The present invention discloses a cooling type dry powder fire extinguishing agent and a preparation method and application thereof, which belongs to the technical field of fire control. Through a static mixing technology, an aqueous solution and a solid hydrophobic material are dispersed and mixed efficiently to form a cooling type dry powder fire extinguishing agent. The fire extinguishing agent is a micron solid particle of the aqueous solution wrapped by the hydrophobic material microscopically, and is in a dry powder state macroscopically, which can significantly reduce the electrical conductivity of the fire extinguishing agent. Meanwhile, a field rapid preparation method is adopted, which can realize real-time preparation. The preparation method is simple and efficient. The technology can be used for fighting a battery fire, has significant cooling and anti-reignition effects and can avoid the problem of electrical conduction of a traditional water-based fire extinguishing agent.

A lighted jet assembly for through hole mounting to a panel in a bathing installation. In an exemplary embodiment, the assembly includes a jet body configured for mounting in a hole formed in the bathing installation panel. A light receptacle is formed with the jet body, the light receptacle configured to receive a light source element. A jet barrel assembly includes a hollow barrel structure configured for insertion into the jet body channel through the open second end of the jet body. A blind structure includes a hollow cylindrical portion having at a first end a flange portion extending over a limited angular extent, and a second end configured to be secured within the open interior region of the jet barrel structure. The blind structure is fabricated of an opaque material, and configured for rotation with the jet barrel assembly relative to the jet body.

Various concepts are provided for suppressing a fire condition in an aircraft. In one embodiment, the presence of a fire condition in an aircraft is detected. After such a detection, extinguishing agents can be dispensed and/or certain areas of the aircraft can be depressurized.

An ice slurry firefighting system includes a water tank for receiving and storing water from a water source. A water pump is connected to the tank and pumps water to a valve. The valve selectively directs the pumped water to one or both of a slurry generation unit and a pump panel. The slurry generation unit includes a condenser, an evaporator, and a compressor that remove heat from water supplied by the tank passing over evaporator coils to produce an ice slurry mixture. The pump panel houses a system controller and a valve tap for engaging a fire hose and nozzle. The system controller operates the pump, the valve, the slurry generation unit, and a ratio control valve to dispense any ratio of water and ice slurry through the hose and nozzle. A generator provides power to the system components.

The present invention provides a fire extinguisher capable of easily installing a thinly molded fire extinguishing agent. A fire extinguisher of the present invention comprises a fire extinguishing agent layer that generates aerosol by combustion, a first plate covering a first surface of the fire extinguishing agent layer and having a blowout aperture for the aerosol, and a second plate covering a second surface of the fire extinguishing agent layer, which is opposite to the first surface. An edge of the first plate and an edge of the second plate may be connected to each other. And, a peripheral wall extending toward the second plate may be provided at the edge of the first plate.

A ratio controller includes a housing defining a mixing chamber. The housing has a water inlet configured to receive water from a water supply, an agent inlet configured to receive agent from an agent supply, an outlet configured to output an agent-water solution, a first pressure port extending through a sidewall of the housing at a first position proximate the water inlet, and a second pressure port extending through the sidewall of the housing at a second position proximate the mixing chamber.

A method as well as a liquid mixing system provide a liquid-foam mixture by mixing water with at least one additive. The liquid mixing system includes a water pressure source, an additive reservoir unit, an air compressor unit with a compressor and a drive device, a first and second mixing device, a discharging unit, and multiple different line networks for the respective media. The drive device is formed by a water engine or a water turbine, the water inlet of which is line-connected to the water pressure source.

The present invention refers to a method and system for ejecting carbon dioxide as High-Speed Jets with Sublimation. More specifically, the present invention describes a method and system capable of controlling and extinguishing fires from the CO.sub.2 ejected. In summary, the proposed method comprises the steps of removing CO.sub.2 in a first state (G) from the storage medium (2) and inserting the CO.sub.2 in first state (G) in the driver set (3); maintaining the insertion of CO.sub.2 in first state in the driver set (3) up to the equalization of the internal pressure between the storage medium (2) and the driver set (3); removing carbon dioxide in a second state (L) from the storage medium (2) and inserting the carbon dioxide in second state in the driver set (3) after the equalization of the pressure of the storage medium (2) and of the driver set; ejecting the CO.sub.2 in the form of high-speed jets with high content of CO.sub.2 in third state (S) through the driver set (3).

A method for producing a firefighting medium from water (W) and a liquefied gas, such as liquid nitrogen (LN) or liquid carbon dioxide, a fire extinguisher (200) for extinguishing a fire with the produced firefighting medium, and a method for extinguishing a fire with the produced firefighting medium, wherein the firefighting medium (FFM) is produced by spraying a pressurized jet of water (WJ) out of a nozzle (201) at a pressure of, for instance, at least 50 bar and mixing a proportion of liquid nitrogen (LN) into the jet of water (WJ).

A fluid system of a fire apparatus includes a water circuit, an agent circuit, and a ratio controller. The agent circuit includes an agent metering valve. The agent metering valve includes a flow restrictor having a non-uniform profile. The ratio controller is configured to (a) receive water from the water circuit and agent from the agent circuit and (b) provide an agent-water solution.