Devices, systems, and methods for explosion resistance include an explosion-resistant enclosure and a lid assembly. The lid assembly includes a lid for enclosing an opening of the explosion-resistant enclosure, and a graphical display assembly for presenting visual information regarding the analysis equipment.

Devices, systems, and methods for explosion resistance include an explosion-resistant enclosure and a lid assembly. The lid assembly includes a lid for enclosing an opening of the explosion-resistant enclosure, and a graphical display assembly for presenting visual information regarding the analysis equipment.

A system for inerting a biomass feed assembly the system including a combustion chamber operably connected to the biomass feed assembly to receive a biofuel, the combustion chamber operable to combust the biofuel and generate a flue gas therefrom and a conduit operably coupled to at least one of the combustion chamber and an inert gas source, and the biomass feed assembly, the conduit operable to carry a gas to the biomass feed assembly. The gas sweeps dust generated in at least the gravity chute assembly toward the combustion chamber and the gas maintains an oxygen partial pressure or concentration in the at least a portion of the biomass feed assembly below a selected threshold sufficient to suppress ignition.

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.

The invention relates to a fire-retardant bag (1) for accommodating flammable devices or energy stores, in particular lithium-ion batteries, having an interior (10) for accommodating such a device or energy store and having a wall surrounding the interior (10). The wall is flexible and of multi-layer design with at least one layer of fire-retardant material which withstands a temperature emanating from the interior (10) of >800° C. According to the invention, the wall has a layered structure in the form of a layer of textile material and at least one following layer of silica fibre material or silica woven fabric material.

The invention relates to a fire-retardant bag (1) for accommodating flammable devices or energy stores, in particular lithium-ion batteries, having an interior (10) for accommodating such a device or energy store and having a wall surrounding the interior (10). The wall is flexible and of multi-layer design with at least one layer of fire-retardant material which withstands a temperature emanating from the interior (10) of >800° C. According to the invention, the wall has a layered structure in the form of a layer of textile material and at least one following layer of silica fibre material or silica woven fabric material.

Multiple robotic monitors are located in a hydrocarbon storage or transport facility. Each robotic monitor is communicably coupled to other robotic monitors and includes a heat sensor configured to detect heat emitted by a hydrocarbon tank of the hydrocarbon storage or transport facility. A controller is communicably coupled to the heat sensor and configured to generate a heat signature based on the heat detected by the heat sensor. A pump is communicably coupled to the controller and configured to exert pressure on a fire retardant, responsive to the generation of the heat signature by the controller. An outlet is mechanically coupled to the pump and configured to discharge the fire retardant at the hydrocarbon tank.

A fire protection sprinkler system includes a horizontal barrier that covers two adjacent racks, and the vertical flue space between the racks. The horizontal barrier is provided at a predetermined height, and has a width that is at least equal to a width of the rack, and a depth that is at least equal to a sum of a depth of the rack, a depth of the other rack, and a depth of the vertical flue space. In addition, the horizontal barrier is a sheet having one or more apertures. The system also includes a rack level fire protection sprinkler connected to a fluid supply conduit, and being disposed in the vertical flue space below the horizontal barrier. The rack level sprinkler has a K-factor of 11.2 gpm/(psi).sup.1/2 or greater, and is vertically spaced from commodities stored on the rack and the other rack covered by the horizontal barrier.

A fire protection sprinkler system includes a horizontal barrier that covers two adjacent racks, and the vertical flue space between the racks. The horizontal barrier is provided at a predetermined height, and has a width that is at least equal to a width of the rack, and a depth that is at least equal to a sum of a depth of the rack, a depth of the other rack, and a depth of the vertical flue space. In addition, the horizontal barrier is a sheet having one or more apertures. The system also includes a rack level fire protection sprinkler connected to a fluid supply conduit, and being disposed in the vertical flue space below the horizontal barrier. The rack level sprinkler has a K-factor of 11.2 gpm/(psi).sup.1/2 or greater, and is vertically spaced from commodities stored on the rack and the other rack covered by the horizontal barrier.

Ignition-quenching covers are configured to quench an ignition event in a combustible environment triggered by an ignition source associated with an ignition-risk structure. Ignition-quenching covers comprise a porous body that includes two or more porous elements and are configured to cover the ignition-risk structure, wherein the ignition-risk structure is associated with a potential ignition source that may produce the ignition event in the combustible environment. The porous body defines passages sized to quench the ignition event. Methods comprise installing a porous ignition-quenching cover over an ignition-risk structure to prevent bulk combustion, e.g., of a fuel vapor in a fuel tank, due to an ignition event associated with the ignition-risk structure.