Ember Armor Wildfire Protection Sprinklers offer a versatile and comprehensive defense against wildfires, easily mountable on various structures like homes, roofs, and trees with just five screws. Upon installation, it establishes a hydration bubble around the protected area, extinguishing embers and creating a wet perimeter to deter ground fires. The innovative powder-coated stainless steel and brass bracket, with a high melting point, ensures year-round durability, shedding rain and sprinkler water to safeguard the structure. The customizable bracket supports different sprinkler heads, with a filter-free option to prevent clogging. Designed for homeowner convenience, it eliminates the need for seasonal setup and features color options for aesthetic appeal. Additionally, the kit includes a firefighter alert sign, mounted at the property entrance, ensuring heightened awareness of wildfire protection measures.

A system for forming and maintaining GPS tracked and mapped environmentally-clean chemical-based fire protection zones formed over property and ground surfaces in and about a neighborhood of homes, that proactively inhibit fire ignition and flame spread when exposed to wild fire. The system includes a GPS-tracking anti-fire (AF) liquid spraying system wirelessly connected to a wireless communication network supporting a network database. The GPS-tracked anti-fire liquid spraying system is used to spray particular GPS-specified ground surfaces in and about the neighborhood, with an environmentally-clean anti-fire chemical liquid so to form environmentally-clean chemical fire protection zones over the GPS-specified property surfaces, while generating GPS-coordinate and time/date stamped data records pertaining to the application of the environmentally-clean anti-fire chemical liquid spray during the formation of the environmentally-clean chemical fire protection zones. The GPS-coordinate and time/date stamped data records are transmitted over the wireless communication network for storage in the network database. A mobile computing system is used to access the GPS-coordinate and time/date stamped data records from the network database, relating to the formation of the GPS-specified environmentally-clean chemical fire protection zones, so as to verify that the GPS-specified environmentally-clean chemical fire protection zones were formed at the GPS-specified property surfaces on the particular date, to proactively inhibit fire ignition and flame spread when exposed to wild fire.

A neighborhood of buildings or homes, provided with a system for forming and maintaining GPS tracked and mapped environmentally-clean chemical-based fire protection zones formed over property and ground surfaces in and about the neighborhood of homes, that proactively inhibit fire ignition and flame spread when exposed to wild fire. The system includes a GPS-tracking anti-fire (AF) liquid spraying system wirelessly connected to a wireless communication network supporting a network database. The GPS-tracked anti-fire liquid spraying system is used to spray particular GPS-specified ground surfaces in and about the buildings and neighborhood, with an environmentally-clean anti-fire chemical liquid so to form environmentally-clean chemical fire protection zones over the GPS-specified property surfaces, while generating GPS-coordinate and time/date stamped data records pertaining to the application of the environmentally-clean anti-fire chemical liquid spray during the formation of the environmentally-clean chemical fire protection zones. The GPS-coordinate and time/date stamped data records are transmitted over the wireless communication network for storage in the network database. A mobile computing system is used to access the GPS-coordinate and time/date stamped data records from the network database, relating to the formation of the GPS-specified environmentally-clean chemical fire protection zones, so as to verify that the GPS-specified environmentally-clean chemical fire protection zones were formed at the GPS-specified property surfaces on the particular date, to proactively inhibit fire ignition and flame spread when exposed to wild fire.

There is provided networks, systems and displays for providing derived data and predictive information for use in emergencies; and in particular for use in wildfire emergencies. More particularly, there is provided systems, equipment and networks having a control system having an operation control command plan for performing an operation plan. in embodiments the operation plan can be a hydration plan, a lockout plan, a low line pressure plan, an adjacent structure based plan, an auto-activation notice with default activation plan. In an embodiment there is provided a parcel by parcel control and optimization of the EFMS for a particular area.

There is provided a networked based coordinated wildfire management system for the protection of a community of structures from a wildfire. The systems have hydration plans that provide for the minimal use of water to protect the structures for the wildfire. The hydration plans can be automated adaptive hydration plans that the control system develops to address a specific wildfire threat, and these plans are developed in real time. The systems can have sprinkler towers that are place along roadway and near structures to implement the hydration plan and protect evaluation routes. The systems provide an integrated approach to protection an entire community.

A vent as described herein provides for a fire and ember barrier border incorporated around the perimeter of vent flashing and/or sub-flashing. In the event that a portion of vent flashing separates from the underlayment to which it was originally attached, it creates a secondary air path between the deck and the flashing and the fire and ember barrier border will prevent fire and embers from entering the secondary air path and ultimately the building.

A fire suppression device has a pump and spray nozzle in hydraulic communication with the interior environment of a swimming pool. The pump and spray nozzle are capable of remote and automatic operation by wireless sensors configured to direct a stream of liquid upon an adjacent fire. The device may be powered via solar power.

A controller responds to an alert from a remote alert system and responds to an AI unit that detects a fire signature, and, in response, sends signals to fire suppression equipment to defend a structure against fire. A delivery device system may include delivery devices that are capable of spraying water and/or retardant at a structure or area to defend against fire. The system may act autonomously to defend against wildfires. The system includes a base station accessible by a user device to take control of the system. Alternatively, a central monitoring system may access the base station to control the system in addition to or instead of the user. In an embodiment, the system automatically sprays water or retardant prior to the outbreak of a fire. The system may optically detect embers landing on a structure or area being defended and sprays the embers with retard and/or water.

A system and methods are provided for community outdoor fire protection comprising: receiving indicators of a current fire, and responsively determining a level of the current fire risk for each of multiple endpoints of a shared water supply; determining a relative duty cycle for operating each endpoint according to a fire risk; receiving a water pressure measurement of the shared water source and determining a maximum number of concurrent endpoints to operate; accordingly allocating operation of each endpoint to a set of time slots; and activating the multiple endpoints to turn on respective water flows according to the time slot allocation.

A fire detection and suppression system operates in independent autonomous modes or under human command. Optical, thermal and laser based sensors detect fire conditions. Anemometers and thermometers detect environmental conditions, allowing the system to adjust the flow of fluid from the system to the targeted flame or condition. Algorithmic analysis of the input data in connection with such preselected thresholds permits rapid detection of fire conditions and in automatic modes triggers a suppression response. A feedback loop enhances adjusts for dynamic flame and environmental conditions.