A method for extinguishing fires which includes the following phases: a first phase wherein a projectile of compact crushed ice is produced, with a volume between 0.5 liters and 2 liters, a second phase wherein the projectile is placed on a shuttle that fires it over the area in flames to be put out, and a third phase wherein successive projectiles are launched until a shower of compact crushed ice projectiles is formed with at least 30 liters per square meter per hour. A projectile for extinguishing fires is also disclosed.

Disclosed herein is a fire extinguishing bullet system for launching, which is capable of effectively extinguishing a fire generated at a place that is difficult to access by a person by loading a fire extinguishing bullet that generates a fire extinguishing gas having a fire extinguishing effect onto a projectile, throwing the fire extinguishing bullet loaded at a long distance from a firing point to a specific distance, and discharging the fire extinguishing gas after the fire extinguishing bullet reaches the firing point.

A fire retarding missile and method of use having a unitary construction and containing a propulsion system as well as fire treatment materials. Dispersal of the materials can be initiated both actively and passively, with passive dispersal allowing for a fail safe mode of operation. The fire treatment materials are of the oxygen reduction type, and the method of the invention is to target the hot spot of a fire in order to reduce the spread and intensity thereof. An active guidance system may be of the heat seeking type, or may alternatively be remote controlled video. Stabilizer and guidance fins are controlled in response to signals from the guidance system in order to precisely position the device. In one embodiment, the device can be broken down to allow for easy replacement of certain components. The device can be modified for use in fires of specific heat ranges by using nose cones designed to melt in a respective heat range.

The present invention features systems, methods and devices directed to fire suppression and/or extinguishment using solid carbon dioxide and/or liquid or aqueous hydrogen. Systems and methods of deployment and/or dispersal of carbon dioxide and hydrogen (which would form water at its deployment location) are contemplated. The present invention also contemplates method(s) of fire suppression and/or extinguishment which may include the steps of: carbon dioxide canister deployment, formation of a carbon dioxide curtain and hydrogen deployment and/or dispersal.

The present invention relates to fire safety devices, and particularly to a fire extinguishing device that can be safely deployed into difficult to reach areas. In particular, this invention relates to a device that disperses fire fighting Dry chemical powder composition through the use of an impact force. When a fire breaks out, simply throw the device towards the fire. It will impact naturally in contact with any surface and will activate/blast in instant and the fire is extinguished. No pin or spare parts or training is required.

A passive fire extinguisher for indoor and outdoor use. The fire extinguisher comprises a three-dimensional body housing an extinguishing powder, a fuse, and an explosive. The fire extinguisher is removably placed in a fire-risk location and can be paired with additional apparatuses. A fire ignites the extinguisher's fuse, induces combustion, causes the apparatus to open and release the fire extinguishing powder, smothering the fire.

The present disclosure provides generally for a system and method for planting flora, fauna, and dispersing various organisms through drone delivery. The system may comprise of a drone with seedling box that may hold and drop the pods containing flora or fauna. The seedling box may hold the pods with the flora or fauna in them and at specific intervals drop the pod with the flora or fauna. The seedling box may also hold various organisms or other materials and drop these organisms or materials when directed. A seedling box may comprise loading mechanism and deploying mechanism to facilitate accurate, timely deployment of the pods containing the seedlings. A pod may comprise a weighted tip with hollow cavity for seedling placement and a vertical rod for securing seedling during deployment. Where the system comprises uneven number of seedlings, seedling box may include counterweights to provide stability in configured flight patterns for duration of seedling deployment.

The application discloses a control system of a fire fighting truck for high-rise and super high-rise building firefighting, comprising: a command control equipment (2), a launch control equipment (3), a turret control apparatus (8), and a photoelectric detection equipment (9), wherein, the photoelectric detection equipment (9) comprises: an installing shell, a power supply, a white light zoom camera, an infrared camera, a laser rangefinder, and an integrated processing unit, wherein the white light zoom camera is connected to the installing shell via screws, the infrared camera is connected to the installing shell by using a screw, the laser rangefinder is connected to the installing shell by using a screw, the power supply interface of the white light zoom camera is connected to the power supply by using a wire, the power supply interface of the infrared camera is connected to the power supply by using a wire, the power supply interface of the laser rangefinder is connected to the power supply by using a wire, the data interface of the white light zoom camera is connected to the integrated processing unit by using a wire, the data interface of the infrared camera is connected to the integrated processing unit by using a wire, and the data interface of the laser rangefinder is connected to the integrated processing unit by using a wire.

The invention discloses a fire fighting truck applicable to high-rise and super high-rise building fire suppression, comprising a truck chassis (1), a command control equipment (2), an launch control equipment (3), an equipment compartment (4), an launching apparatus (5), an ejection device (6), a fire extinguishing bomb (7), a turret control apparatus (8) and a photoelectric detection equipment (9), wherein, the command control equipment (2) and the launch control equipment (3) are arranged in the co-pilot position of the cab of the truck chassis (1); the equipment compartment (4) is arranged behind the cab and is fixed on the truck chassis (1) with bolts; the launching apparatus (5) is arranged on the truck chassis (1) and is fixed with screws; the ejection device (6) is arranged and fixed on the launching apparatus (5); the fire extinguishing bomb (7) is arranged within the ejection device (6); the turret control apparatus (8) is distributed on the truck chassis and the launching apparatus for accomplishing the actions of leveling the truck body and controlling the launching apparatus.

An intelligent method of fighting a forest or brush fire in a remote area including the steps of targeting the remote area by means of an aerial surveillance device and generating a map of the forest or brush fire. The method also includes the step of delivering a plurality of containers to the remote area. Each container contains a fire retardant material and an explosive device. Each of container has a GPS locating device. a position transmitting device and a remote detonating device electronically coupled to the explosive device. The method further includes the steps of locating the position of each container, selecting according to a plan which of the containers are to be selected to be detonated and remotely detonating the selected containers. The forest or brush fire can be either extinguished or contained in an intelligent manner. An individual generates the plan according to which of said containers are to be selected to be detonated in order to maximize effectiveness of said intelligent method.