A firing mechanism for a compressed gas gun includes a heating chamber attached to a fluid source. Gas or liquified gas from the fluid source is admitted into the heating chamber through a valve, which seals the gas source from the heating chamber thereby preventing back flow of the gas from the heating chamber to the source. A heating element inside the heating chamber is then energized to heat the gas to a temperature and pressure to well above that of the gas source. When a predetermined temperature and pressure is achieved, the heating chamber is exhausted into the breech of the gas gun to expel the projectile.

A firing mechanism for a compressed gas gun includes a heating chamber attached to a fluid source. Gas or liquified gas from the fluid source is admitted into the heating chamber through a valve, which seals the gas source from the heating chamber thereby preventing back flow of the gas from the heating chamber to the source. A heating element inside the heating chamber is then energized to heat the gas to a temperature and pressure to well above that of the gas source. When a predetermined temperature and pressure is achieved, the heating chamber is exhausted into the breech of the gas gun to expel the projectile.

The fishing lure launching device is a mechanical device. The fishing lure launching device launches a payload. In the first potential embodiment of the disclosure, the payload comprises one or more elements selected from the group consisting of a fishing line, a fishing lure, a leader and a swivel. An example of a fishing lure is a spinnerbait lure. The fishing lure launching device launches the payload on a controlled trajectory. The fishing lure launching device is a pneumatically operated device. The fishing lure launching device comprises a bucket, a transfer shaft, a thrust structure, a trigger valve, an adjustable pressure regulator, and a gas source. The payload is contained in the bucket. The transfer shaft attaches the bucket to the thrust structure. The thrust structure generates the forces necessary to launch the payload out of the bucket. The trigger valve initiates the operation of the thrust structure.

The system comprises a firing mechanism (20), which comprises a trigger (22) and a main valve (23), which is connected to a barrel (21), and a first reservoir (1), wherein the fluid to be distributed to the main valve (23) is provided at a pre-determined pressure; said first reservoir (1) being arranged inside a tubular element (3), characterised in that it comprises: a second reservoir (2), arranged inside the tubular element (3), having the same pressure as the first reservoir (1), and a spacing element (4), which operates as a moving piston, arranged inside the tubular element (3), which separates the first reservoir (1) from the second reservoir (2),
and in that the tubular element (3) at least partially surrounds the first reservoir (1), the spacing element (4) and the second reservoir (2).

A compact improved bug killing gun includes a compressed gas source fluidly connected to a chamber connected to a barrel. A compressed gas release mechanism is connected to the compressed gas source. A projectile storage magazine stores particulate projectiles and is located adjacent the chamber. A projectile loading mechanism moves the projectiles into the chamber from the magazine. A cocking mechanism is mechanically connected to the compressed gas source, the compressed gas release mechanism, and the projectile loading mechanism. When the gun is cocked, the projectile loading mechanism loads a quantity of the particulate projectiles into the chamber. When the compressed gas release mechanism is activated the projectiles are ejected from the chamber into the barrel and expelled from the gun. The gun optionally includes a laser sighting mechanism. The battery operated laser sighting mechanism is removably attached to the barrel or permanently attached with an integral, trigger operated switch.

A compact improved bug killing gun includes a compressed gas source fluidly connected to a chamber connected to a barrel. A compressed gas release mechanism is connected to the compressed gas source. A projectile storage magazine stores particulate projectiles and is located adjacent the chamber. A projectile loading mechanism moves the projectiles into the chamber from the magazine. A cocking mechanism is mechanically connected to the compressed gas source, the compressed gas release mechanism, and the projectile loading mechanism. When the gun is cocked, the projectile loading mechanism loads a quantity of the particulate projectiles into the chamber. When the compressed gas release mechanism is activated the projectiles are ejected from the chamber into the barrel and expelled from the gun. The gun optionally includes a laser sighting mechanism. The battery operated laser sighting mechanism is removably attached to the barrel or permanently attached with an integral, trigger operated switch.

The present invention relates generally to an adaptor system for use with a pneumatic gun that allows for the delivery of a fluid from a tank to the chamber of the gun. The adaptor system can easily be added or removed from the cartridge cavity of a gun whereby allowing a user to easily convert between a gun that uses a cartridge system or one that can use a large tank system with an attached hose.

The present invention relates generally to an adaptor system for use with a pneumatic gun that allows for the delivery of a fluid from a tank to the chamber of the gun. The adaptor system can easily be added or removed from the cartridge cavity of a gun whereby allowing a user to easily convert between a gun that uses a cartridge system or one that can use a large tank system with an attached hose.

An integrated structure of a barrel and an air storage pipe of an air gun is provided. The air storage pipe is fixedly connected with a first connecting member and a second connecting member. The barrel is fixedly connected between the first connecting member and the second connecting member. The air storage pipe, the first connecting member, the second connecting member and the barrel cooperate to form an air storage area. The air storage area is located between the first connecting member and the second connecting member and communicated with an inflation head through an air supply passage disposed in the second connecting member. The layout of the air storage pipe and the barrel is more reasonable to prolong the service life of the air gun and to enhance the shooting accuracy.

Projectile carrier for a gas gun with a barrel defining a barrel bore arranged to guide a projectile, the projectile carrier including a projectile carrier bore for holding a projectile aligned with a barrel bore of the gas gun and to be sealingly in communication with a pressure chamber when the projectile carrier is in a service position, the projectile carrier being adapted to receive a projectile when in a loading position. The projectile carrier is distinct from the barrel and includes at least one projectile retaining element held in place by at least one locking element arranged to move on the projectile carrier between a locking position, in which the at least one projectile retaining element is engaged with a retention surface included by the projectile, and an unlocked position, in which the projectile is free to move under the effect of pressure in the pressure chamber.