A high-explosive squash head (HESH), also known as high-explosive plastic (HEP) in some contexts, is a type of anti-tank ammunition designed to defeat armored vehicles through the generation of internal spalling rather than direct penetration.[1] Upon impact, the thin-walled projectile flattens against the target's surface, spreading a plastic explosive charge into a thin disk; a base-detonated fuse then triggers an explosion that propagates a powerful shockwave through the armor.[2] This shockwave causes the inner layer of the armor to fracture and eject fragments, or "scabs," into the vehicle's interior, potentially injuring crew members, damaging equipment, or igniting ammunition without breaching the outer shell.[1]HESH rounds were developed during World War II by British inventor Charles Dennistoun Burney primarily as an anti-fortification munition to shatter concrete bunkers and walls through similar spalling effects.[2] Although the technology was not fully perfected or deployed in combat before the war's end, post-war testing revealed its unexpected effectiveness against metal armor, leading to its adaptation for anti-tank roles in rifled artillery and tank guns.[2] Unlike shaped-charge rounds such as high-explosive anti-tank (HEAT), HESH relies on chemical energy from the explosive rather than high velocity or shaped jets, making it less dependent on impact speed but more susceptible to countermeasures like spaced or composite armor that disrupt the shockwave.[1]HESH ammunition saw widespread adoption by British and Commonwealth forces, including in 105 mm rounds for the Centurion tank and 76 mm variants for vehicles like the Cougar reconnaissance vehicle, proving particularly useful against mid-20th-century Soviet armor in the 1950s and 1960s.[2] It also found applications in recoilless rifles and as a dual-purpose round effective against lightly armored targets, bunkers, buildings, and external optics or sensors on heavier vehicles.[1] In modern usage, HESH remains part of the armament for the British Army's Challenger 2 main battle tank, fired from the 120 mm L30 rifled gun alongside kinetic penetrators, though its role has diminished against advanced reactive and composite armors prevalent since the 1970s.[3]
Operating Principles
Mechanism of Action
Upon impact with the target, the high-explosive squash head (HESH) warhead, consisting of a thin metal shell filled with plastic explosive, deforms at moderate velocities into a disc-shaped charge that adheres to the surface without initial penetration. This squashing action ensures intimate contact between the explosive and the target's exterior, maximizing energy transfer.[1]The filler, typically a plastic explosive such as Composition B (a mixture of RDX and TNT), flows and conforms to the contours of the armored surface due to its dough-like consistency under impact stress. A delayed-action base fuze then triggers uniform detonation across the entire flattened charge, avoiding premature fragmentation that could reduce effectiveness.[4][1]The resulting explosion generates a high-pressure shock wave that transmits through the target material, reflecting from internal boundaries and causing widespread internal disruption. This process relies on the combined kinetic energy from impact and chemical energy from detonation, rather than forming a penetrating jet as in high-explosive anti-tank (HEAT) rounds. In early designs, HESH demonstrated effectiveness against armor equivalents up to 300 mm of rolled homogeneous armor (RHA).[1]
Physics of Deformation and Detonation
The plastic deformation of the high-explosive squash head (HESH) warhead upon impact is driven by the kinetic energy of the projectile, which exceeds the yield strength of the thin metal casing and the malleable filler material. The filler, typically a plastic explosive like Composition B (containing 60% RDX, 39% TNT, and 1% wax), undergoes viscous flow and conforms to the target's surface, forming a thin, uniform layer known as the "explosive pat." This deformation ensures maximal contact area for subsequent energy transfer, with the filler's low yield stress (on the order of 10-50 MPa) allowing it to spread radially without fracturing under impact velocities of 600-800 m/s.[5][6]Detonation in HESH warheads follows the principles of high explosive shock initiation, where the base fuze triggers a supersonic shock wave that propagates through the squashed explosive at velocities of approximately 8,000 m/s for RDX-based compositions at densities around 1.7 g/cm³. This wave compresses the explosive, leading to rapid chemical reaction and release of energy, with the Chapman-Jouguet detonation pressure reaching about 28 GPa at the front for such materials. The pressure buildup occurs over a reaction zone thickness of 0.1-1 mm, enabling efficient coupling of the blast to the target interface.[6][5]The response of the target material to this incident shock is described by the Rankine-Hugoniot relations for shock compression, particularly the linear approximation for stress:\sigma = \rho_0 U_s u_pwhere \sigma is the longitudinal stress, \rho_0 is the initial density of the target (e.g., ~7.8 g/cm³ for steel), U_s is the shock speed (typically 4-6 km/s in metals under these loads), and u_p is the particle velocity induced by the detonation (up to 2-3 km/s). This equation quantifies the compressive state behind the shock, essential for predicting material response in armored targets.[7][8]Under the extreme conditions of impact and detonation, the explosive filler exhibits hydrodynamic behavior, modeled as a high-pressure fluid with negligible shear strength to simulate its spreading and confinement against the target. This fluid-like approximation, using equations of state like the Jones-Wilkins-Lee (JWL) model for detonation products, captures the radial flow during deformation and the subsequent pressure distribution, with bulk moduli exceeding 10 GPa post-squash.[9]
Design Features
Warhead Construction
The warhead of a high-explosive squash head (HESH) round consists of a thin-walled steel casing designed for minimal structural rigidity, allowing it to deform and flatten upon impact with the target. This casing, typically a cylindrical steel forging with a short ogive nose and flat base, encloses the explosive filler and is engineered to collapse without fragmenting, thereby promoting the squashing effect essential to the round's performance.[10][11]The primary component within the casing is a plastic explosive filler, formulated for high plasticity and controlled detonation. A representative composition is Composition A3, comprising approximately 91% RDX (cyclotrimethylenetrinitramine) and 9% wax as a binder, which ensures the filler remains cohesive during flight and impact while enabling it to spread evenly. For a standard 105 mm round, the filler weight is typically around 3 kg, balancing explosive power with projectile aerodynamics.[12][13][11]The warhead integrates directly with the overall projectile body, forming the forward section of the full-bore round. In rifled gun systems, such as the British 105 mm L7, a copper rotating band is fitted around the projectile's midsection to engage the barrel rifling, imparting spin for flight stability without the need for a discarding sabot. The base of the warhead accommodates the fuze assembly, which is positioned to initiate detonation after deformation.[11][10]
Fuze and Initiation Systems
The fuze and initiation systems in high-explosive squash head (HESH) ammunition are engineered to trigger detonation after the plastic explosive filler has deformed and conformed to the target surface, optimizing shock wave transmission. Base-detonating fuzes are standard, positioned at the rear of the projectile to sense impact through mechanical means and incorporate a short delay mechanism. This delay, typically on the order of milliseconds, permits the explosive to spread fully before initiation, preventing premature explosion that could reduce effectiveness.[14][15]Impact detection in these fuzes typically relies on mechanical percussion elements that initiate upon collision, powering the initiation sequence. Early designs used mechanical impact detectors to create the necessary signal for delay activation, ensuring reliable functioning in high-velocity environments. Over time, these evolved to more advanced electronic fuzes with integrated delay circuits, offering greater precision and adaptability, such as variable timing adjustments for different target standoff distances or environmental conditions.[16][17]Safety interlocks are integral to HESH fuzes, featuring graze sensitivity controls that adjust the threshold for initiation to avoid detonation on shallow angles or minor contacts. These mechanisms include setback locks and environmental safeguards, such as acceleration thresholds during flight, to maintain arming only under proper launch conditions and prevent accidental functioning on angled surfaces. For example, the L56 percussion base fuze used in British HESH variants for the Challenger 2 main battle tank incorporates such interlocks for enhanced reliability in combat scenarios.[18][19]
Effects and Performance
Spalling and Armor Defeat
The high-explosive squash head (HESH) warhead defeats armored targets by inducing spalling, a process where the detonation generates intense internal shock waves that propagate through the armor, causing delamination at weak points and the ejection of metal fragments from the rear face. Upon contact, the warhead's plastic explosive filler deforms and spreads across the target's surface, maximizing contact area before detonation; the resulting blast impulse loads the armor with a high-pressure wave that travels longitudinally through the material. This compressive wave reflects as a tensile wave from the inner surface, superimposing to create stresses sufficient to fracture the armor internally, forming a "scab" or spall that detaches and projects inward at velocities capable of lethal damage to occupants and components.HESH's spalling effect is particularly effective against homogeneous rolled homogeneous armor (RHA), where the uniform ductility allows efficient wave transmission and fragmentation; British trials and related studies have demonstrated penetration depths equivalent to up to 150 mm of RHA through spall generation, with fragment velocities reaching up to approximately 140 m/s in impact simulations against steel plates.[20][9] For larger calibers, such as the 120 mm L2 used in recoilless systems like the BAT, HESH achieves equivalence against up to 400 mm RHA by producing extensive internal scabbing without physical perforation of the outer layer.[21] Experimental data from impulsive loading tests confirm scab thicknesses of 16-20 mm with average ejection velocities around 140 m/s, though higher velocities occur in full-scale detonations due to optimized explosive distribution.[9]The efficacy of spalling depends heavily on the target's material properties, with ductile metals like RHA promoting delamination and fragment ejection, while brittle ceramics in composite armors reflect or attenuate the shock waves, significantly reducing spall formation and overall defeat capability. In layered composite systems, the ceramic strike-face shatters or disperses the wave energy, preventing the tensile superposition needed for rear-face fragmentation, as evidenced by enhanced resistance in multi-layered designs incorporating porous or ceramic elements. This material dependence limits HESH against modern spaced or composite armors, where air gaps or non-ductile interlayers interrupt wave propagation, often resulting in minimal internal damage compared to homogeneous targets.
Limitations and Vulnerabilities
One major vulnerability of HESH rounds lies in their ineffectiveness against explosive reactive armor (ERA), where the outward detonation of ERA tiles upon impact disrupts the warhead's plastic explosive from properly squashing against the underlying armor, preventing the formation of the shock-transmitting "pat" essential for spall generation.[22]HESH performance is also highly dependent on impact velocity; the rounds are designed for muzzle velocities below approximately 800 m/s to ensure the thin-walled casing and malleable filler deform intact upon striking the target, as higher velocities—common in modern smoothbore guns—cause premature fragmentation and dispersal of the explosive before it can conform to the surface.[23]The introduction of Chobham-style composite armors in the post-1980s era has further diminished HESH capabilities, with layered ceramics, metals, and spacers attenuating shock waves and significantly reducing penetration effectiveness compared to homogeneous steel plates, as the discontinuities in the armor structure dissipate the transmitted pressure before significant spalling occurs.[24]While HESH excels at inducing spalling on traditional rolled homogeneous armor, these inherent limitations render it particularly vulnerable to contemporary armored vehicle designs and operational conditions. In modern applications, HESH retains utility for stripping ERA tiles or damaging external sensors and optics on advanced vehicles.
Historical Development
Origins in World War II
The development of the high-explosive squash head (HESH) warhead originated in Britain during World War II as an anti-fortification munition to defeat concrete bunkers and walls through spalling effects.[25] The British Armaments Design Establishment undertook the project in 1943-1944 to create a munition capable of defeating concrete fortifications through non-penetrative spalling effects, drawing on observations of explosive effects against structures and early experiments with plastic explosives.[26]The concept was proposed by inventor Charles Dennistoun Burney, who drew inspiration from molding experiments with plastic explosives pressed against hard surfaces, noting how the material conformed and transmitted shock waves effectively without needing a shaped charge liner.[2] Burney, a prolific designer of ordnance including recoilless weapons, envisioned a warhead filled with plastic explosive that would "squash" on impact to spread the detonation over a larger area, generating internal spalling in the target.[23]Initial prototypes were developed and tested in 1944 for use with the 6-pounder gun, focusing on anti-fortification effects, though not deployed before the war's end.[25] Although prototypes were developed, the technology was not fully perfected or deployed in combat before the war's end. Post-war testing revealed its unexpected effectiveness against metal armor, leading to its adaptation for anti-tank roles. These trials, conducted at British proving grounds, confirmed the warhead's ability to disrupt tank crews and internals via shock-induced fragments, marking a proof-of-concept for its application against heavy armor.[5][2]To maintain secrecy regarding its unique mechanism, the munition was initially designated "High-Explosive Plastic," a classification that emphasized the plastic filler while downplaying the squash-head design.[5] This nomenclature later influenced the American term HEP (high-explosive plastic) for similar rounds.[5]
Post-War Advancements and Proliferation
Following World War II, high-explosive squash head (HESH) ammunition underwent significant integration into advanced tank systems during the 1950s, particularly with the British Centurion tank's upgrade to the 105 mm L7 rifled gun. This development, introduced around 1959, allowed for more accurate and longer-range delivery of HESH rounds compared to earlier 20-pounder guns, achieving an effective engagement range of approximately 3 km against armored targets.[27]Post-war technological advancements focused on enhancing HESH performance through refined fuze mechanisms and explosive formulations. Improved base-detonating fuzes with variable delay capabilities were developed to optimize the timing of detonation after impact, allowing the plastic explosive to fully conform to the target surface before exploding and maximizing spall generation.[2] Additionally, the adoption of composite plastic explosives, such as those based on RDX with plasticizers, increased brisance—the shattering power of the blast—while maintaining the necessary malleability for squashing without premature fragmentation.[28]HESH technology proliferated internationally through licensing and exports, adapting to various national needs. The United States licensed the design in the 1950s and designated it as high-explosive plastic (HEP) for use in its 105 mm-armed M60 tanks, retaining the core squash-head mechanism for anti-armor effects.[28] The Soviet Union tested British HESH rounds in later decades to evaluate their performance against Soviet armor, though they did not fully adopt the squash-head concept.[20] Exports extended to allies, including India, where licensed production of HESH-compatible rounds began for integration into indigenous tank programs.[29]By the 1970s, HESH rounds were adapted for 120 mm smoothbore guns in some systems, though rifled barrels remained preferred for optimal spin stabilization of the malleable warhead. However, the rise of explosive reactive armor (ERA) in the late 1970s and 1980s significantly diminished HESH's effectiveness against modern tanks, as ERA disrupted the shockwave propagation needed for spalling, leading to a broader decline in its frontline role by the 1990s.[2]
Military Applications
Adoption by Forces
The British Army was the primary adopter of high-explosive squash head (HESH) munitions, integrating them into its main battle tanks starting in the late 1950s as part of the FV4201 Chieftain program, with the tank entering service in 1965.[30] The Chieftain's L11 120 mm rifled gun was designed to fire HESH rounds alongside armor-piercing discarding sabot (APDS) ammunition, providing versatility for engaging both armored vehicles and soft targets such as infantry or fortifications.[31] This dual-role capability aligned with British doctrine, which emphasized a balanced ammunition loadout to support combined arms operations, including suppression of enemy positions without excessive structural penetration.[31]Through Commonwealth ties, HESH munitions were exported and adopted by allied forces, including the Canadian, Australian, and Indian armies, which operated British-designed tanks like the Centurion and its derivatives during the Cold War era. These nations incorporated HESH into their tank inventories for similar multi-purpose applications, leveraging the round's effectiveness against both armored and unarmored threats in diverse operational environments. India continues to use HESH in its Arjun main battle tank as of 2025. The doctrinal preference for HESH in these forces stemmed from its suitability for low-collateral engagements in urban settings, where the squash-head mechanism spreads the explosive force across the target surface, minimizing risks of overpenetration into adjacent structures or populated areas compared to shaped-charge alternatives.[30]The United States implemented a limited variant known as high-explosive plastic (HEP), equivalent to HESH, primarily in specialized engineering roles rather than as a standard anti-armor round. This was seen in the M728 Combat Engineer Vehicle, a derivative of the M60 tank chassis, which entered U.S. Army service in 1968 and featured a 165 mm M135 demolition gun firing the M123A1 HEP round for breaching obstacles and fortifications.[32] Over 300 M728 units were produced by 1983, but HEP/HESH remained niche in U.S. doctrine, overshadowed by kinetic energy penetrators and high-explosive anti-tank rounds for main battle tanks.[32]By the 2000s, HESH had largely been phased out in most NATO forces in favor of advanced kinetic penetrators like armor-piercing fin-stabilized discarding sabot (APFSDS) rounds, driven by the need to counter evolving composite armors on modern tanks. The British Army retained HESH longer due to its rifled-gun heritage. Future upgrades, such as the Challenger 3 with a smoothbore gun, may be incompatible with traditional HESH designs.[3][30]
Combat Usage and Effectiveness
In the Falklands War of 1982, British forces deployed Scorpion CVR(T) reconnaissance vehicles armed with 76mm guns firing HESH rounds to provide direct fire support against Argentine positions. These rounds proved effective in neutralizing bunkers and fortified structures during advances such as the Battle of Mount Longdon, where HESH's explosive effect disrupted enemy defenses without requiring precise armor penetration. However, the Scorpion's light armament limited its impact against Argentine T-55 tanks, as HESH struggled to reliably defeat their sloped armor at typical engagement ranges, leading to reliance on other weapons for anti-tank roles.[33]In the Gulf War of 1991, HESH played a marginal role in British Challenger 1 tanks, which primarily used APFSDS for tank-on-tank combat but employed HESH for urban suppression and non-armored targets during operations like the Battle of Norfolk. Night engagements benefited from HESH's distinctive thermal signature visible through thermal sights, aiding target confirmation with bright flashes, though its overall use was overshadowed by kinetic penetrators against Iraqi T-72s. Post-war assessments noted HESH's value in area suppression but emphasized its limitations against modern reactive armor.[34]This usage underscored HESH's tactical flexibility in combined arms operations, though evolving threats shifted preferences toward specialized munitions.[35]