The invention generally encompasses fire suppressant compositions and methods. In certain embodiments, the composition is configured to the heating device, for example, a stove or microwave. In certain embodiments, the invention includes holes to allow heat to enter into a compartment/shell and impinge upon a pressurized pouch containing a suppressant agent. In other embodiments, when a fire occurs it causes an exterior layer or relief valve to rupture the suppressant agent discharging towards the heat source and extinguishing the fire. In another application this complication is connected to an electrical or gas system and cuts the supply when the exterior layer of the device ruptures and releases a suppressant.

The invention generally encompasses fire suppressant compositions and methods. In certain embodiments, the composition is configured to the heating device, for example, a stove or microwave. In certain embodiments, the invention includes holes to allow heat to enter into a compartment/shell and impinge upon a pressurized pouch containing a suppressant agent. In other embodiments, when a fire occurs it causes an exterior layer or relief valve to rupture the suppressant agent discharging towards the heat source and extinguishing the fire. In another application this complication is connected to an electrical or gas system and cuts the supply when the exterior layer of the device ruptures and releases a suppressant.

A conductive film, a fabrication method of the conductive film, and a lithium-ion battery (LIB) are provided. The fabrication method includes: S10: selecting a support layer, and plating a first metal layer on upper and lower surfaces of the support layer, respectively; S20: compounding a first film on a surface of one of the first metal layers, and compounding a second film on a surface of the other one of the first metal layers; S30: compounding a third film on surfaces of the first film and the second film, and etching a plurality of circular holes penetrating through the third film and the second film; S40: plating a second metal layer on an outer surface of the third film and an inner wall of the circular hole; S50: fabricating a composite film; and S60: plating a third metal layer on upper and lower surfaces of the composite film.

A method for suppressing a pyrophoric metal fire may include arranging a suppression system above a containment structure. The suppression system includes a first extinguishing agent. The containment structure is configured to contain and isolate a pyrophoric metal from ambient air. The suppression system is configured to activate upon a leak and ignition of the pyrophoric metal so as to release the first extinguishing agent to suppress the pyrophoric metal fire.

A fire suppression system includes a transport refrigeration unit configured to cool a transport container. Also included is a tubular container having a fire suppressant stored therein, the tubular container disposed within the transport refrigeration unit. Further included is a predetermined fracture location of the tubular container, wherein the predetermined fracture location is configured to rupture upon reaching a critical temperature to expel the fire suppressant.

A fire suppression system includes a transport refrigeration unit configured to cool a transport container. Also included is a tubular container having a fire suppressant stored therein, the tubular container disposed within the transport refrigeration unit. Further included is a predetermined fracture location of the tubular container, wherein the predetermined fracture location is configured to rupture upon reaching a critical temperature to expel the fire suppressant.

There is provided a fire extinguisher comprising a fire extinguishing agent; a first mechanism configured to operate said fire extinguisher via a manual operation; a second mechanism configured to operate said fire extinguisher automatically; and wherein said fire extinguisher comprises at least one detector to detect the existence of a fire and cause the operation of said second mechanism.

There is provided a fire extinguisher comprising a fire extinguishing agent; a first mechanism configured to operate said fire extinguisher via a manual operation; a second mechanism configured to operate said fire extinguisher automatically; and wherein said fire extinguisher comprises at least one detector to detect the existence of a fire and cause the operation of said second mechanism.

A construction material consisting of a deployment system for a tire retardant substance, suitable for use in a wide variety of applications. This invention is designed to deploy a fire retardant substance in in response to the detection of an uncontrolled fire, thus minimizing or reducing risk of death, serious injury or property damage associated with uncontrolled fires when present in a habitable structure. The invention consists of a construction material which incorporates hinged or folding door(s) or flap(s) which contain a fire retardant substance within the construction material. When an uncontrolled fire is detected, the door(s) or flap(s) open and thus deploy the fire retardant substance onto the area affected by the uncontrolled fire.

A construction material consisting of a deployment system for a tire retardant substance, suitable for use in a wide variety of applications. This invention is designed to deploy a fire retardant substance in in response to the detection of an uncontrolled fire, thus minimizing or reducing risk of death, serious injury or property damage associated with uncontrolled fires when present in a habitable structure. The invention consists of a construction material which incorporates hinged or folding door(s) or flap(s) which contain a fire retardant substance within the construction material. When an uncontrolled fire is detected, the door(s) or flap(s) open and thus deploy the fire retardant substance onto the area affected by the uncontrolled fire.