A mobile compressed foam firefighting unit comprising a mixing chamber connected at the outlet to the foam feeder, and the following systems connected to the mixing chamber inlet: a water supply system comprising a water pump and a water pump drive, a foam concentrate supply system comprising a foam pump and a foam pump drive, and an air supply system comprising an air compressor and an air pump drive. The system includes a drive motor, and drives of the air compressor and the foam pump comprise variable hydraulic transmissions kinetically connected to the drive motor, and the system is equipped with a water flow meter, a throttle valve with an electric drive and a check valve, and an electronic control unit of the throttle valve installed in the water supply pipe between the water pump and the mixing chamber.

A “FirePOD” provides a self-contained, portable, standalone fire protection system that enables property owners, firefighters or others to mix and apply fire-protective gel or foam to entities such as structures, vehicles, vegetation, etc., to protect those entities from wildfire events or other external fire incidents. In various implementations, the FirePOD includes a recirculation-based mixing system for combining a mixture comprising a powder, liquid, or gel-based Thermal Protective Substance (TPS) with a volume of water or other liquid to produce the fire-protective gel or foam. By applying reconfigurable valves, one or more pumps are applied to both recirculate the mixture and, when sufficiently mixed, apply the resulting fire-protective gel or foam via one or more hoses or other dispensing mechanisms. In various implementations, the FirePOD is movable, and is manually or automatically propelled to locations suitable for applying the fire-protective gel or foam.

A “FirePOD” provides a self-contained, portable, standalone fire protection system that enables property owners, firefighters or others to mix and apply fire-protective gel or foam to entities such as structures, vehicles, vegetation, etc., to protect those entities from wildfire events or other external fire incidents. In various implementations, the FirePOD includes a recirculation-based mixing system for combining a mixture comprising a powder, liquid, or gel-based Thermal Protective Substance (TPS) with a volume of water or other liquid to produce the fire-protective gel or foam. By applying reconfigurable valves, one or more pumps are applied to both recirculate the mixture and, when sufficiently mixed, apply the resulting fire-protective gel or foam via one or more hoses or other dispensing mechanisms. In various implementations, the FirePOD is movable, and is manually or automatically propelled to locations suitable for applying the fire-protective gel or foam.

Provided herein is a fluid projecting platform. In some embodiments, the fluid projecting platform herein is configured for use in firefighting, crowd dispersion, agriculture or other related tasks.

Provided herein is a fluid projecting platform. In some embodiments, the fluid projecting platform herein is configured for use in firefighting, crowd dispersion, agriculture or other related tasks.

Environmentally-clean fire inhibiting and extinguishing dry powder compositions and products for sorbing flammable liquids while inhibiting ignition and extinguishing fire involving flammable hydrocarbon liquids such as, oils, fuels and non-polar solvents such as ketones and alcohols. The dry powder chemical compositions are made by mixing, blending and milling to suitable powder particle sizes, the following components: a fire extinguishing agent in the form of at least one alkali metal salt of a nonpolymeric saturated carboxylic acid; a powder fluidizing agent to help provide the dry powder composition with excellent fluid flow characteristics; and an oleophilic/hydrophobic composition for absorbing liquid hydrocarbons, while repelling water. A surfactant may be added to promote the formation of anhydrous semi-crystalline metal mineral salt film onto the surface of flammable hydrocarbon liquids involved in fire outbreaks to be extinguished and preferably absorbed by the dry powder chemical compositions.

A fire fighting vehicle includes an energy storage system coupled to the chassis and a charging assembly configured to interface with a charging plug. The energy storage system includes battery cells. The charging assembly includes a housing, a charging port disposed within the housing and electrically coupled to the battery cells, a retainer positioned proximate the charging port, a first actuator, and a second actuator. The charging port is configured to engage with a charging interface of the charging plug. The retainer is configured to engage with a retaining interface of the charging plug to secure the charging interface within the charging port. The first actuator is positioned to release the retaining interface from engagement with the retainer by repositioning the retaining interface into a release position. The second actuator is positioned to eject the charging plug from the charging assembly when the retaining interface is in the release position.

A fire fighting vehicle includes an energy storage system coupled to the chassis and a charging assembly configured to interface with a charging plug. The energy storage system includes battery cells. The charging assembly includes a housing, a charging port disposed within the housing and electrically coupled to the battery cells, a retainer positioned proximate the charging port, a first actuator, and a second actuator. The charging port is configured to engage with a charging interface of the charging plug. The retainer is configured to engage with a retaining interface of the charging plug to secure the charging interface within the charging port. The first actuator is positioned to release the retaining interface from engagement with the retainer by repositioning the retaining interface into a release position. The second actuator is positioned to eject the charging plug from the charging assembly when the retaining interface is in the release position.

A fire fighting vehicle includes a front axle, a rear axle, an energy storage system, an engine, a first motor/generator, and a second motor/generator. In a first mode, (a) the engine is off and (b) at least one of the first motor/generator or the second motor/generator uses stored energy in the energy storage system to drive at least one of the front axle or the rear axle. In a second mode, (a) the engine provides a mechanical input the first motor/generator, (b) the first motor/generator uses the mechanical input to generate electricity, (c) the second motor/generator uses the electricity to drive at least one of the front axle or the rear axle. Any electricity generated by either the first motor/generator or second motor/generator in response to the mechanical input from the engine is never provided to the energy storage system to charge the energy storage system.

A fire fighting vehicle includes a front axle, a rear axle, an energy storage system, an engine, a first motor/generator, and a second motor/generator. In a first mode, (a) the engine is off and (b) at least one of the first motor/generator or the second motor/generator uses stored energy in the energy storage system to drive at least one of the front axle or the rear axle. In a second mode, (a) the engine provides a mechanical input the first motor/generator, (b) the first motor/generator uses the mechanical input to generate electricity, (c) the second motor/generator uses the electricity to drive at least one of the front axle or the rear axle. Any electricity generated by either the first motor/generator or second motor/generator in response to the mechanical input from the engine is never provided to the energy storage system to charge the energy storage system.