The invention relates to a toy for discharging a liquid. The toy comprises a discharging chamber adapted to receive a liquid from a liquid storage tank; an outlet arranged at the discharging chamber adapted to discharge at least some of the liquid received in the discharging chamber, the outlet being controllable by a covering mechanism movable between a closed position and an open position to thereby close and open the outlet, respectively; a movable member operably connected with the covering mechanism; wherein, in response to a triggering action of the toy, the movable member is movable from a first position to a second position thereby actuating the covering mechanism to move from the closed position to the open position, and at the same time, triggering discharge of the at least some of the liquid from the discharging chamber via the outlet.

The disclosure is premised on the realization that despite the apparent convenience, safety and effectiveness possible by use of a less-lethal weapon incorporated into the foregrip of a two-handed weapon, no major police department, government agency, or military unit deploys such a system. This deficiency can be remedied by the disclosed device, which comprises a less-lethal weapon system that employs industry-standard components, and is effective and easy to use. The disclosed invention mounts a standard-size incapacitant canister in the handgrip portion of a foregrip. The foregrip is secured to the firearm by a standard rail system, and uses standard trigger and safety configurations. The canister magazine allows for efficient loading and reloading of the incapacitant, and the canister mounting angle allows for effective use. Further, some embodiments of the invention may include an accessory mounting area in which a tactical flashlight or laser may be mounted.

A device responsive to an acceleration pulse event, the device including: a piezoelectric device configured to generate a voltage over a duration responsive to one or more acceleration pulse events; an electrical storage device configured to receive a portion of the generated voltage to accumulate a charge; an energy dissipating device coupled to the electrical storage device and configured to dissipate the accumulated charge following the one or more acceleration pulse events and not to substantially dissipate the accumulated charge during the one or more acceleration pulse events; and a voltage limiting device coupled to the electrical storage device and configured to limit the portion of the generated voltage applied to the electrical storage device to a predetermined limit.

A toy water gun having a stream interrupter or interrupter valve that is configured to periodically interrupt a flow of water that is discharged such that periodic bursts of water are delivered in a rapid succession. In one arrangement, a nozzle recovery chamber is provided in a nozzle opening of the nozzle is located that is directed to discharge water through the nozzle recovery chamber along a discharge axis. The stream interrupter is located in the nozzle recovery chamber between the nozzle opening and the discharge opening and is configured to periodically interrupt a flow of water from the nozzle along the discharge axis to the discharge opening to form the periodic bursts of water that are delivered from the discharge opening. Blocked water in the recovery chamber is recycled back to the supply tank. Use of the interrupter valve provides for interrupted discharges from the nozzle.

The present application relates to a water storage and jetting structure of toy water gun, comprising a housing, a water storage tank, a push rod and a trigger mechanism, in which the front part of the push rod is located inside the water storage tank, wherein the water storage and jetting structure of toy water gun further comprises an electric water jetting mechanism for driving the push rod to push forward water jetting and a spring for pulling back the push rod to return; wherein all of the water storage tank, the electric water jetting mechanism, the trigger mechanism, the push rod and the spring are disposed inside the housing, and a trigger end of the trigger mechanism is electrically connected to a signal input end of the electric water jetting mechanism; and wherein the rear of the push rod engageably contacts with the spring.

The present disclosure provides a portable wireless electroshock device. The portable wireless electroshock device includes (A) a fluid reservoir containing a conductive fluid and (B) a pump in fluid communication with the fluid reservoir and a terminal having an orifice. The orifice is operable to emit a fluid stream trajectory of the conductive fluid there-through, and the terminal is operable to deliver an electrical current through the fluid stream trajectory.

A liquid dispensing squirt device comprises a handle member, a barrel/loading member, and a spray nozzle member. The barrel/loading member connects to the top portion of the handle member, and contains an access hatch where the carbonated beverage is held. The liquid from the carbonated beverage can is dispensed through the spray nozzle with the can is pierced.

The invention is directed to a soap foam blaster device with a switch (or trigger) actuated pump to create soap foam using an aerator that is directed into a telescoping breech for pressurization thereof. A grip member with a nozzle on the free end thereof is attached to an inner member and actuated rearwardly to collapse the breech thereby launching the soap foam a substantial distance for targeted direction of soap foam for improved gameplay. For another blast of foam soap, the telescoping breech is expanded again by moving the grip member forwardly to slide out the inner member within the outer member whereby another volume of soap foam can be loaded into the breech for a subsequent launch. Alternatively, soap foam solution may be manually pumped from the soap solution reservoir by a manual telescoping pump configuration to create foam and then manually launched therefrom through the outer nozzle.

The invention relates to a device for controlling a liquid discharge from a toy gun, comprising: a chamber adapted to receive a pressurized liquid, the chamber comprising at least a first sub-chamber and a second sub-chamber, an outlet arranged at the chamber to enable a discharge of at least some of the pressurized liquid received in the chamber; a movable member movably arranged in the chamber; wherein the movable member is movable from a first position to a second position in response to a drop in liquid pressure in the first sub-chamber when compared to a liquid pressure in the second sub-chamber, wherein, at the first position, the movable member is arranged to close the outlet to thereby prevent liquid discharging from the chamber, and, at the second position, the movable member is arranged to open the outlet to thereby allow some of the pressurized liquid to discharge from the chamber. The invention also relates to a toy gun for discharging a liquid, comprising: a tank adapted to store a liquid; a nozzle adapted to discharge under pressure at least some of the liquid stored in the tank; and a conduit adapted to fluidly connect the above described device with the tank.

An anti-freeze water gun structure has a gun body. The gun body has a water passageway therein, a water inlet at a lower end thereof, and a water chamber between the water passageway and the water inlet. A guide tube is provided in the water chamber. A slidable piston is fitted onto the guide tube. A lower end of the guide tube has a sealing structure for blocking a lower end of the water chamber. A lower half of the water chamber, located below the piston, is surrounded by the piston, an inner wall of the water chamber, an outer wall of the guide tube and the sealing structure to form a closed chamber. An elastic member is provided in the closed chamber for elastically pushing the piston upward. A water channel communicating with the water inlet and the water passageway is formed in the guide tube.