockwave depleting oxygen and causing structural collapse.^[1]^[2] A variant, the CBU-55A/B, incorporates the FMU-83/B fuze for improved deployment reliability.^[1] Tested operationally in South Vietnam around 1971–1972 for minefield breaching, the weapon demonstrated FAE efficacy but saw only one confirmed combat use on April 21, 1975, when the South Vietnamese Air Force deployed it from a C-130 Hercules at 6,098 m altitude during the Battle of Xuan Loc, inflicting approximately 250 casualties on People's Army of Vietnam infantry by igniting a propylene oxide cloud that devastated their positions.^[2] This deployment highlighted the CBU-55's potential against massed troops in confined areas, though its limited production and specialized role curtailed broader adoption amid evolving munitions doctrines.^[2] As a first-generation thermobaric system, it influenced subsequent FAE designs like the CBU-72, emphasizing volumetric explosion effects over fragmentation.^[1]^[2]

Overview

Description and Classification

The CBU-55/B is an unguided, free-fall cluster bomb unit developed by the United States Air Force in the late 1960s, consisting of a SUU-76/A dispenser that releases three BLU-73/B fuel-air explosive submunitions designed for enhanced blast effects against troop concentrations.^[3]^[2] Each submunition functions by dispersing a cloud of ethylene oxide fuel aerosol over a target area, followed by ignition after a brief delay of approximately 150 milliseconds to detonate the mixture, generating a high-pressure shock wave and thermal pulse effective for area saturation.^[4] This mechanism distinguishes it from conventional high-explosive munitions by prioritizing overpressure and oxygen-depletion effects over fragmentation, making it suitable for defoliated or open terrain engagements.^[3] Classified under U.S. military nomenclature as a Cluster Bomb Unit (CBU) within the tactical munitions category, the CBU-55/B represents an early implementation of fuel-air explosive (FAE) technology, categorized as an enhanced blast or thermobaric weapon due to its reliance on volumetric explosion principles rather than contained detonation.^[3]^[2] It is air-delivered from fixed-wing aircraft such as the A-1 Skyraider or F-4 Phantom, with deployment typically at low altitudes to ensure accurate submunition dispersal over a footprint of several hundred meters. The system's design emphasized simplicity and rapid production, with submunitions weighing around 100 pounds each, though exact total payload specifications varied slightly across variants like the CBU-55A/B.^[5]

Intended Role and Tactical Advantages

The CBU-55 was designed as an air-dropped cluster munition to deliver fuel-air explosive (FAE) submunitions against enemy personnel and light fortifications, particularly in dense jungle environments where conventional high-explosive ordnance faced limitations in coverage and penetration. Each unit dispersed three BLU-73 submunitions, which upon deployment released a vapor cloud of ethylene oxide and propylene oxide fuel, followed by ignition to produce a sustained blast wave. This mechanism was intended to deny areas to massed infantry, clear vegetation for troop movements or landing zones, and suppress forces in bunkers or trenches by exploiting the FAE's ability to generate overpressure exceeding 30 psi over a radius of up to 50 meters per submunition. Deployment to Vietnam occurred in 1970, with the system tailored for low-altitude delivery from fixed-wing aircraft to address North Vietnamese Army tactics involving concealed positions and rapid dispersal.^[6] Tactically, the CBU-55 offered advantages in area saturation and psychological impact over unitary bombs, as the clustered FAE submunitions covered approximately 1,000 square meters per unit with lethal effects from blast, heat, and oxygen displacement, causing severe pulmonary trauma and disorientation even to those under partial cover. Unlike traditional explosives reliant on fragmentation, FAE's two-phase detonation—dispersion then combustion—propagated shockwaves around corners and into defilade, making it suitable for combating tunnel networks and foliage-concealed ambushes prevalent in Southeast Asia. This enhanced blast uniformity reduced dud rates in cluttered terrain compared to spin-stabilized bomblets and minimized collateral risks to friendly forces by enabling standoff delivery, though operational use remained limited due to weather sensitivity and fuel volatility. Military analyses noted its efficacy in creating temporary vacuums that incapacitated unprotected troops, with overpressure waves rupturing eardrums and lungs at distances where conventional munitions would fragment ineffectively.^[7]

Development

Origins in Vietnam War Era

The development of the CBU-55 fuel-air explosive (FAE) cluster bomb originated in the early 1960s amid escalating U.S. involvement in Vietnam, where conventional munitions proved inadequate against North Vietnamese and Viet Cong forces concealed in dense jungle canopies, tunnel networks, and fortified positions. Traditional blast-fragmentation weapons often dispersed ineffectively in humid, vegetated terrain, failing to generate sufficient overpressure to collapse bunkers or clear landing zones. In response, the U.S. military pursued FAE technology, which disperses a fuel aerosol cloud before ignition to produce a prolonged blast wave and incendiary effect, enhancing area-denial capabilities. Early FAE research at the Naval Weapons Center began in 1962, building on prior aerosol explosive experiments to create munitions tailored for Southeast Asian combat environments.^[6] The CBU-55 specifically addressed limitations in delivery platforms prevalent in Vietnam, such as helicopters (e.g., UH-1 Hueys) and low-speed fixed-wing aircraft like the OV-10 Bronco operated by units including VAL-4 "Black Ponies." Unlike free-fall bombs suited for high-altitude jets, the CBU-55 incorporated parachute-retarded submunitions for safe release at low altitudes and speeds, minimizing risks to slow-moving platforms while ensuring dispersal over targeted areas. Developed primarily by naval ordnance experts, it featured three BLU-73/B FAE bomblets containing ethylene oxide or propylene oxide fuel, dispensed from a SUU-44/A dispenser, with initial production ramping up by the late 1960s to support close air support missions. This design reflected causal adaptations to Vietnam's tactical demands, prioritizing blast radius over precision fragmentation.^[8] By 1970, the CBU-55 entered limited operational testing and deployment, with stockage objectives set at 90-120 days' supply for allied Vietnamese forces, underscoring its role in Vietnamization efforts to equip South Vietnamese aircraft against similar threats. Production emphasized compatibility with A-1 Skyraiders and A-37 Dragonflies, approximating one-third the area coverage of B-52 strikes in jungle settings. However, its specialized nature and logistical constraints—requiring precise environmental conditions for optimal fuel dispersion—limited widespread adoption beyond experimental phases.^[9]

Testing and Initial Production

The CBU-55 fuel-air explosive cluster bomb was primarily developed and tested at the U.S. Naval Weapons Center in China Lake, California, where engineers advanced first-generation fuel-air explosive (FAE) technology from smaller-scale prototypes to operational cluster dispensers.^[10] Testing focused on the weapon's ability to generate overpressure blasts effective against entrenched positions, caves, and bunkers, leveraging the dispersion of ethylene oxide submunitions to create a combustible cloud followed by detonation.^[2] A notable field demonstration occurred on 10 March 1972, when a CBU-55 was dropped in Louisiana to assess its efficacy against underground targets, producing a visible shockwave that highlighted the FAE mechanism's potential for area denial in contested terrain.^[11] This test, conducted under controlled conditions, validated the bomb's three BLU-73A/B submunitions, each weighing approximately 100 pounds, and their deployment from the SUU-44/A dispenser.^[2] Initial production ramped up in the late 1960s to support Vietnam War requirements, with the weapon entering limited deployment by 1970 as part of efforts to equip U.S. and South Vietnamese forces with enhanced blast munitions for close air support.^[10] By early 1972, naval documentation described the CBU-55 as a mature "all-up" cluster system ready for integration with aircraft like the A-1 Skyraider, though production remained modest due to the specialized nature of FAE technology and ongoing refinements for reliability in humid, jungle environments.

Design and Technical Specifications

Components and Submunitions

The CBU-55 cluster bomb comprises a tactical munitions dispenser housing three BLU-73 series fuel-air explosive (FAE) submunitions, designed for aerial dispersal to generate enhanced blast effects over targeted areas.^[1] The primary structural component is the SUU-49/B dispenser in the CBU-55/B variant, a cylindrical aluminum alloy container approximately 2.2 meters in length and 0.72 meters in diameter, weighing about 210 kg when fully loaded, which releases the submunitions via mechanical or pyrotechnic expulsion mechanisms upon command or impact.^[1]^[12] This dispenser lacks aerodynamic control surfaces in its base configuration, limiting compatibility to helicopters and low-speed fixed-wing aircraft.^[13] The CBU-55A/B variant employs the modified SUU-49A/B dispenser, incorporating a strongback structural reinforcement and folding tailfins for stability during high-speed carriage and release from jet aircraft, enabling broader deployment options while maintaining the same submunition loadout.^[14] Both dispensers integrate fuzing systems—typically mechanical time or impact types—that initiate submunition release at predetermined altitudes or conditions, ensuring dispersion over a footprint suited to FAE characteristics rather than high-density fragmentation.^[15] Each BLU-73A/B or BLU-73/B submunition is a self-contained FAE unit weighing approximately 45-50 kg, featuring a parachute-retarded descent for stabilization and precise ground impact orientation.^[16] Internally, the BLU-73 consists of a fuel reservoir (often containing volatile liquids like propylene oxide or ethylene oxide), an explosive burster charge to aerosolize the fuel into a vapor cloud, and a secondary ignition charge to detonate the mixture, producing a sustained overpressure wave effective against soft targets, personnel, and light fortifications.^[17] A fuze with self-destruct capability activates if the submunition fails to function post-dispersal, minimizing unexploded ordnance risks compared to non-self-destructing cluster types.^[18] Unlike fragmentation-focused submunitions in other CBUs (e.g., hundreds of small bomblets), the BLU-73's design prioritizes volumetric blast coverage, with each unit's three-compartment architecture separating fuel, oxidizer precursors, and initiator components for reliable cloud formation.^[13] This configuration yields fewer but larger submunitions, optimizing for area denial in vegetated or confined spaces where traditional high-explosive munitions underperform.^[19]

Fuel-Air Explosive Mechanism

The fuel-air explosive (FAE) submunitions in the CBU-55, designated BLU-73/B, number three per cluster unit and are housed within an SUU-49/B dispenser weighing approximately 460 pounds (210 kg) total.^[1]^[20] Each BLU-73/B bomblet weighs about 100 pounds (45 kg) and incorporates a two-stage detonation sequence initiated by a proximity or impact fuze upon reaching the target area.^[16] In the initial stage, a small burster charge ruptures the casing to aerosolize a liquid fuel—typically ethylene oxide in early U.S. FAE designs from the Vietnam era—dispersing it as fine droplets or vapor particles over a ground coverage area of roughly 10 to 20 meters in diameter.^[21]^[16] This creates a fuel-rich cloud that rapidly mixes with atmospheric oxygen, forming an explosive volume rather than relying on contained chemical oxidizers as in traditional high explosives. The secondary stage involves a delayed igniter that detonates the homogenized fuel-air mixture, triggering a deflagration-to-detonation transition.^[4] This ignition propagates as a high-velocity blast wave, generating peak overpressures of 20 to 30 psi (138 to 207 kPa) near the epicenter—comparable to or exceeding conventional TNT equivalents in blast duration and impulse—while consuming surrounding oxygen and producing temperatures up to 2,500–3,000°C (4,500–5,400°F).^[7] The mechanism's reliance on ambient air for combustion extends the effective radius, allows penetration into enclosed spaces like bunkers via shock reflection, and enhances lethality through prolonged positive-phase pressure and negative-phase vacuum effects that can cause structural collapse or physiological trauma such as lung rupture.^[16]^[22] Unlike single-stage explosives, the FAE process in the BLU-73/B prioritizes volume-filling blast over fragmentation, optimizing it for soft targets in vegetated or tunnel environments encountered in Vietnam.^[23] Early testing revealed challenges with fuel dispersion reliability in varying wind and humidity conditions, prompting refinements in atomization nozzles and fuze timing to ensure consistent cloud formation and ignition.^[21] Production variants addressed storage stability issues with ethylene oxide by incorporating stabilizers, though propylene oxide later supplanted it in subsequent FAE iterations for improved shelf life.^[21]

Deployment and Delivery Systems

The CBU-55 employs the SUU-49/B tactical munitions dispenser as its primary delivery system, housing three BLU-73A/B fuel-air explosive submunitions within a 210 kg (460 lb) unguided cluster bomb configuration.^[1] This dispenser is released via standard bomb racks from helicopters or low-speed fixed-wing aircraft, limiting high-velocity deployment to avoid structural stress on the submunitions' aerosol dispersion mechanisms.^[14] Upon release, the SUU-49/B free-falls toward the target, activating a height- or time-based fuze to eject the BLU-73 submunitions, which then separate and independently disperse ethylene oxide fuel aerosols over an area before ignition.^[24] Subsequent variants, such as the CBU-55A/B, retained the three BLU-73A/B payload but incorporated minor dispenser refinements for improved low-altitude release reliability, though compatibility remained restricted to slower platforms to ensure submunition integrity during dispersal.^[1] No ground-launch or rocket-assisted delivery systems were developed for the CBU-55, emphasizing its role in aerial close air support rather than standoff munitions.^[14] The system's design prioritized tactical flexibility in contested environments, with deployment altitudes typically ranging from 300 to 1,000 feet to optimize blast overpressure against soft targets like troop concentrations.^[24]

Operational History

Use in Vietnam War

The CBU-55, a cluster bomb employing fuel-air explosive submunitions, saw its sole combat deployment during the final stages of the Vietnam War in support of South Vietnamese forces at the Battle of Xuan Loc. On April 21, 1975, as North Vietnamese Army (NVA) units advanced on the strategic town of Xuan Loc, approximately 60 miles east of Saigon, the United States provided a single CBU-55 unit to the Republic of Vietnam Air Force (RVNAF) to bolster Army of the Republic of Vietnam (ARVN) defenses against overwhelming NVA assaults.^[2]^[25] Deployed from a VNAF C-130 Hercules transport aircraft, the 750-pound CBU-55 was air-dropped targeting an NVA divisional headquarters or troop concentration near Xuan Loc, marking the first operational use of a fuel-air explosive weapon in combat.^[26]^[27] The bomb's submunitions dispersed an aerosol fuel cloud that ignited to create a high-pressure blast wave, designed to neutralize personnel in bunkers and open areas by consuming oxygen and generating overpressure effects equivalent to several tons of TNT in a localized zone.^[2] This employment contributed to inflicting heavy casualties on the attacking NVA 341st Division, forcing a temporary retreat despite their numerical superiority of over 40,000 troops against ARVN's 5,000 defenders.^[26] Post-deployment assessments indicated the CBU-55's blast effects disrupted NVA command structures and morale, though Xuan Loc ultimately fell to NVA forces on April 22 amid broader collapses in South Vietnamese lines during the Ho Chi Minh Campaign.^[25] No further uses occurred, as U.S. aid restrictions and the rapid advance of communist forces precluded additional deployments, rendering the weapon's Vietnam service a one-off tactical experiment in desperation.^[2]

Limited Post-Vietnam Applications

Following the Vietnam War's conclusion in 1975, the CBU-55 saw no documented combat deployments by U.S. forces in subsequent operations, limiting its applications primarily to training exercises, testing, and inventory maintenance.^[8] Military specifications for associated components, such as UH-1 helicopter firing panels, continued to be revised into 1976, reflecting ongoing logistical support for the munition's retention in service.^[28] The weapon remained part of U.S. stockpiles through the 1980s, alongside development of successor fuel-air explosive systems, but was supplanted by improved variants like the CBU-72 for later needs.^[6] In major post-Vietnam conflicts, including Operation Urgent Fury in Grenada (1983), Operation Just Cause in Panama (1989), and Operation Desert Storm (1991), the CBU-55 was not employed; the latter saw use of second-generation FAE clusters such as the CBU-72 instead.^[29] U.S. Marine Corps and Navy units withdrew remaining fuel-air munitions, including legacy types like the CBU-55, from operational service following Desert Storm due to evolving tactical priorities and reliability concerns.^[30] This phase-out aligned with broader shifts toward precision-guided munitions amid debates over area-effect weapons' collateral risks.^[8]

Non-US Deployments and Analogues

The CBU-55 fuel-air explosive cluster bomb was not exported to non-US allies or deployed independently by foreign militaries outside of US-supported operations during the Vietnam War era, where South Vietnamese (RVNAF) and Royal Laotian (RLAF) air forces occasionally employed US-supplied munitions under joint command structures. No declassified records or reports indicate transfers to other nations, such as Israel or Gulf states, despite broader US cluster munition aid programs to allies like Egypt involving different variants. This limited dissemination aligns with the weapon's infrequent US usage and its classification as an experimental system with reliability issues in early tests.^[31] Analogous thermobaric or fuel-air explosive systems have been developed and deployed by Russia, evolving from Soviet-era research independent of US designs like the CBU-55. The Soviet Union fielded early volumetric detonating aviation bombs (e.g., ODAB series) and ground-launched systems by the 1980s, prioritizing enhanced blast effects for urban and fortified targets over dispersed submunitions. Russia's TOS-1 "Buratino" (later TOS-1A "Solntsepek") multiple rocket launcher, introduced in 1988 with 24 thermobaric rockets per salvo, serves a comparable area-saturation role to the CBU-55's cluster dispersal, generating overpressure waves to defeat personnel and light cover in a 400-meter radius per rocket; it has seen combat in Afghanistan (1989 Soviet withdrawal), Chechnya (1999-2000), and Ukraine (2022 onward, including confirmed uses near Kharkiv on February 28, 2022).^[7]^[32]^[33] These Russian analogues differ in delivery—favoring unguided rockets or unitary aerial bombs like the ODAB-500PMV rather than air-dropped submunition clusters—but achieve similar fuel-dispersion and detonation mechanisms for prolonged blast and vacuum effects, with reported dud rates and collateral risks comparable to early FAE systems. Deployments emphasize close-support roles against dug-in forces, as in Chechnya where fuel-air bombs were used against Grozny positions on December 27, 1999, per Interfax reporting. Unlike the CBU-55's phase-out due to precision demands, Russian systems remain in active service, integrated into hybrid tactics combining thermobarics with conventional cluster munitions like 9M55K rockets.^[34]^[35]

Military Effectiveness

Combat Performance Data

The CBU-55's combat performance was marked by high lethality against personnel in its rare deployments, primarily during the final stages of the Vietnam War. Each BLU-73/B submunition generated a fuel-air detonation that created a sustained overpressure wave and oxygen-depleting fireball, effective for neutralizing soft targets in open or semi-confined spaces such as ravines or troop concentrations. In one documented use by the South Vietnamese Air Force during the Battle of Xuan Loc on April 10, 1975, a single CBU-55 strike reportedly killed approximately 250 North Vietnamese Army soldiers through asphyxiation and blast effects, underscoring the weapon's capacity for mass casualties without reliance on fragmentation.^[25] This incident exemplified the fuel-air explosive's advantages in producing uniform blast coverage over an area, with effects propagating further than standard high-explosive munitions due to the aerosol dispersion and secondary combustion phase. U.S. Navy records confirm additional limited applications, including OV-10A Bronco-delivered drops against enemy positions in 1971, though enemy casualties were often undetermined owing to operational challenges in battle damage assessment.^[36] The weapon's demonstrated efficacy against unarmored infantry led to its characterization as a breakthrough in FAE technology, influencing subsequent thermobaric designs despite scant quantitative data from broader field testing.^[2] Overall, the CBU-55's infrequent use—estimated at fewer than a dozen combat sorties—limited aggregated performance metrics, but available accounts indicate a high probability of neutralization for exposed personnel within the detonation envelope, with minimal dud rates reported in operational logs. Its effects prioritized physiological disruption over material destruction, rendering it particularly suited for anti-personnel roles in dense foliage or tunnel-adjacent environments prevalent in Vietnam.^[37]

Comparative Advantages Over Conventional Munitions

The CBU-55's deployment of BLU-73/B fuel-air explosive submunitions offers distinct advantages over conventional high-explosive (HE) bombs in generating sustained overpressure waves, which cause extensive physiological damage to personnel through lung rupture, eardrum perforation, and oxygen depletion across a broader lethal radius—typically 20-50 meters per submunition compared to the narrower fragmentation-focused kill zones of standard 500-pound HE bombs. This mechanism, involving aerosol dispersion followed by detonation, produces blast effects that are more uniform and penetrating than the rapid, localized shock of HE munitions, enabling higher casualty rates against dispersed infantry without requiring precise direct hits.^[7] In Vietnam War applications, such as the Battle of Xuan Loc in April 1975, the CBU-55B demonstrated superior area-denial capabilities against People's Army of Vietnam troop concentrations, contributing to the destruction of 37 tanks and over 5,000 enemy casualties through its ability to saturate jungle and open terrain with multiple overlapping blast zones from three submunitions, outperforming equivalent-weight HE cluster units that fragmented prematurely in foliage. Military assessments noted that the CBU-55 allowed slower platforms like the A-1 Skyraider to replicate roughly one-third of a B-52's arc-light bombing effectiveness against soft personnel targets, reducing sortie requirements and logistical demands relative to the volume of conventional bombs needed for similar suppression.^[26]^[27]^[38] Furthermore, the CBU-55's fuel-air clouds excel in confined environments like tunnels and bunkers—prevalent in Vietnam's terrain—where the pressure wave propagates through openings and consumes internal oxygen, rendering it more effective than HE bombs whose energy dissipates at barriers, thus providing a tactical edge in flushing or neutralizing hidden forces without extensive ground assault. This volumetric explosion characteristic minimizes reliance on shrapnel, prioritizing blast lethality that scales better against unarmored targets in asymmetric warfare, though it demands low-altitude delivery for optimal dispersion.^[39]^[7]

Criticisms and Controversies

Collateral Damage and Civilian Risks

The CBU-55, employing fuel-air explosive (FAE) submunitions, generates a detonable aerosol cloud that produces a prolonged blast wave with overpressures capable of rupturing lungs, eardrums, and internal organs, as well as incendiary effects from rapid oxygen consumption and heat generation exceeding 2,500°C in the fireball. These characteristics amplify collateral damage risks in areas with non-combatants, as the blast propagates through enclosures and open spaces alike, potentially affecting individuals up to several hundred meters away depending on yield and environmental factors.^[40]^[7] Fuel dispersion in FAE systems like the CBU-55's BLU-73/B submunitions can be influenced by wind, humidity, and terrain, leading to unpredictable ignition zones that may drift toward civilian concentrations, thereby challenging compliance with international humanitarian law principles of distinction and proportionality during attacks near populated or urban environments. Reports on analogous thermobaric and FAE weapons highlight elevated civilian injury patterns, including blunt trauma and asphyxiation, when used in proximity to human settlements.^[41] As a cluster munition, the CBU-55 also leaves unexploded submunitions that function as persistent hazards, with general cluster bomb failure rates documented between 5% and 40% across conflicts, resulting in post-strike civilian casualties from duds acting as improvised anti-personnel devices. Although precise dud rates for the CBU-55 remain undocumented in public military assessments, the complexity of FAE mechanisms—requiring sequential fuel dispersal, mixing, and ignition—likely contributes to higher unreliability compared to unitary explosives, exacerbating long-term risks in Vietnam-era operational areas where remnants contaminated terrain.^[42]^[43]^[19] Limited deployment records from the Vietnam War, where the CBU-55 saw infrequent use against troop concentrations, provide scant specific data on civilian incidents attributable to the weapon, but broader analyses of cluster munitions in that conflict underscore their role in generating unexploded ordnance that killed or injured civilians for decades post-war, with estimates of millions of submunitions failing to detonate across Indochina. Critics, including human rights organizations, argue that such area-effect weapons inherently heighten civilian exposure relative to precision-guided alternatives, though U.S. military evaluations contend that dispersed FAE yields can minimize total explosive equivalence compared to equivalent unitary bombs, potentially reducing structural collateral in open terrain.^[42]^[44]

International Bans and US Policy

The Convention on Cluster Munitions, adopted on May 30, 2008, in Dublin, Ireland, and entering into force on August 1, 2010, prohibits the use, production, transfer, and stockpiling of cluster munitions, including types like the CBU-55 that disperse multiple explosive submunitions.^[45]^[46] As of 2024, the treaty has 111 states parties and 12 signatories that have not ratified, representing a majority but not consensus among UN member states, with non-parties including major military powers such as the United States, Russia, China, and India.^[47] Proponents, including organizations like Human Rights Watch, argue the ban addresses humanitarian risks from unexploded ordnance, though critics of the treaty note its exclusion of key producers and users limits enforceability against threats like massed armored formations.^[48] The United States has neither signed nor ratified the Convention on Cluster Munitions, maintaining that cluster munitions provide essential capabilities for countering area threats where precision-guided unitary weapons are insufficient, as evidenced by their utility in conflicts involving dispersed or armored enemy forces.^[49]^[50] In 2008, the U.S. Department of Defense (DoD) adopted a policy restricting cluster munition use to areas where civilians are not known to be present and prioritizing munitions with failure rates below 1%, though this applied prospectively to new production rather than legacy stockpiles like the CBU-55.^[44] A 2017 DoD revision permitted use of older cluster munitions, including those with higher dud rates, if commanders determine no suitable alternatives exist, reflecting a balance between humanitarian concerns and operational needs.^[44] U.S. law, via the 2019 National Defense Authorization Act, generally prohibits transfers of cluster munitions with more than 1% failure rates, but presidents can waive this for national security reasons, as President Biden did multiple times between July 2023 and October 2024 to authorize transfers of U.S. cluster munitions to Ukraine amid its conflict with Russia.^[49]^[44] The U.S. has phased out production of most cluster munitions since 2008, focusing on improved designs, but retains stockpiles of legacy systems for potential use or deterrence, with no plans to accede to the treaty due to assessed military requirements.^[50]^[51] This stance has drawn criticism from treaty supporters for undermining the norm against cluster weapons, yet U.S. officials emphasize risk-mitigation efforts and the treaty's non-universal adherence as rationale for non-participation.^[48]^[52]

Debates on Indiscriminate Effects vs. Precision Utility

The CBU-55, as a fuel-air explosive cluster munition, embodies tensions between area-denial effectiveness against massed enemy forces and the challenges of limiting effects to combatants. U.S. military evaluations during its development highlighted its precision utility in Vietnam-era scenarios, where the BLU-73 submunitions dispersed ethylene oxide fuel aerosols over approximately 100-200 meters, generating a blast overpressure of up to 20 psi capable of incapacitating personnel through lung rupture and oxygen depletion even behind cover.^[3] This mechanism provided tactical advantages over conventional high-explosive bombs by saturating troop concentrations or bunker systems without requiring pinpoint accuracy, as the multi-phase detonation—fuel dispersion followed by ignition—propagated effects around obstacles and in open terrain.^[2] Proponents, including defense analysts, argued that such capabilities justified its role in breaking enemy assaults, with empirical tests demonstrating near-total lethality within the effective radius against unarmored targets.^[19] Critics, primarily from humanitarian and legal perspectives, have countered that the CBU-55's reliance on cluster dispersal exacerbates indiscriminate risks, as wind-influenced fuel clouds and variable ignition could extend lethal effects beyond intended zones, potentially encompassing civilians in mixed combat environments. Reports on similar fuel-air systems document failure rates of submunitions leading to incomplete burns or residual hazards, though lower than fragmentation clusters, still posing post-strike threats comparable to unexploded ordnance.^[53] International Committee of the Red Cross analyses have questioned compliance with proportionality under international humanitarian law, noting that thermobaric overpressures cause disproportionate non-discriminatory injury, such as eardrum rupture and thermal burns at distances exceeding 300 meters in open air. These concerns contributed to its restricted deployment, with only one recorded combat use in 1970, reflecting operational hesitancy amid guerrilla warfare where target discrimination proved difficult despite aerial delivery accuracy.^[54] The debate persists in broader assessments of cluster-delivered thermobarics, with U.S. Department of Defense policy retaining such munitions for scenarios where unitary precision-guided weapons falter against dispersed or concealed adversaries, asserting that empirical combat data from analogous systems affirms net military value over alternatives.^[44] Conversely, organizations like Human Rights Watch attribute higher civilian-to-combatant casualty ratios in cluster FAE engagements to inherent design flaws, citing post-Vietnam analyses showing environmental factors amplifying unintended spread, though military sources rebut this by emphasizing context-specific targeting protocols that mitigated excesses in controlled tests.^[55]^[19] This divergence underscores a core tension: while first-use data suggested utility in high-density threat neutralization, scaling to diverse theaters revealed precision limitations favoring phase-out in favor of sensor-fused alternatives.

Legacy and Obsolescence

Phase-Out and Stockpiling

The CBU-55, a specialized fuel-air explosive cluster bomb, received limited funding of $9.3 million in the U.S. fiscal year 1973 ordnance appropriation, reflecting modest production volumes compared to other cluster munitions amid a total budget of $666.3 million for such systems.^[56] Its single documented combat use on April 21, 1975, during the defense of Xuân Lộc in South Vietnam, marked the end of operational deployment, with no subsequent production or fielding reported. This scarcity of application, coupled with the U.S. military's post-Vietnam emphasis on precision-guided and sensor-fuzed alternatives, rendered the weapon obsolete by the late 20th century. By 2004, the CBU-55B variant—featuring three BLU-73/B fuel-air submunitions—was not included in the U.S. Department of Defense's comprehensive cluster munition inventory report to Congress, signaling its exclusion from both active and total stockpiles at that time.^[57] ^[58] Earlier transparency efforts, such as a 2004 DoD overview listing 5.5 million cluster munitions across 17 types, omitted the CBU-55 series entirely, further confirming its retirement prior to broader policy shifts on cluster submunitions.^[59] Although the U.S. abandoned a 2008 DoD policy in November 2017 that had mandated phasing out cluster munitions with submunition failure rates exceeding 1% by 2018, this reversal preserved newer, more reliable systems rather than legacy ordnance like the CBU-55.^[19] No evidence indicates ongoing stockpiling or modernization of the CBU-55; any residual units from its limited 1970s inventory were presumptively demilitarized through standard munitions disposal protocols for outdated explosives, prioritizing safety and resource allocation to contemporary thermobaric and precision weapons.^[19]

Influence on Modern Thermobaric Weapons

The CBU-55/B, introduced as the inaugural operational fuel-air explosive (FAE) cluster munition during the Vietnam War, dispersed three BLU-77/B submunitions containing ethylene oxide and propylene oxide to form an aerosol cloud ignited for sustained blast overpressures exceeding those of conventional explosives.^[3] This design validated FAE's capacity for volumetric detonation, consuming atmospheric oxygen to generate temperatures up to 2,500–3,000°C and prolonged shock waves effective against exposed personnel, vegetation, and light fortifications, though performance degraded in wind or rain due to fuel dispersion inconsistencies.^[30]^[22] Lessons from CBU-55's deployment spurred second-generation FAE iterations, such as the CBU-72, which refined burster charges and fuel mixtures for more reliable cloud formation, directly influencing the transition to modern thermobaric weapons that prioritize unitary warheads over clusters to minimize unexploded ordnance risks.^[30]^[10] These evolutions incorporate enhanced initiators, ethylene oxide variants with metal additives for increased impulse, and precision delivery via missiles or glide bombs, as seen in U.S. systems like the AGM-114N Hellfire variant (deployed circa 2002 in Afghanistan) and BLU-118/B penetrator (used in 2003 Iraq operations), which amplify overpressures in enclosed environments like caves or buildings.^[22] Russian advancements, including man-portable RPO-A Shmel rockets and TOS-1A launchers observed in Chechnya (1990s) and Ukraine (2022 onward), further exemplify CBU-55's conceptual legacy by scaling FAE for infantry and vehicular use against urban strongpoints, achieving kill radii up to 25 meters via improved fuel-air mixing despite lacking guidance in early models.^[22] Overall, the CBU-55 established FAE's tactical niche for non-line-of-sight defeat of dispersed or sheltered targets, driving global R&D toward thermobarics with 2–5 times the blast energy of TNT equivalents, though persistent challenges include sensitivity to countermeasures like suppression foams.^[3]^[30]

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[5]
John Ismay on X: "In it, a U.S. Army major general says it's possible ...
Mar 1, 2022 · In it, a U.S. Army major general says it's possible that an American air-dropped cluster bomb -- the CBU-55, with its three BLU-73 fuel-air ...
[6]
[PDF] Notable Achievements of the Naval Weapons Center - DTIC
The initial operational version was deployed to Vietnam in 1970. The CBU-55A/B for low-speed aircraft and the CBU-72B for high-speed delivery have been in the ...
[7]
MUNITIONS - Thermobaric Munitions and their Medical Effects!
... explosives by exploding a vapour in the blast zone. Their main use initially was in airborne fuel-air explosive bombs. Whilst the United States has ...
[8]
[PDF] Arming the Fleet - GovInfo
... CBU-55/B and CBU-72/B but contained propylene fuel. A surface-launched FAE was also developed by China Lake to clear safe paths through mined areas, a feat ...
[9]
Historical Documents - Office of the Historian
Ammunition—Desired stockage objectives (90 days for ARVN, 120 days for VNAF and VNN) have been achieved with the exception of CBU–55's, 60mm mortar ...
[10]
Weapons - China Lake Museum Foundation
China Lake's rocketry expertise--propulsion, warheads, airframes, aerodynamics, ballistics, launchers, fire-control, etc.--was also instrumental in ...
[11]
1972 China Lake Photo Gallery
Nov 13, 2015 · Rocketeer photo. FAE test drop. A CBU-55 FAE test drop in Louisiana demonstrates its effectiveness on underground positions, 10 March 1972.
[12]
CBU-55/B Fuel Air Explosive [3 x BLU-73/B] , SUU-49 - cmano-db.com
CBU-55/B Fuel Air Explosive [3 x BLU-73/B] (SUU-49) ; Type: Bomb, Weight: 210 kg ; Length: 2.2 m, Span: 0.36 m ; Diameter: 0.72, Generation: None ...Missing: specifications | Show results with:specifications
[13]
CBU-55 | Military Wiki - Fandom
The CBU-55 was a cluster bomb Fuel Air Explosive that was developed during the Vietnam War, by the United States Army, and was used only once in warfare.
[14]
SBU/SBK to SXU - Equipment Listing - Designation-Systems.Net
Oct 31, 2024 · The SUU-49( )/B was used for the following cluster bombs: CBU-55/B (3 BLU-73A/B in SUU-49/B); CBU-55A/B (3 BLU ...
[15]
https://bulletpicker.com/pdf/CBU.pdf
[16]
CBU-72 / BLU-73/B Fuel/Air Explosive (FAE) - GlobalSecurity.org
Jul 7, 2011 · The 550-pound CBU-72 cluster bomb contains three submunitions known as fuel/air explosive (FAE). The submunitions weigh approximately 100 pounds.
[17]
Bomb, Fuel Air Explosive, BLU-73/B - Bulletpicker
Description These are aerial dispensed, parachute stabilized, fuel-air-explosive (FAE) bombs which contain a self-destruct unit in the fuze.Missing: details | Show results with:details
[18]
Blu 73 submunition - CAT-UXO
This is the American BLU-73, a large aerially-dispersed, parachute-retarded and stablsied, High-Explosive-Blast (HE-Blast), Fuel-Air-Explosive (FAE) ...Missing: details | Show results with:details
[19]
Cluster Bombs - GlobalSecurity.org
Dec 20, 2017 · US Air Dispensed Submunitions ; CBU-52/B · BLU-61A/B · 217 ; CBU-55/B · BLU-73/B · 3 ; CBU-58/B · BLU-63/B · 650 ; CBU-59/B · BLU-77/B · 717 ; CBU-60/A, BLU- ...Missing: specifications | Show results with:specifications
[20]
[PDF] A GLOBAL OVERVIEW OF EXPLOSIVE SUBMUNITIONS
If this device fails to deploy or function as intended, or the distance of travel from the dispenser is not sufficient to arm the fuze, the submunition will not ...
[21]
[PDF] Fuel Air Explosives - CORE
However of these only methane, ethylene oxide, propylene oxide and MAPP. (methyl acetylene propadiene and propane mixture) found use in military applications.
[22]
Thermobaric Munitions and their Medical Effects - JMVH
... explosives by exploding a vapour in the blast zone. Their main use initially was in airborne fuel-air explosive bombs. Whilst the United States has ...
[23]
Thermobarics – Developments and Deployments - Euro-sd
Nov 10, 2022 · Thermobaric weapons, also known as Fuel Air Explosives (FAE), vacuum or aerosol bombs, dual-stage explosives or enhanced-blast weapons, have been developed and ...<|separator|>
[24]
Dispenser, SUU-49A/B - Bulletpicker
These are externally carried dispensers used to deliver fuel-air-explosive or smoke (SUU-49A/B only) bombs. The SUU-49A/B is released from high-speed and jet ...Missing: 55 | Show results with:55
[25]
South Vietnam's Thermopylae - HistoryNet
Feb 25, 2020 · On April 22 a C-130 dropped a 750-pound CBU-55 fuel-air bomb, approaching the explosive power of a nuclear bomb, on the headquarters of the ...Missing: details | Show results with:details<|separator|>
[26]
Battle of Xuan Loc - Vietnam War Commemoration
... CBU-55B fuel-air bomb—the first one ever used in combat. One North Vietnamese division retreats with heavy losses, but Xuan Loc is isolated and indefensible ...
[27]
Hô Chí Minh Campaign (April 1975) - War History
At Xuân Lôc the VNAF employed 750-pound CBU-55 cluster bombs and 15,000-pound “Daisy Cutter” bombs. On the 21st a VNAF C-130 dropped a CBU-55 “fuel bomb”, the ...Missing: deployment details
[28]
of validation military spocification panel, firing fae cbu-55 uh-1 ...
PANEL, FIRING FAE CBU-55 UH-1. ASSEMBLY AND PACKING. MIL-P-63052(AR). NOTICE 1 ... MIL-P-63052(AR), dated 4 March 1976, has been reviewed and determined to be.
[29]
Cbu 72 cluster bomb - CAT-UXO
This is the American CBU-72, a non-guided, free-fall, 550lb (250kg), Cluster-Bomb-Unit (CBU) dispensing the Fuel-Air-Explosive (FAE) BLU-73 submunition, ...
[30]
F16 - Aggressor
The 550-pound CBU-72 cluster bomb contains three submunitions known as fuel/air explosive (FAE). The submunitions weigh approximately 100 pounds.
[31]
[PDF] Meeting the Challenge - International Human Rights Clinic
II. A Decade of Cluster Munition Use: Recent Case Studies Documented by Human Rights Watch .... 19. Methodology .
[32]
Russia's Thermobaric Weapons Employment In The Ukrainian Conflict
May 28, 2024 · The TOS-1A Solntsepek multiple rocket launcher (MRL), a potent short-range thermobaric weapon system, has been the subject of significant ...
[33]
Fact Sheet: Russia's Use of Thermobaric Weapons in Ukraine
Mar 1, 2022 · On February 28, 2022, the Ukrainian ambassador to the United States confirmed that Russia had used a “vacuum bomb,” killing 70 soldiers, as part of its illegal ...Missing: history | Show results with:history
[34]
Chechnya Conflict: Use of Vacuum Bombs by Russian Forces
Feb 1, 2000 · On December 27, 1999, Interfax reported Russian forces were using fuel-air explosive bombs in the fighting in Chechnya.Missing: history | Show results with:history
[35]
Cluster Munitions and Thermobaric Weapons - PISM
Russia might now adapt its forces' tactics and capabilities for siege and urban warfare in the main cities and capital of Ukraine.
[36]
[PDF] PDF Related to Monthly Summaries, 1971 October
Oct 3, 1971 · There were no friendly casualties, and enemy casualties were undetermined. On 6 October, a CBU-55 drop was made by Black Ponies in the.
[37]
[PDF] Air War over South Vietnam 1968–1975
Jan 31, 2010 · This volume covers the period from the Tet offensive and the opening of the road to Khe Sanh in 1968 through the final collapse of South ...
[38]
[PDF] nd Modernization of Sout~ Vietnamese Armed Forces (RVNAF
It is apparent that the highly sophisticated US aerial bom- bardment capability cannot be duplicated In the Vietnamese. Air Force just as it is apparent that ...Missing: propane | Show results with:propane
[39]
[PDF] principles of fire support b2c2437 student handout
Topic. Page. M224 60mm Mortar. 5. M252 81mm Mortar. 7. 120mm Mortar. 8. Mortar Capabilities and Limitations. 10. Marine Corps Artillery.
[40]
Detonating the air: The legality of the use of thermobaric weapons ...
Apr 17, 2023 · The general customary law principles of international humanitarian law that determine the legality of the use of all weapons, including ...
[41]
[PDF] EXPLOSIVE WEAPONS IN POPULATED AREAS - ICRC
These categories of explosive weapon system may include large or unguided air-delivered bombs, missiles and rockets, unguided indirect fire weapons such as ...<|separator|>
[42]
Fatally Flawed: Cluster Bombs and Their Use by the United States in ...
The weapon attracts two major humanitarian criticisms: 1) cluster bombs are prone to causing civilian casualties during strikes, and 2) they leave large numbers ...
[43]
America's Dark History of Killing Its Own Troops With Cluster Munitions
Dec 4, 2019 · The weapons are notorious for their effects on civilians. But five years of reporting and hundreds of interviews have revealed they've also ...<|separator|>
[44]
Cluster Munitions: Background and Issues for Congress
Dec 16, 2024 · Cluster munitions are air-dropped or ground-launched weapons that release a number of smaller submunitions intended to kill enemy personnel or destroy vehicles.
[45]
The Convention on Cluster Munitions
The Convention on Cluster Munitions is an international treaty of more than 100 states. The Convention prohibits all use, production, transfer and stockpiling ...Convention text · States Parties · Convention · Organisation
[46]
https://disarmament.unoda.org/en/our-work/conventional-arms/legal-instruments/convention-cluster-munitions
[47]
States Parties - The Convention on Cluster Munitions
To date, a total of 123 States have committed to the goals of the Convention – 111 States Parties and 12 Signatories.
[48]
Cluster Munitions: New Use, Transfers Test International Ban
Sep 9, 2024 · The international treaty banning cluster munitions is making demonstrable progress, but is being tested by new use and transfers of cluster ...
[49]
United States - Landmine and Cluster Munition Monitor
Department of Defense officials claim the DPICM submunitions “have a dud rate less than 2.35 percent” but say that the testing data behind this figure is “ ...
[50]
Cluster Munitions: What Are They, and Why Is the United States ...
Jul 10, 2023 · Although the United States did not sign the convention, it stopped producing cluster munitions in 2008 and has produced only unitary warheads ...
[51]
Cluster Munitions at a Glance | Arms Control Association
As of July 2023, there have been no commitments by President Biden to change cluster munition policy. (See ACT, May 2022).
[52]
Why Biden Was Justified to Send Cluster Munitions to Ukraine | RAND
Aug 14, 2023 · The policy “established an unwaiverable requirement that cluster munitions used after 2018 must leave less than 1 percent of unexploded ...
[53]
[PDF] Humanitarian, military, technical and legal challenges of cluster ...
For working purposes in the meeting, the meaning of cluster munitions was taken to be the same as, and was used interchangeably with, "submunitions", which is ...Missing: analogues | Show results with:analogues
[54]
File:Fuel Air Explosive bombs in South Vietnam 1970.jpg
Aug 20, 2024 · The following other wikis use this file: Usage on de.wikipedia.org. CBU-55. Usage on fi.wikipedia.org. Aerosolipommi.
[55]
iii. concerns about cluster bombs - Human Rights Watch
Even if a cluster bomb hits its target, the bomblets may kill civilians within the footprint or, if they blow astray, nearby. The inherent risks to civilian ...
[56]
Weapons Potentially Inhumane: The Case of Cluster Bombs
Apr 1, 1974 · What is certain is that the CBU established itself during the Vietnam War as a highly effective weapon. Although the models used were not ...
[57]
https://the-monitor.org/online-reader/cluster-munition-monitor-2024?anchor=Major-Findings-115634
[58]
[PDF] Cluster Munition Monitor 2025 - ICBLCMC
Sep 16, 2025 · ... CBU-55B, and M509A1) were not listed in the “active” or “total” inventory by the US Department of Defense in a report to Congress in 2004.
[59]
[PDF] The US Cluster Munition Inventory and the FY 2006 Department of ...
The Air Force still has CBU-87 cluster bombs containing more than 20 million submunitions; the DoD report cites a failure rate of 4 to 6 percent, while U.N. ...Missing: 55B | Show results with:55B