A method of designing a fire detection system including: determining a location of one or more fire detection devices within the building; and generating a map that displays the location of one or more fire detection device.

A hydro fire mitigation system is provided that is associated with a structure. The system employs a number of sensors that detect an oncoming fire, which directs a controller to initiate fluid flow through a number of sprinklers. The system is fully autonomous and does not require municipal water or power during use.

Certain aspects relate to an apparatus for fire protection to a peak of a roof of a structure including a fire-retardant conduit mounted to the peak of the roof. The fire-retardant conduit includes a channel having sidewalls, each sidewall including a top portion having a lip; a channel windbreak configured to cover the channel and the lip of the channel; and a fire-retardant source pipe coupling the fire-retardant conduit to a fire-retardant source to supply fire-retardant into the channel.

An irrigation recirculation and fire extinguishing system is provided that includes a water collection system, and a fluid conduit configured to receive water from the water collection system such that the water flows through the fluid conduit along a fluid flow path. A water distribution tank is configured to receive the water from the fluid conduit received from the water collection system, and a sprinkler head pump is configured to direct the water toward at least one sprinkler discharge nozzle. A dwelling pump is configured to direct the water toward at least one dwelling discharge nozzle that discharges water onto a dwelling.

An extinguishing system and method for extinguishing fires. The extinguishing system includes—a pump system for pumping extinguishing agent; one or more nozzles connected operatively to the pump system for the purpose of spraying extinguishing agent at a source of fire; a supply or inlet arranged on the pump system for the purpose of supplying extinguishing agent to the pump system; an extinguishing conduit with an extinguishing length arranged on the pump system for the purpose of supplying extinguishing agent to the at least one nozzle; and an extinguishing controller provided with an input system for inputting system data, including data about the extinguishing conduit, the pump system and the at least one nozzle. The extinguishing controller is configured to determine with the system data an operating pressure at or close to the at least one nozzle and thereby control the pump system.

The present disclosure concerns a fire spread-limiting assembly comprising a heat resistant covering; and a cooling fluid circulation assembly comprising: a cooling fluid source integrated to the heat resistant covering, one or more flexible fluid lines being part of the heat resistant covering, and a pump fluidly connected to said one or more flexible fluid lines and to the cooling fluid source and configured to circulate the cooling fluid within said one or more flexible fluid lines upon actuation. There is also disclosed a method for limiting a spread of a fire.

A personal fire-fighting system can extinguish fires in order to save structures such as homes or business buildings. The personal fire-fighting system includes a frame, a water pump system, a suction hose, a high-trajectory nozzle, a rotor sprinkler, and a length-adjustable tube. The frame protects and holds the water pump system, the length-adjustable tube, and the rotor sprinkler in place. The water pump system drives water from the suction hose in order to be outputted by the rotor sprinkler. The suction hose is a fluid conduit between a body of water and the water pump system. The high-trajectory nozzle increases the trajectory angle of water that is outputted by the rotor sprinkler. The rotor sprinkler rotates and outputs streams of water in order to cover large areas. The length-adjustable tube allows the rotor sprinkler to output water at higher areas if needed.

An automated roof sprinkler fire suppression system is disclosed. The system responds to heat and smoke around an exterior perimeter of the structure and supplies pressure during low municipal pressures without depleting fire hydrant pressures. The system includes multiple sprinkler heads disposed on a roof of the structure and optional additional sprinkler heads on a sidewall of the structure. A conduit communicates a water source with the multiple sprinkler heads to douse the roof and exterior of the building with water to prevent heat and embers from igniting the structure.

Embodiments of the present invention are related to an automated structure and curtilage protection system including a mechanical system hub, a piped network, a plurality of spray nozzles, and a remote user control portal. The mechanical system hub includes at least one of a control center, a pump, a pressure tank, a plurality of controllable valves, and a chemical injector assembly. The system is structured to autonomously take system action depending on a hierarchy of preprogrammed threat levels. The system is also structured to autonomously deliver water at set time intervals onto a structure and curtilage when instruction sets corresponding to relative threat levels have been activated. The system is further structured to autonomously deliver chemically infused water solely onto a structure's curtilage for a set time interval when instruction sets corresponding to a relative threat level have been activated.

A Silver Lining solar transfer module incorporates roof solar photovoltaic cells in a cased layer sandwiched between two water-handling layers. The bottom waste heat layer contains heat transfer pipes tuned for absorbing heat from the bottom of the photovoltaic layer and to dissipate heat into cool water pumped through the transfer pipes from ground level. The top cascade layer uses a casing transparent to solar radiation at the wavelengths used by the solar photovoltaic cells and containing a cascade of relatively cool water pumped from ground level, absorbing heat from the photovoltaic layer. The Silver Lining module is installed with a vertical slant, so that water is gravity fed from the top edge to the bottom edge in the waste heat layer and cascade layer. Fire sprinklers are incorporated into the plumbing of a system of Silver Lining solar transfer modules and provide protection to the roof in fire emergencies.