A system for providing inerting gas to a protected space is disclosed. The system includes an electrochemical cell that produces inerting gas on a cathode fluid flow path, and delivers it to an inerting gas flow path is disposed in operative fluid communication with the cathode fluid flow path outlet and the protected space. The inerting gas flow path includes a condenser that receives inerting gas from the cathode fluid flow path outlet, and also includes a pressure control device configured along with the pressurized gas source to provide a pressure at the condenser greater than ambient pressure.

A control system for use with a fire-fighting device includes a remote component having a touch sensitive screen configured to receive a user-requested parameter of fluid and to display a plurality of indicators associated with the fire-fighting device. The control system also includes a base component including a programmable logic controller having predefined logic stored thereon. The base component automatically controls operation of the pump based on the predefined logic and the user-requested parameter of fluid. The remote component receives signals from the base component and presents, via the touch sensitive screen, at least one of a first of the plurality of indicators indicative of a water volume associated with a first water source stored at a fire fighting device, and a second of the plurality of indicators indicative of a water pressure associated with a second water source remote from the fire-fighting device.

A control system for use with a fire-fighting device includes a remote component having a touch sensitive screen configured to receive a user-requested parameter of fluid and to display a plurality of indicators associated with the fire-fighting device. The control system also includes a base component including a programmable logic controller having predefined logic stored thereon. The base component automatically controls operation of the pump based on the predefined logic and the user-requested parameter of fluid. The remote component receives signals from the base component and presents, via the touch sensitive screen, at least one of a first of the plurality of indicators indicative of a water volume associated with a first water source stored at a fire fighting device, and a second of the plurality of indicators indicative of a water pressure associated with a second water source remote from the fire-fighting device.

A fire apparatus includes an engine, a water tank configured to store water, an agent tank configured to store a fire suppressing agent, a fuel tank configured to store a fuel used to power the engine, and a processing circuit. The processing circuit is configured to monitor the fluid level data indicating at least one of a water level within the water tank, a fire suppressing agent level within the agent tank, and a fuel level within the fuel tank; monitor fault data indicating any active faults of the fire apparatus; monitor maintenance data indicating whether maintenance is due; monitor exercise data indicating an elapsed time since the fire apparatus was last exercised; determine a readiness score based on the fluid level data, fault data, maintenance data, and exercise data; and at least one of transmit the readiness score to (i) a display device and (ii) a remote server.

Compounds with fire extinguishing properties having the formula: ##STR00001##
wherein R.sup.1 is CR.sup.5R.sup.6R.sup.7 or CR.sup.5R.sup.6CR.sup.8R.sup.9R.sup.10 as well as fire extinguishing units including one or more of the compounds.

An example of a fire-extinguishing apparatus includes a plate member including a convex front surface configured to be exposed to fire, and a concave rear surface. The apparatus includes a handle member including a first end and a second end. The handle member is configured to push the plate member over the fire. A joint connects the first end of the handle member to the concave rear surface. In one example of using the apparatus, the apparatus can be placed on a location on a line of fire. By pushing the apparatus along the line of fire, the fire along the line can be mowed.

Aspects of the present disclosure relate to systems and methods for automated fire detection, such as in aircraft galleys, or other areas where power sources may result in fire or smoke. The system includes one or more detectors to monitor for smoke or fire in an aircraft galley. Upon detection of smoke or fire, a signal is sent from the one or more detectors to a controller. In response to the incoming signal, the controller sends a signal to a galley power source. The signal provided to the galley power source ceases the application of power to one or more devices located in the galley, extinguishing the source of the fire or smoke. The controller may also send a notification signal to alert the crew to the potential fire hazard. A method of operation is also disclosed.

Aspects of the present disclosure relate to systems and methods for automated fire detection, such as in aircraft galleys, or other areas where power sources may result in fire or smoke. The system includes one or more detectors to monitor for smoke or fire in an aircraft galley. Upon detection of smoke or fire, a signal is sent from the one or more detectors to a controller. In response to the incoming signal, the controller sends a signal to a galley power source. The signal provided to the galley power source ceases the application of power to one or more devices located in the galley, extinguishing the source of the fire or smoke. The controller may also send a notification signal to alert the crew to the potential fire hazard. A method of operation is also disclosed.

Disclosed are fire extinguishants comprising from about 20% to about 80% by weight of 1-chloro-3,3,3-trifluoropropene (HFO-1233zd) and from about 20% to about 80% by weight of 1,1,1,2,2,4,5,5,5-nonafluoro-4-(trifluoromethyl)-3-pentanone (FK5-1-12), and to methods, systems and containers which use the fire extinguishants.