A nozzle positioning includes a primary pole, a grasping element supported on the upper end of the pole and configured to secure the pole to a surface, and a nozzle mount supported on the grasping element. The nozzle mount is configured to support a nozzle in a substantially horizontal position, and may allow the nozzle to rotate and swivel. The grasping element may be in the form of a hook configured to fit over a window ledge or similar structure.

A safety ladder for protecting a lineman or firefighter from a flash fire. The ladder has the appearance of a conventional ladder but include fluid conduits that allow for dispensing of a fire suppressants to be sprayed over an individual using the ladder should a fire erupt. The rungs of the ladder have spray nozzles located along the bottom of the rung so that they do not interfere with normal use of the ladder. A pressurized container of fire suppressants is coupled to the ladder, through a battery powered solenoid valve. The solenoid valve can be operated by the individual using the ladder by use of a triggering device, or remotely by an individual positioned apart from the ladder by a remote triggering device. The triggering device can be operated electrically or by radio frequency, can be temperature sensitive, or can be manually bypassed.

A safety ladder for protecting a lineman or firefighter from a flash fire. The ladder has the appearance of a conventional ladder but include fluid conduits that allow for dispensing of a fire suppressants to be sprayed over an individual using the ladder should a fire erupt. The rungs of the ladder have spray nozzles located along the bottom of the rung so that they do not interfere with normal use of the ladder. A pressurized container of fire suppressants is coupled to the ladder, through a battery powered solenoid valve. The solenoid valve can be operated by the individual using the ladder by use of a triggering device, or remotely by an individual positioned apart from the ladder by a remote triggering device. The triggering device can be operated electrically or by radio frequency, can be temperature sensitive, or can be manually bypassed.

A fire-fighting system includes a fluid monitor that includes a fluid outlet and is selectively moveable between a stowed configuration and a deployed configuration. The system further includes a controller configured to receive a request to direct a fluid flow from the fluid monitor towards a desired target area, determine whether the fluid monitor is in a proper position to direct the fluid flow toward the target area, and control the fluid flow from the fluid monitor through the fluid outlet based on the determination.

A fire-fighting system includes a fluid monitor that includes a fluid outlet and is selectively moveable between a stowed configuration and a deployed configuration. The system further includes a controller configured to receive a request to direct a fluid flow from the fluid monitor towards a desired target area, determine whether the fluid monitor is in a proper position to direct the fluid flow toward the target area, and control the fluid flow from the fluid monitor through the fluid outlet based on the determination.

A fire suppressant system is a device that uses steam/super-heated water to suppress and put out fires rather than the traditional water method. The invention uses steam/super-heated water under high pressure to blow out and suppress the fire. The wet pressurized steam/super-heated water blows out the fire and the pressure removes (displaces) the oxygen and spark needed for the fire to continue burning. The wet steam/super-heated water works much like water to suppress and put out the fire but the additional benefits of the pressure help to reduce the fuel (air and spark) for the fire as well.

A fire suppressant system is a device that uses steam/super-heated water to suppress and put out fires rather than the traditional water method. The invention uses steam/super-heated water under high pressure to blow out and suppress the fire. The wet pressurized steam/super-heated water blows out the fire and the pressure removes (displaces) the oxygen and spark needed for the fire to continue burning. The wet steam/super-heated water works much like water to suppress and put out the fire but the additional benefits of the pressure help to reduce the fuel (air and spark) for the fire as well.

A rapid deployment boom-mounted sprinkler gun is an apparatus that allows for unmanned dispersal of fire extinguishing substance from a boom of a mobile crane. The apparatus includes a mounting housing, a fastening mechanism, an at least one imaging device, a sprinkler gun, a water-receiving tube, a wireless communication device, and a power source. The mounting housing is mounted to the boom and the sprinkler gun is rotatably mounted onto a top surface of the mounting housing. The water-receiving tube is in fluid communication with the sprinkler gun and an external water supply to discharge fire extinguishing substance. The imaging device is externally mounted to a front surface of the mounting housing in order to provide a live feed. The wireless communication device is electronically connected to the imaging device in order to broadcast the live feed to an external control unit.

A firefighting monitor includes logic circuitry for determining the reaction force caused by the flow of firefighting fluid therethrough. The reaction force may be communicated to structures remote from the monitor for taking appropriate actions in response to the reaction forces exceeding one or more criteria. The monitor may also use flow and nozzle data for calculating a reach of the stream of the fluid, and may transmit this reach data to a remote location. The monitor may also utilize multiple pressure sensor transducers positioned inside the monitor for determining the rate of fluid flow, rather than a paddle wheel-type sensor.

A firefighting monitor includes logic circuitry for determining the reaction force caused by the flow of firefighting fluid therethrough. The reaction force may be communicated to structures remote from the monitor for taking appropriate actions in response to the reaction forces exceeding one or more criteria. The monitor may also use flow and nozzle data for calculating a reach of the stream of the fluid, and may transmit this reach data to a remote location. The monitor may also utilize multiple pressure sensor transducers positioned inside the monitor for determining the rate of fluid flow, rather than a paddle wheel-type sensor.