A fire suppression system in which the water supply line is fitted with repeating arrays or groups of sprinkler heads. Each array is composed of at least two side-discharge sprinklers. The side-discharge sprinklers in each array are aimed so that their coverage areas point in opposite directions. Each side-discharge sprinkler includes a lateral heat shield. The lateral heat shield has a concave heat-concentering side that focuses radiant heat toward the sprinkler's trigger, and a convex heat-scattering side that disperses radiant heat away from the trigger. In some embodiments, the array can include one or more vertical-discharge sprinklers. The vertical-discharge sprinkler may include a heat collector to facilitate early activation of its trigger. The fire suppression system is advantageous in high-challenge applications like facilities where large quantities of combustible items are stored in close proximity, such as in warehouses and attics.

Fire extinguishing equipment includes an ORC cycle configured to circulate a fire extinguishing agent as a working medium and at least one fire extinguishing agent supply line. The ORC cycle includes a condenser provided on the ORC cycle and configured to liquefy a gaseous fire extinguishing agent that is the fire extinguishing agent in a gas state, a booster pump provided on a downstream side of the condenser on the ORC cycle and configured to pressurize a liquid fire extinguishing agent obtained by liquefying the gaseous fire extinguishing agent in the condenser, a vaporizer provided on a downstream side of the booster pump on the ORC cycle and configured to vaporize the liquid fire extinguishing agent, and an expansion turbine provided on a downstream side of the vaporizer and on an upstream side of the condenser on the ORC cycle and configured to be driven by a gaseous fire extinguishing agent obtained by vaporizing the liquid fire extinguishing agent. The at least one fire extinguishing agent supply line is configured to extract at least one of the liquid fire extinguishing agent or the gaseous fire extinguishing agent from the ORC cycle and supply the at least one of the liquid fire extinguishing agent or the gaseous fire extinguishing agent to at least one fire prevention object.

Fire extinguishing equipment includes an ORC cycle configured to circulate a fire extinguishing agent as a working medium and at least one fire extinguishing agent supply line. The ORC cycle includes a condenser provided on the ORC cycle and configured to liquefy a gaseous fire extinguishing agent that is the fire extinguishing agent in a gas state, a booster pump provided on a downstream side of the condenser on the ORC cycle and configured to pressurize a liquid fire extinguishing agent obtained by liquefying the gaseous fire extinguishing agent in the condenser, a vaporizer provided on a downstream side of the booster pump on the ORC cycle and configured to vaporize the liquid fire extinguishing agent, and an expansion turbine provided on a downstream side of the vaporizer and on an upstream side of the condenser on the ORC cycle and configured to be driven by a gaseous fire extinguishing agent obtained by vaporizing the liquid fire extinguishing agent. The at least one fire extinguishing agent supply line is configured to extract at least one of the liquid fire extinguishing agent or the gaseous fire extinguishing agent from the ORC cycle and supply the at least one of the liquid fire extinguishing agent or the gaseous fire extinguishing agent to at least one fire prevention object.

Methods and systems for sprinkler system (100) diagnostics are provided. Aspects include increasing, by a controller (115), a fluid pressure in a pipe (14) to a first pressure, wherein the pipe (14) is coupled to at least one sprinkler (40), receiving, from a sensor (50), first sensor data associated with a moving portion (210) of the least one sprinkler (40), wherein the first sensor data includes a first movement distance (250) of the moving portion (210) of the at least one sprinkler (40), and enacting a first action based at least in part on the first movement distance (250) being less than a threshold.

An example system for suppressing a fire condition in an aircraft includes a supply of fire suppressant agent on-board the aircraft, a conduit coupled to the supply of fire suppressant agent and configured to carry fire suppression agent, an inlet located downstream of the conduit that is coupled to the conduit and is configured to be attached to a cargo container in the aircraft to deliver the fire suppression agent directly into the cargo container, a valve connected to the conduit between the supply of fire suppressant agent and the inlet, a detector located inside the cargo container, and a computer controller in communication with the valve and in communication with the detector, and controlling operation of the valve for delivery of the fire suppression agent into the cargo container based on an output received from the detector.

A system and method for providing a wildfire home protection water blanket is disclosed. The system includes a plurality of water blanket distributors attached to and integrated into the fascia of a building, a water source and control components for connecting the plurality of water blanket distributors to a water source, and a water line connecting the plurality of water blanket distributors to the water valve, the water line receives water from the water valve upon receiving a user command. The plurality of water blanket distributors comprise an enclosure attached to and integrated into the fascia of the building under the eaves, a plurality of water distribution nozzles and a water line. The water source and control components comprise the water valve and a WIFI-enabled controller.

A system and method for providing a wildfire home protection water blanket is disclosed. The system includes a plurality of water blanket distributors attached to and integrated into the fascia of a building, a water source and control components for connecting the plurality of water blanket distributors to a water source, and a water line connecting the plurality of water blanket distributors to the water valve, the water line receives water from the water valve upon receiving a user command. The plurality of water blanket distributors comprise an enclosure attached to and integrated into the fascia of the building under the eaves, a plurality of water distribution nozzles and a water line. The water source and control components comprise the water valve and a WIFI-enabled controller.

A fire protection system is provided for a space having a pitched roof constructed of structural members extending from a ridgeline to an eave, with respective channels therebetween. A first row of sprinklers is mounted to a first branch line extending generally parallel to the ridgeline. Each sprinkler is positioned within a respective channel, with consecutive sprinklers spaced apart having no less than one, and no more than five, channels therebetween. A second row of sprinklers, downslope from the first row, is mounted to a second branch line extending generally parallel to the first branch line. Each sprinkler thereof is positioned within a respective channel, with consecutive second row sprinklers spaced apart as in the first row. Each second row sprinkler is also placed within a different channel from each first row sprinkler. A farthest number of channels between a first row sprinkler and a second row sprinkler is three.

A fire protection system is provided for a space having a pitched roof constructed of structural members extending from a ridgeline to an eave, with respective channels therebetween. A first row of sprinklers is mounted to a first branch line extending generally parallel to the ridgeline. Each sprinkler is positioned within a respective channel, with consecutive sprinklers spaced apart having no less than one, and no more than five, channels therebetween. A second row of sprinklers, downslope from the first row, is mounted to a second branch line extending generally parallel to the first branch line. Each sprinkler thereof is positioned within a respective channel, with consecutive second row sprinklers spaced apart as in the first row. Each second row sprinkler is also placed within a different channel from each first row sprinkler. A farthest number of channels between a first row sprinkler and a second row sprinkler is three.

An electronic device may obtain a water pressure measurement associated with a charged fire sprinkler system. The electronic device may determine obtained water pressure measurement is indicative of a slow leak or indicative of the fast leak. The electronic device may, in response to determining that the water pressure is indicative of a slow leak, initiate a system recharge in which a fire pump of the fire sprinkler system is activated to attempt to recharge the water pressure.