A portable fuel container is disclosed that includes a paddle actuator that is depressible into an engaged position, whereby fluid may only be removed from the container while the paddle actuator is being depressed.

A flame mitigation device (FMD) contained within the neck of a container and configured to allow the fuel nozzle to pass through the FMD. The FMD forming a barrier in the neck of the fill port and capable of constricting the fuel nozzle upon passing through the FMD to inhibit external debris from entering the interior of the portable container and to inhibit fuel from flowing back out of the fill port.

The present invention includes systems, assemblies, and methodologies for inhibiting combustion within fluid containers, enhancing the safety of such containers. One aspect includes a novel base module from which assemblies of varying shape and size, suitable for disposing within a variety of different fluid containers, are created. In one embodiment, the base module is made from an expanded mesh which is rolled in a novel cylindrical configuration according to a novel methodology. In another embodiment, the base module may be combined with other base modules to form an assembly. The present invention is also directed to an apparatus and method for creating base modules which allows for varying density of the base modules and therefore varying flexural strength and rigidity of the assemblies. As such, the packing density of assemblies within containers may be optimized to produce the desired effect of inhibiting combustion within the container.

A liquid storage tank has a breathing valve that vents the tank's headspace at a high-pressure value and admits an ambient gas at a low-pressure value. A controller generates a first control signal when the percentage of the catalyst gas is less than a catalyst threshold, a second control signal when the percentage of the catalyst gas exceeds the catalyst threshold, and a third control signal when the pressure in the headspace is equal to a low-pressure threshold between the breathing valve's low-pressure value and high-pressure value. The first valve is only opened to output inert gas at a discharge pressure greater than the breathing valve's high-pressure value in response to the second control signal. The second valve is only opened to output inert gas at a discharge pressure that is between the breathing valve's low-pressure value and high-pressure value in response to the third control signal.

The present invention includes systems, assemblies, and methodologies for inhibiting combustion within fluid containers, enhancing the safety of such containers. One aspect includes a novel base module from which assemblies of varying shape and size, suitable for disposing within a variety of different fluid containers, are created. In one embodiment, the base module is made from an expanded mesh which is rolled in a novel cylindrical configuration according to a novel methodology. In another embodiment, the base module may be combined with other base modules to form an assembly. The present invention is also directed to an apparatus and method for creating base modules which allows for varying density of the base modules and therefore varying flexural strength and rigidity of the assemblies. As such, the packing density of assemblies within containers may be optimized to produce the desired effect of inhibiting combustion within the container.

The present invention includes systems, assemblies, and methodologies for inhibiting combustion within fluid containers, enhancing the safety of such containers. One aspect includes a novel fuel containers which take advantage of the inventive principles disclosed herein. In one embodiment a fuel drum includes a plurality of base assemblies arranged in a drum cluster, and disposed within the drum. In another embodiment, a portable fuel container includes a plurality of base assemblies arranged in a can cluster and disposed within the portable fuel container. In yet another embodiment, a plurality of base assemblies are arranged in a cell cluster and disposed within a lattice structure.

A flame mitigation device (FMD) contained within the neck of a container and configured to allow the fuel nozzle to pass through the FMD. The FMD forming a barrier in the neck of the fill port and capable of constricting the fuel nozzle upon passing through the FMD to inhibit external debris from entering the interior of the portable container and to inhibit fuel from flowing back out of the fill port.

A portable fuel container configured to prevent liquid fuel contained therein from being entirely emptied from the container. The amount of liquid fuel retained in the container can be sufficient to maintain a fuel-to-air ratio in the container at a fuel-rich level that prevents combustion within the container if the container were to be placed near an ignition source or if an ignition source were to somehow enter the container. The container can also include other safety features such as, for example, a flash suppressor located at the fill opening, an extra wide fill opening, and/or an easily controllable dispensing spout. When a flash suppressor is employed, the perforations in the flash suppressor can be configured to retain fuel therein after fuel has been dispensed from the container and the flash suppressor is no longer submerged in fuel.

A portable fuel container configured to prevent liquid fuel contained therein from being entirely emptied from the container. The amount of liquid fuel retained in the container can be sufficient to maintain a fuel-to-air ratio in the container at a fuel-rich level that prevents combustion within the container if the container were to be placed near an ignition source or if an ignition source were to somehow enter the container. The container can also include other safety features such as, for example, a flash suppressor located at the fill opening, an extra wide fill opening, and/or an easily controllable dispensing spout. When a flash suppressor is employed, the perforations in the flash suppressor can be configured to retain fuel therein after fuel has been dispensed from the container and the flash suppressor is no longer submerged in fuel.

The present invention includes systems, assemblies, and methodologies for inhibiting combustion within fluid containers, enhancing the safety of such containers. One aspect includes a novel base module from which assemblies of varying shape and size, suitable for disposing within a variety of different fluid containers, are created. In one embodiment, the base module is made from an expanded mesh which is rolled in a novel cylindrical configuration according to a novel methodology. In another embodiment, the base module may be combined with other base modules to form an assembly.