This system is directed to the action and assembly for a compressed gas gun, including a paintball gun.
Gas powered guns, including paintball guns that can be used in paintball activities typically use compressed gas for firing projectiles. Generally, these guns are known, but lack consistency with the pressures that is used to propel and eject the projectile from the gun. It is a known problem that with traditional guns, the pressure or actuation of the trigger can affect the pressure that is used to eject a projectile. For example, if a trigger is partially depressed, it is possible for the pressure in the gun to “leak” so that the pressure used to eject the projectile is lower than optimal.
Therefore, it is one objective of this system to provide a consistent pressure for ejecting a projectile that is not reliant upon the pressure applied to the trigger.
The above objectives are accomplished by providing a gas gun projectile platform comprising: a frame; a trigger carried by the frame that can rotate when pressure is applied to the trigger; a first spool biased against a magnet; a pad assembly that, when actuated, allows pressure to enter a first spool pressure area that is forward the first spool and configured to release the first spool from the magnet when sufficient pressure is transferred to the first spool pressure area; the first spool configured to transmit pressure to a second spool wherein the second spool is configured to be positioned rearward overcoming a spring force to allow pressure to release from a bolt pressure area; wherein the bolt pressure area is pressurized when the bolt is in a forward position and configured to transition rearward when the second spool overcomes the spring force; and, wherein an ejection pressure stored in a bolt pressure area is transmitted to a chamber and ejects a projectile from a barrel.
The first spool can be attracted to a magnet disposed in the frame and the trigger is configured to allow pressure to overcome the attraction and separate the first spool from the magnet. A follower can be configured to actuate when the trigger is actuated and configured to allow pressure to overcome the attraction and separate the first spool from the magnet. The second spool can be biased by a spring disposed in the frame and the trigger is configured to allow pressure to overcome the spring and position the second spool rearward.
The construction designed to carry out the invention will hereinafter be described, together with other features thereof. The invention will be more readily understood from a reading of the following specification and by reference to the accompanying drawings forming a part thereof, wherein an example of the invention is shown and wherein:
With reference to the drawings, the invention will now be described in more detail.
Referring to
Once the pressure in the area forward of the first spool 34 increases sufficiently to move first spool 34 so that the magnetic attraction between the magnet 84 and the first spool is overcome the first spool 34 releases from the magnet and moves rearward. The first spool travels rearward into space 36 sending a pressure signal through path 42 into a space around the second spool 54. The second spool can include one or more O-rings to seal the second spool in member 52. When the first spool releases from the magnet, the pressured fluid enters path 40 and fill area 66′. Fluid pressure from area 66′ moves to area 66 and causes ejection of the projectile 11. Areas 66 and 66′ contain fluid pressure for ejecting the projectile and area 66′ stores fluid pressure until first spool 34 causes second spool 56 to move rearward. When the bolt moves forward and rearward, pressure can enter the pressure areas 66′ through opening 62.
A trigger adjustment screw or other member can extend through path 86 and allow for the length of pull to be adjusted.
The bolt 64 is in a forward position while the pressure in 66′ is increased and stored. The bolt prevents the fluid pressure in area 66′ from entering the chamber including areas 66 and 69. When spool 34 is released, fluid pressure causes the second spool 54 to overcome the spring 50 tension and move rearward. The spring tension can be changed by adjustment 46 so that the amount of pressure required to position the second spool from a forward position to a rearward position can be modified. The pressure in the read of the frame and associated with the second spool can be released from the frame through opening 43 and 48 defined in an end member 44.
When the trigger 12 is actuated, the second spool (e.g., timing valve) 54 controls fluid pressure acting on the rear side of the bolt 64. When fluid pressure is released, the fluid pressure around the bolt is directed into the chamber to eject the projectile.
When the bolt 64 is positioned forward, a projectile can be in the chamber for ejection. When first spool 34 moves rearward, the pressure holding the bolt forward is released, pressure from the area 66′ is then allowed to flow into area 66 and against the projectile, the barrel is in a rearward position and the projectile is ejected from the barrel. Once ejected, the barrel can move forward allowing a second projectile to enter the chamber. The barrel can be configured to be disposed forward when out of battery to receive a projectile in a chamber and to be disposed rearward when in battery. A detent can be included and configured to place a projectile rearward against a seal when the projectile is placed in the chamber. The trigger can include an adjustment configured to modify the length of pull of the trigger. A spring adjustment can be included and configured to modify the pressure required to move the second spool rearward. When a projectile enters the chamber, it can contact detent 82, which positions the projectile rearward and against seal 90. When the barrel 10 moves rearward, the detent can be lowered, allowing the barrel to move rearward.
A barrel pressures area 74 can be in fluid communications with area 66 or area 66′ so that when fluid pressure is building in area 66 or 66′, the barrel is moved rearward to close the chamber. When the bolt 64 moves rearward, the fluid pressure is transferred to the barrel and projectile is ejected by fluid pressure from the barrel, and barrel is moved forward. The frame can include an endcap 76 that can secure the barrel to the frame. The frame can include a read barrel housing 72 that can include a barrel pressure release port 70.
Referring to
Referring to
The gas gun can include a first stage wherein fluid pressure is gathered in a bolt pressure area 66 and 66′ from an external pressure source, a bolt 64 is in a forward position, a first spool 34 is in a forward position and a second spool 54 is in a forward position; a second stage wherein the first spool is positioned rearward when a predetermined amount of pressure is transferred to around the first spool, the second spool is positioned rearward overcoming the force of a spring and releasing pressure on a bolt, the bolt is moved rearward configured to allow the bolt pressure to transfer to a projectile to eject the projectile; and, a third stage where the first spool is positioned forward, the second spool is positioned forward, the bolt is positioned forward and the trigger is reset. Fluid can flow between the bolt pressure area 66 into chamber 69 and into barrel pressures area 74 along fluid pathway 65.
In one embodiment, the stages of operation include a first stage where the projectile is disposed in the chamber and the barrel it in a forward position. A forward position is shown as a direction 92 and a rearward direction is shown as a direction 94. The projectile is disposed rearward by the detent 82 and can be adjacent to and against a seal 90. The seal can be carried by seal member 67 that can be configured to receive the bolt. The barrel moves to a rearward position. The bolt is 64 is in a forward position and pressure is stored on area 66 and/or 66′.
The second stage includes the trigger 12 being actuated which causes the first spool 34 to move rearward due to pressure traveling along supply path 28 to position the first spool rearward. The positioning of the first spool rearward allows for pressure to travel along path 42 and into area around the second spool 54 causing the second spool to move rearward, overcoming the force of the spring 50. When the second spool moves rearward, the bolt is allowed to move rearward.
In a third stage, the bolt moves rearward and pressure that has gathered in area 66 and 66′ is allowed to escape into the chamber and eject the projectile. A pathway from area 66 to area 74 positioning the barrel forward. The chamber is opened allowing a second projectile to enter the chamber. The bolt is moved forward, and pressures is again gathered in areas 66 and 66′. The second spool returns forward, and the trigger is reset.
The gas gun projectile platform may include: a frame; a trigger carried by the frame that can rotate when pressure is applied to the trigger; a first spool biased against a magnet; a pad assembly that, when actuated, allows pressure to enter a first spool pressure area forward the first spool and configured to release the first spool from the magnet when sufficient pressure is transferred to the first spool pressure area; the first spool configured to transmit pressure to a second spool wherein the second spool is configured to be positioned rearward overcoming a spring force to allow pressure to release from a bolt pressure area; wherein the bolt pressure area is pressurized when the bolt is in a forward position and configured to transition rearward when the second spool overcomes the spring force; and, wherein an ejection pressure stored in a bolt pressure area is transmitted to a chamber and ejects a projectile from a barrel.
The first spool can be attracted to a magnet disposed in the frame and the trigger is configured to allow pressure to overcome the attraction and separate the first spool from the magnet. A follower can be configured to actuate when the trigger is actuated and configured to allow pressure to overcome the attraction and separate the first spool from the magnet. The second spool can be biased by a spring disposed in the frame and the trigger is configured to allow pressure to overcome the spring and position the second spool rearward.
It is understood that the above descriptions and illustrations are intended to be illustrative and not restrictive. It is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims. Other embodiments as well as many applications besides the examples provided will be apparent to those of skill in the art upon reading the above description. The scope of the invention should, therefore, be determined not with reference to the above description, but should instead be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. The disclosures of all articles and references, including patent applications and publications, are incorporated by reference for all purposes. The omission in the following claims of any aspect of subject matter that is disclosed herein is not a disclaimer of such subject matter, nor should it be regarded that the inventor did not consider such subject matter to be part of the disclosed inventive subject matter.
This application is a non-provisional patent application claiming priority from U.S. Provisional Patent Application 63/248,608 filed Sep. 27, 2022 which is incorporated by reference.
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