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TOS-2

The TOS-2 Tosochka is a self-propelled heavy system, classified as a that fires thermobaric rockets to engage enemy personnel in open areas, field fortifications, and light armored vehicles. It mounts an 18-tube launcher on a Ural-63706 6x6 wheeled chassis, providing greater road mobility compared to the tracked TOS-1A predecessor. Developed as a successor emphasizing , accuracy, and extended range, the system incorporates an automatic fire control suite with thermal imaging, ballistic computation, and laser ranging for rapid salvo delivery. Introduced publicly around 2020 during state trials, the TOS-2 entered limited production and service with Russian radiation, chemical, and biological defense troops by 2022, with further battalions formed in the Southern Military District. It employs 220-mm TBS-3M thermobaric rockets, achieving a maximum range of 15 kilometers and capable of saturating up to 6 hectares per full salvo of 18 rounds in as little as 6 seconds under automatic mode. First confirmed in combat during the Russia-Ukraine conflict, targeting fortified positions and urban strongpoints, its thermobaric warheads generate intense overpressure and heat, proving effective against entrenched infantry but drawing scrutiny for indiscriminate area effects. Powered by a 440-horsepower YaMZ-652 diesel engine, it attains speeds up to 100 km/h with an operational range of 1,000 km, enhancing tactical flexibility over prior models.

Development

Origins from TOS-1

The TOS-2 Tosochka heavy flamethrower system evolved directly from the , a tracked developed in the early by the KBTM design bureau in to deliver thermobaric munitions against enemy fortifications, manpower concentrations, and light armor in open terrain. The , which entered limited Soviet service without public acknowledgment until the early , featured a 24-tube mm launcher pod mounted on a tank chassis, emphasizing short-range, high-volume with rockets effective up to approximately 3-5 kilometers. This design prioritized cross-country mobility but suffered from vulnerabilities including exposure during reloading, limited road speeds of around 50 km/h, and dependency on separate loading vehicles, which complicated operations in dynamic battlefields. Development of the TOS-2 addressed these limitations by shifting to a wheeled platform and incorporating , retaining the core thermobaric concept while enhancing survivability and tactical flexibility as a direct successor intended to phase out older variants. efforts, led by entities like , focused on integrating an onboard crane for self-reloading and a more compact 18-tube launcher to reduce crew exposure, drawing lessons from combat use in conflicts such as and where the system's devastating area effects were proven but logistical demands were evident. Preliminary work likely began in the mid-2010s, culminating in state trials by 2019, with the Ministry of Defense announcing initial deliveries slated for May 2020. The TOS-2's origins reflect a doctrinal toward systems better suited for rapid , transitioning from the 's tank-derived heavy armor—which offered protection but hindered strategic mobility—to a Ural-63706 6x6 truck chassis capable of speeds exceeding 80 km/h and improved off-road performance without the maintenance burdens of tracks. This change maintained compatibility with 220 mm thermobaric projectiles while enabling automated sequencing and remote operation, reducing the crew from three to two and minimizing vulnerability during fire missions. Initial public unveiling occurred during the on June 24, 2020, marking the system's maturation from TOS-1 heritage into a modernized platform for Radiation, Chemical, and Biological Troops.

Design improvements and testing

The TOS-2 features a wheeled derived from the Ural-63706-0120 6x6 , replacing the tracked T-72-derived of the TOS-1A, which enhances road mobility, reduces maintenance requirements, and improves tactical redeployment speed across varied terrains. This shift prioritizes operational flexibility over the cross-country prowess of tracks, aligning with requirements for rapid positioning in defensive or urban engagements. A primary advancement is the incorporation of an integral hydraulic crane for automated reloading of the 18-rocket launch pod, eliminating reliance on external transport-loading vehicles and enabling self-sufficient operations with reduced crew exposure during replenishment. This mechanism, visible as a compact 3-link arm, supports faster salvo preparation, with the system capable of firing its initial barrage in under 30 seconds post-setup. The has been upgraded to full , integrating targeting, ballistic , and stabilized for improved under motion or adverse conditions, while crew protection is bolstered through enhanced armor and reduced launch signatures compared to predecessors. Compatibility with extended-range TBS-3M thermobaric rockets further amplifies lethality, achieving up to 15 km engagement distances via refined solid-propellant motors and heavier warheads. Development testing began with prototypes evaluated by Russian CBRN troops in 2020, focusing on integration of the automated loader and wheeled mobility in field conditions. State trials for the vehicle and munitions were slated for completion by late 2020, incorporating live-fire validations of range extensions and survivability metrics. Subsequent troop trials confirmed operational reliability, leading to public demonstration at the Army-2022 forum, where the system's crane and pod mechanics were showcased under static and dynamic scenarios. New rocket variants underwent parallel state testing, with initial prototype batches produced to assess propulsion stability and warhead yields against fortified targets.

Entry into production and service

The TOS-2 Tosochka heavy system completed state acceptance trials following initial testing during the Kavkaz-2020 exercises in September 2020, where prototypes were employed for the first time. Official adoption into service occurred on January 6, 2021, with initial delivery to the of the . Serial production commenced in 2021 under the Splav State Research and Enterprise, enabling broader integration into Russian radiation, chemical, and biological troops units. By May 2022, TOS-2 systems were reported in operational deployment during the special military operation in , marking their combat debut. confirmed active combat employment of the TOS-2 in subsequent updates, highlighting its role in engaging fortified positions and lightly armored targets. Production output has supported incremental fleet expansion, though specific unit numbers remain classified, with confirmed losses of individual vehicles in by early 2025.

Design and Specifications

Chassis and mobility features

The TOS-2 utilizes the , a high-mobility all-terrain developed for enhanced transport capabilities compared to the tracked T-72-derived chassis of the TOS-1A. This shift to a wheeled configuration increases strategic mobility, allowing faster road marches and quicker repositioning after firing salvos. The chassis is powered by a YaMZ-652 V8 delivering 440 horsepower, enabling a maximum speed of 100 km/h and an operational range of 1,000 km on a full load. The 6×6 drive system provides improved cross-country performance suitable for rapid deployment in varied terrains, though optimized primarily for road networks and open areas to support mobile operations. Additional mobility features include a compact design for better maneuverability and an integrated crane for self-loading of pods, reducing reliance on external during field operations. This setup allows the TOS-2 to achieve speeds comparable to standard trucks, facilitating swift integration into motorized units and minimizing exposure during transit.

Launch system and automation

The TOS-2 employs a system consisting of 18 fixed launch tubes arranged in two layers, capable of firing 220 mm thermobaric rockets in salvos. The launcher is mounted on a Ural-63706 6x6 wheeled chassis, enabling rapid deployment and repositioning after firing to avoid . Aiming, shooting, and fire control processes are fully automated, incorporating a thermal imaging sight, ballistic computer, and for precise and engagement. This automation allows for launch initiation without manual intervention, improving response times and accuracy compared to predecessor systems like the TOS-1A. Reloading is facilitated by an integrated crane-manipulator, eliminating the need for separate support vehicles and enabling the crew to perform the task independently in under 20 minutes under optimal conditions. The system's digital fire control integrates with external reconnaissance data, supporting networked operations for coordinated strikes.

Crew protection and survivability

The TOS-2 features an armored crew cabin mounted on the forward section of its Ural-63706 , designed to the three-person from small-arms fire and artillery shell fragments. This protection level aligns with the system's assignment to Russia's Nuclear, Biological, and Chemical () defense troops, incorporating standard NBC filtration and overpressurization systems to safeguard occupants against contaminated environments. Survivability is further enhanced by electronic countermeasures, including systems to counter high-precision guided munitions, given the TOS-2's operation in forward tactical zones where exposure to enemy targeting is elevated. Recent field adaptations in Ukraine have included radio-absorbing camouflage netting over the cabin to reduce detectability by radar and optical sensors, as well as metal screens and netting to deter drone strikes on exposed components. The automated fire control and remote reloading capabilities minimize crew exposure during firing sequences, allowing rapid salvo delivery from cover without prolonged dismounting. Despite these measures, operational losses in highlight vulnerabilities to FPV drones and precision strikes when or electronic defenses are overwhelmed, underscoring that while the cabin provides baseline ballistic protection, the system's overall survivability relies heavily on mobility and tactical positioning rather than heavy armor.

Munitions and Tactical Capabilities

Types of thermobaric rockets

The TOS-2 system launches 220 mm rockets primarily equipped with thermobaric s, which function by dispersing a fuel-air to create an cloud that ignites, generating a prolonged and extreme effective against personnel, fortifications, and light vehicles in open or enclosed spaces. These munitions consist of a motor, a containing separated combustible and , and a that atomizes the mixture on impact before secondary ignition. Key variants include the MO.1.01.04 series, with the baseline model measuring 3.3 meters in length and weighing 173 kg, offering a maximum range of approximately 6 km for engaging close-range targets. An extended variant, MO.1.01.04M, extends to 3.7 meters for improved range up to 10 km, incorporating a heavier thermobaric payload upgraded in March 2020 to enhance blast effects while maintaining compatibility with the TOS-2's automated launchers. More recent developments feature the TBS-M3 and TBS-3M rockets, introduced to extend operational reach; the TBS-M3 achieves up to 15 km with refined and propulsion, while the TBS-3M further optimizes the solid-propellant motor for reliability in contested environments, as demonstrated in field upgrades reported in April 2025. These thermobaric types prioritize volume-of-fire salvos from the system's 18-round capacity (two pods of nine), delivering high-density coverage over areas up to 40,000 square meters per full launch. In addition to thermobaric loads, the TOS-2 supports incendiary variants weighing around kg, designed for sustained fire-starting and area denial against or structures, though these are secondary to the primary blast-focused thermobaric munitions. All rockets remain unguided, relying on inertial stabilization and pre-launch alignment for accuracy within 50-100 meters CEP at maximum range, with no confirmed guided subtypes as of October 2025.

Range, accuracy, and destructive effects

The TOS-2 Tosochka launches 220 mm thermobaric rockets from an 18-tube pod, with a maximum of 15 kilometers using the upgraded TBS-3M munitions featuring improved solid-propellant motors, as demonstrated in operational testing by April 2025. Prior configurations achieved ranges up to 12 kilometers, representing a substantial extension over the TOS-1A's 6-kilometer limit to enable standoff engagements beyond direct counterfire threats. Accuracy is augmented by an integrated automated , which processes ballistic data, environmental factors, and target coordinates to adjust launch parameters, yielding improved hit probabilities for area saturation compared to manual systems on earlier models. Dispersion patterns remain characteristic of unguided rockets, prioritizing volume fire over precision strikes, with reported values in the tens of meters for salvoes under optimal conditions, though susceptible to and influences. Destructive effects stem from the thermobaric warheads, which disperse clouds ignited to produce a high-temperature wave combining exceeding 30 , incendiary burns up to 2,500°C, and vacuum-like oxygen depletion that asphyxiates unprotected personnel and collapses pulmonary structures. A single TOS-2 salvo covers an intensified —approximately 50% larger than the TOS-1A's due to denser packing and enhanced yields—capable of demolishing reinforced bunkers, light vehicles, and concentrations within a 200-300 meter radius per , with secondary fires propagating through urban or forested terrain. These munitions excel against enclosed spaces, where pressure waves reverberate to amplify lethality, but efficacy diminishes in open air against dispersed or hardened targets shielded by earthworks.

Comparison to conventional munitions

The thermobaric rockets used in the TOS-2 system differ fundamentally from conventional high-explosive (HE) munitions in their detonation mechanism and resulting effects. Thermobaric warheads disperse a fuel-air aerosol cloud, which is ignited to create a fireball and sustained blast wave, producing temperatures of 2,500–3,000°C and overpressures up to 73 kg/cm², with a prolonged duration that exceeds the near-instantaneous impulse of HE explosives. In contrast, HE munitions generate a rapid pressure spike through chemical decomposition but lack the aerosol dispersion phase, resulting in shorter blast impulses and reliance on fragmentation for secondary effects. This distinction makes thermobaric effects particularly amplified in volumetric or confined environments, where the blast wave reflects off surfaces, enhancing impulse delivery. In terms of lethality against personnel, thermobaric munitions inflict more severe primary blast injuries due to the extended duration, which transmits deeper into the body, causing pulmonary , gastrointestinal rupture, and arterial gas emboli at lower peak pressures than equivalent HE blasts require. Conventional HE munitions, while effective via and initial shock, produce fewer delayed respiratory failures or oxygen-depletion effects, leading to comparatively lower rates of overwhelming internal trauma in enclosed spaces. Thermobaric systems like the TOS-2's rockets thus excel against in fortifications or urban settings, where a single salvo can neutralize dug-in positions equivalent to multiple HE rounds, as demonstrated in TOS-series applications against buildings. Tactically, TOS-2 thermobaric rockets offer superior structural penetration and area-denial capabilities over HE counterparts, entering cavities to propagate blasts internally and consuming ambient oxygen to hinder survivor recovery, but they underperform against open-area armored targets lacking fragmentation kill mechanisms. Conventional HE munitions provide broader versatility in fragmentation-dominant scenarios, such as anti-vehicle roles, without the weather sensitivity or potential toxic residues associated with fuel-air mixtures. Overall, thermobaric effects prioritize in asymmetric engagements involving , potentially generating casualty severities that strain medical response more than standard HE engagements.

Operational History

Initial deployments

The TOS-2 Tosochka heavy flamethrower system underwent its operational deployment during the Kavkaz-2020 strategic exercises, conducted by the from September 21 to 26, 2020, across multiple ranges in the . On September 25, at the proving ground in the Region, the TOS-2 fired unguided rockets with thermobaric warheads to neutralize simulated advancing enemy armored columns, showcasing its automated targeting, fire control, and rapid salvo capabilities in a scenario emphasizing destruction of fortified positions and light armor. The exercises involved approximately 80,000 personnel and integrated the TOS-2 with other systems for operations, highlighting its role in countering open-terrain threats. Prior to the drills, the TOS-2 had been publicly unveiled at the Parade in on June 24, 2020, mounted on a Ural-63706 wheeled for enhanced mobility over its TOS-1A predecessor. State tests concluded around this period, paving the way for serial production and unit integration. The system formally entered service with the in 2021, with early deliveries equipping specialized heavy flamethrower subunits within the Chemical, Biological, Radiological, and Nuclear ( Troops. Initial fielding prioritized battalions in the , where three new units were formed to operate TOS-2 alongside TOS-1A systems, focusing on thermobaric support for breakthrough operations against entrenched defenses. These deployments emphasized the TOS-2's self-loading crane and extended range, reducing logistical dependencies compared to earlier models.

Use in the Russo-Ukrainian War

The heavy flamethrower system saw its first confirmed combat deployment in the in October 2023, according to state media reports, marking an upgrade over the earlier TOS-1A Solntsepek in fire support operations. forces employed it primarily against fortifications, manpower concentrations in open terrain, and light armored vehicles, leveraging its thermobaric rockets for area-denial effects in support of ground advances. Deployments included units equipped with radiation-absorbing coatings to reduce detectability by and sensors, as observed in frontline positions by November 2024. Russian military sources claimed TOS-2 strikes inflicted heavy casualties on positions, with video footage from early 2025 showing volleys targeting defensive lines and destroying entrenched targets through and incendiary effects. The system's automated reloading and extended range—up to 15 km in recent variants—enabled support from safer standoff distances compared to predecessors, integrating it into tactics alongside and drones. On February 16, 2025, FPV operators from the 414th Separate UAV Brigade, known as "Birds of ," destroyed the first visually confirmed TOS-2 near in , with geolocated imagery showing the wrecked after a precision . This loss highlighted vulnerabilities to munitions, despite the TOS-2's enhanced mobility on the Ural-63706 , and underscored limited fielding, with production constraints reportedly restricting widespread use prior to 2025. Subsequent reports indicated sporadic employment in high-intensity sectors like the , but no large-scale formations were verified by mid-2025.

Reported losses and adaptations

The first visually confirmed destruction of a TOS-2 Tosochka occurred near in in February 2025, with photographs of the wreckage published by Russian military personnel themselves. As of October 2025, tracking based on photographic and videographic evidence has documented one TOS-2 as destroyed and another as damaged in the , reflecting the system's limited deployment and high-value status. Russian forces have responded to vulnerabilities exposed in combat—particularly to FPV drones and munitions—by retrofitting TOS-2 units with protective measures. These include anti-drone cages installed over the module to deflect incoming projectiles, a modification observed on deployed systems as early as February 2025. Additionally, TOS-2 vehicles in have received radio wave-absorbing kits to reduce detectability by and systems, with such upgrades noted on frontline units by November 2024. These adaptations build on the TOS-2's inherent design improvements over predecessors, such as automated reloading to minimize exposure time during operations, but address war-specific threats like pervasive swarms.

Analysis and Reception

Combat effectiveness and achievements

The TOS-2 Tosochka has demonstrated notable in suppressing fortified positions and concentrations during operations in the Donetsk region of , primarily through its thermobaric munitions' capacity to generate sustained high-pressure blasts and incendiary effects in enclosed environments. Ministry of reports indicate that TOS-2 salvos have neutralized strongholds, with crews achieving rapid transitions from march to fire positions via automated systems, enabling strikes within seconds of . For instance, on July 28, 2025, a TOS-2 unit reportedly destroyed multiple enemy firing points and manpower groups, with operators citing the system's ability to deliver both area saturation and point targeting, resulting in "very serious and good" outcomes against dispersed forces. In another engagement on October 7, 2025, TOS-2 crews targeted and obliterated a fortified stronghold, leveraging the launcher’s 18-rocket capacity to cover areas up to 15 km distant with upgraded TBS-M3 projectiles, which produce fireballs and waves effective against bunkers and trenches. These operations underscore the system's role in breaching defenses ahead of advances, with assessments emphasizing its high lethality and short salvo times—typically under 10 seconds—contributing to minimized exposure and sustained fire support. Military analyses from sources highlight the TOS-2's achievements in scenarios, where thermobaric effects have reportedly cleared building complexes and underground positions more efficiently than conventional high-explosive , due to the munitions' fuel-air creating oxygen-depleting vacuums and secondary fires. Deployments since late 2023 have integrated the system into tactics, achieving localized breakthroughs by demoralizing and incinerating exposed personnel, though such claims originate from state-affiliated outlets and lack independent corroboration amid the conflict's information constraints.

Criticisms, vulnerabilities, and countermeasures

The TOS-2 Tosochka has demonstrated vulnerabilities in environments, where its radio communications are susceptible to , resulting in slow and unstable data exchange between units and command centers that hampers fire adjustments. Centralized command structures further limit crew autonomy, delaying responses in fast-paced combat and requiring escorts from armored vehicles and to counter threats and ambushes. Physically, the system's wheeled Ural-63706 chassis enhances mobility over the tracked TOS-1A but offers only cab armor sufficient against small-arms fire, leaving it exposed to drones, precision-guided munitions, and artillery. This was evidenced by the destruction of the first deployed TOS-2 near on February 16, 2025, likely via drone or precision strike, highlighting failures in its defensive systems despite modern upgrades. Ukrainian countermeasures exploit these weaknesses through enhanced reconnaissance, disruption, and targeted strikes with FPV drones or anti-armor systems, which have proven effective against similar thermobaric platforms by capitalizing on their need for close-range positioning. adaptations include radio-absorbing coatings to reduce detectability, as applied to TOS-2 units by November 2024, and operational escorts with buggies and personnel armed against low-flying threats. Critics, including defense analysts, note that these doctrinal rigidities and reliance on support groups undermine the TOS-2's tactical flexibility in contested , rendering it a high-value, detectable target despite range extensions to 15 km.

Strategic implications and future prospects

The TOS-2 Tosochka enhances Russia's capacity for delivering high-volume thermobaric strikes against fortified positions and personnel concentrations, aligning with doctrinal emphasis on overwhelming for assaults in or environments. Its wheeled Ural-63706 chassis provides superior cross-country mobility over the tracked TOS-1A, enabling faster repositioning and reduced exposure during operations, while the automated allows for rapid salvoes of up to 18 rockets covering areas of approximately six hectares. This capability supports attritional strategies observed in the Russo-Ukrainian conflict, where such systems neutralize defensive strongpoints to facilitate mechanized advances, though their short —extended to 15 km with TBS-3M munitions—necessitates forward deployment and integration with assets to mitigate risks from . Strategically, the system's deployment underscores Russia's prioritization of thermobaric weaponry within troops for area-denial effects, with three new battalions equipped with TOS-1A and TOS-2 variants formed in the by 2024, expanding total heavy flamethrower assets to 42 units. However, documented losses, including the first confirmed destruction of a TOS-2 near in February 2025 via Ukrainian drone strikes, highlight vulnerabilities to precision-guided munitions and , prompting adaptations like radio-absorbing and counter-drone shielding. These incidents reveal a causal : while thermobaric excels against unarmored targets in cover, the vehicle's size and reload time—requiring proximity to —expose it to attrition in drone-saturated battlefields, potentially limiting its utility in high-intensity peer conflicts against adversaries with advanced capabilities. Looking ahead, prospects for the TOS-2 include serial production acceleration following completion of state trials for extended-range projectiles by late 2023, with ongoing enhancements such as integrated electronic warfare suites to counter UAV threats, as evidenced by upgrades to predecessor systems. Russian leadership's recognition, including a 2025 state award for TOS-2 rocket developers, signals commitment to iterative improvements amid sanctions-constrained manufacturing, potentially integrating the platform with loitering munitions for hybrid fire support. Export potential remains constrained by international prohibitions on thermobaric systems, though domestic fielding could evolve toward networked operations, balancing its niche role in breaking low-tech defenses against evolving countermeasures like Western-supplied precision artillery.

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