This invention relates generally to the construction of compressed gas guns and more particularly to the guns designed to propel a liquid containing frangible projectile, otherwise known as a “paintball.” As used herein, the term “compressed gas” refers to any mean known in the art for providing a fluid for firing a projectile from a compressed gas gun, such as a CO2 tank, a nitrous tank, or any other means supplying gas under pressure. Older existing compressed gas guns generally use a mechanical sear interface to link the trigger mechanism to the hammer or firing pin mechanism. In these guns, a trigger pull depresses the sear mechanism which allows the hammer, under spring or pneumatic pressure, to be driven forward and actuate a valve that releases compressed gas through a port in the bolt, which propels a projectile from the barrel.
This design, however, has many problems, including increased maintenance, damage after repeated cycles, and a higher amount of force is required to drive the hammer mechanism backwards to be seated on the sear. Also, because the sear and resulting hammer must be made of extremely hard materials, the gun is heavy. Such weight is a disadvantage in paintball, where a player's agility works to his advantage.
To overcome the problems of a mechanical sear, other solutions have been developed. One solution uses a pneumatic cylinder, which uses spring or pneumatic pressure on alternating sides of a piston to first hold a hammer in the rearward position and then drive it forward to actuate a valve holding the compressed gas that is used to fire the projectile. Although the use of a pneumatic cylinder has its advantages, it requires the use of a stacked bore, where the pneumatic cylinder in the lower bore and is linked to the bolt in the upper bore through a mechanical linkage. It also requires increased gas use, as an independent pneumatic circuit must be used to move the piston backwards and forwards. A further disadvantage is that adjusting this pneumatic circuit can be difficult, because the same pressure of gas is used on both sides of the piston and there is no compensation for adjusting the amount of recock gas, used to drive it backwards, and the amount of velocity gas, which is the amount of force used to drive it forward and strike the valve. This results in erratic velocities, inconsistencies, and shoot-down. In addition, this technology often results in slower cycling times, as three independent operations must take place. First, the piston must be cocked. Second, the piston must be driven forward. Third, a valve is opened to allow compressed gas to enter a port in the bolt and fire a projectile. Clearly, the above design leaves room for improvement.
Single-bore designs have been developed which place the cylinder and piston assembly in the top bore, usually behind the bolt. This reduces the height of the compressed gas gun, but still requires that a separate circuit of gas be used to drive the piston in alternating directions, which then actuates a valve to release compressed gas, which drives the bolt forward to launch a paintball. These are generally known as spool valve designs. See, for instance, U.S. Pat. Nos. 5,613,483 and 5,494,024.
Existing spool valve designs have drawbacks as well. Coordinating the movements of the two separate pistons to work in conjunction with one another requires very precise gas pressures, port orifices, and timing in order to make the gun fire a projectile. In the rugged conditions of compressed gas gun use, these precise parameters are often not possible. In addition, adjusting the velocity of a compressed gas gun becomes very difficult, because varying the gas pressure that launches a paintball in turn varies the pressure in the pneumatic cylinder, which causes erratic cycling.
What is needed is a compressed gas gun design that eliminates the need for a separate cylinder and piston assembly and uses a pneumatic sear instead of a pneumatic double-acting cylinder to hold the firing mechanism in place prior to firing a projectile. This allows the gun to be very lightweight and compact, and simplifies adjusting the recock gas used to cock the bolt and the gas used to fire the projectile. A further need exists for an easily removable inline cylinder that can be removed, preferably without using tools, so that the marker can be field-stripped and maintained.
The current invention addresses these needs. The main advantage is that the inventive inline cylinder includes a gas governor that reduces gas flow from a compressed gas source to a valve area when the bolt is in a firing position; this increases efficiency in the marker because only the required air is used to fire the paintball. This particular design operates independent of the valve pin, which increases cycle speed and enables the governor to open and close at the optimum time in the firing cycle. Further, when the bolt/piston is recocking, the gap between the valve pin and governor valve pin enables low pressure gas driving the piston to start pressurizing the cylinder and driving the piston rearwards without resistance from the high pressure gas.
It allows a user to remove the inline cylinder without the use of tools, and gives the user a convenient carrying handle for holding the paintball marker, which is commonly called a “snatch grip.”
Further, the invention uses a safety mechanism that prevents the inline from being removed while the marker is pressurized without the safety, such removal would result in the inline cylinder being driven backwards out of the marker.
Other objects of the invention will be more readily apparent upon reading the following description of embodiments of the invention and upon reference to the accompanying drawings wherein:
Hereinafter, the term forward shall indicate being towards the direction of the barrel 10 and rearward shall indicate the direction away from the barrel 10 and towards the rear of main body 3. Preferably forward of the grip portion 45, and also attached to main body 3, the regulator mount 2 houses both the low-pressure regulator 21 and the high-pressure regulator 50. Compressed gas is fed from preferably a compressed gas tank into the input port 49 on high-pressure regulator 50 to be directed to tube 7 to launch a projectile and to be directed to low pressure regulator 21 to cock the bolt tip 38 for loading. Both regulators 21, 50 are constructed from principles generally known to those skilled in the art, and have adjustable means for regulating compressed gas pressure.
Referring more particularly to
The variable pneumatic sear 29 of the compressed gas gun of the present invention preferably consists of a control valve 30, a piston 32, residing in preferably sealed cylinder housing 31 as shown in
Control valve 30 is preferably controlled by an electrical signal sent from circuit board 63. The electronic control circuit consists of on/off switch 87, power source 64, circuit board 63, and micro-switch 86. When the gun is turned on by on/off switch 87, the electronic control circuit is enabled. For convenience, the on/off switch 87 (and an optional additional switches, such as that for adjacent anti-chop eye that prevents the bolt's advance when a paintball 100 is not seated within the breech) is located on the rear of the marker, within a recess 88 shielded on its sides by protective walls 89. This location protects the switch 87 from inadvertent activation during play. The switch 87 is preferably illuminated by LEDs.
When actuating switch 86 by manually depressing trigger 24, an electrical signal is sent by circuit board 63 to the control valve 30 to actuate and close the primary port, thereby releasing valve pin 33 and launching a projectile. Once the momentary pulse to the control valve 30 is stopped by circuit board 63, the electronic circuit is reset to wait for another signal from switch 86 and the gun will load its next projectile. In this manner, the electrical control circuit controls a firing operation of the compressed gas gun.
A description of the gun's operation is now illustrated. The function of the pneumatic sear is best illustrated with reference to
This allows bolt tip 38 to clear the breech area of the body 3, in which stage a projectile 100 moves from the feed tube 6 and rests directly in front of bolt tip 38. The projectile is now chambered and prepared for firing from the breech. The high-pressure compressed gas, which has passed into the valve chamber 36 via high pressure passage 37, is now pushing against valve pin 33 on the rear of piston 32. The seal created by o-ring 70 on valve pin 33 is not broken because the force of the low-pressure gas on the first side of cylinder 31 is sufficient to hold the valve pin 33 rearward.
When trigger 24 is depressed, electro-pneumatic valve 30 is actuated (preferably using a solenoid housed within the manifold 41, shutting off the flow of low-pressure gas to housing 31 and venting the housing 31 via manifold 41. This allows the higher pressure gas, which is already pushing against valve tip 33 from the rear, to drive valve tip 33 forward to the firing position and break the seal 72 against the housing 35. Bolt tip 38, which is connected to piston 32, pushes a projectile forward in the breech and seals the feed tube 6 from compressed gas during the first stage of launch because the valve pin 33 is still passing through valve housing tip 35 during this stage. This prevents gas leakage up the tube 6 and positions the projectile for accurate launch. Once the valve pin 33 clears the housing tip 35, a flow passage D is opened, and the higher pressure gas flows through ports drilled through the interior of piston 32 and bolt tip 38 and propels the paintball from barrel 10. Note that the piston's 32 movement in the forward direction is limited by contact between the first surface 72 and a shoulder 73 within the cylinder 31.
The signal sent to electro-pneumatic valve 30 is a momentary pulse, so when the pulse ceases, the valve 30 is de-actuated. This allows low-pressure gas to enter cylinder housing 31 and drive valve piston 32 rearwards against the force exerted by high-pressure gas to the seated position and allow loading of the next projectile.
Since piston 32 has a larger surface area on its outside diameter than the surface area on the valve pin 33, low-pressure gas is able to hold high-pressure gas within the valve chamber 36 during the loading cycle of the gun. This is more advantageous than a design where a separate piston is used to actuate a separate valve, because the step of actuating and de-actuating the piston is removed from the launch cycle.
In addition, the pressures of the low pressure gas and high pressure gas may be varied according to user preference, thereby allowing for many variable pneumatic configurations of the gun and reducing problems with erratic cycling caused by using the same gas to control both the recock and launch functions of the gun. Because the mechanical sear is eliminated, the gun is also extremely lightweight and recoil is significantly reduced. The gun is also significantly faster than existing designs because the independent piston operation is eliminated.
In an alternate embodiment, the compressed gas gun can operate at one operating pressure instead of having a high-pressure velocity circuit and a low-pressure recock circuit. This is easily accomplished by adjusting the ratio of the surface sizes of the first surface 72 and the valve pin 33. In this manner, the size of the gun is reduced even more because low-pressure regulator 21 is no longer needed.
The marker of
When a user removes the mechanical linkage 400 from within the bores 302, 402 as shown in
The locking pin 406 extends through the bores 302, 402 to lock the inline cylinder 314 within the marker bore 300, and prevent motion between the inline cylinder 314 and the marker. As best seen in
It should be appreciated, from
The operation of the inline cylinder 314 during the firing cycle will now be described. The control valve 30 directs low pressure compressed gas from low pressure regulator 21 through manifold 41 through the low pressure passages 374 to bolt chamber 331 allowing gas to contact first surface 332a of piston 332, driving the piston 332 rearward. Rearward movement of the piston 332 moves the valve pin 333 rearwards, which results in a seal between the seal 370 and the valve housing 333a. This is considered the loading position because the piston's tip 338 clears the breech 101 and allows a paintball 100 to drop into the breech 101. (This loading position corresponds to the bolt position in
Meanwhile, high pressure gas from the high pressure regulator flows through high pressure passage 337, then through cylinder channels 339, through governor channels 382, into the governor chamber 380, through firing chamber channels 384, and into the firing chamber 308. The low pressure compressed gas drives the piston 332 rearward, overcoming high-pressure gas pressure on valve pin 333 because the surface area of first surface 332a of piston 332 is larger than that of the surface area 333a of valve pin 333. In this loading position shown in
As with the embodiment of
The function of the inline cylinder 314 and gas governor 380 can best be appreciated in
This high pressure cutoff results in a faster loading cycle, which begins when the normally open valve low pressure valve reopens and low pressure gas acts on the forward surface 332a of bolt 332. The cycle is faster because it does not have to overcome high pressure gas in the firing chamber 308 as the low pressure gas drives bolt 332 rearward, since there is no or little high pressure gas in the firing chamber 308. As the low pressure gas drives the bolt 332 rearward, the valve 333 engages the gas governor pin 386 and drives it backwards to its position in
The length of the governor pin 386 can also be manipulated to change the timing of the opening and closing of the governor without affecting the firing cycle.
While the present invention is described as a variable pneumatic sear for a paintball gun, it will be readily apparent that the teachings of the present invention can also be applied to other fields of invention, including pneumatically operated projectile launching devices of other types. In addition, the gun may be modified to incorporate a mechanical or pneumatic control circuit instead of an electronic control circuit, for instance a pulse valve or manually operated valve, or any other means of actuating the pneumatic sear.
It will be thus seen that the objects set forth above, and those made apparent from the preceding description, are attained. It will also be apparent to those skilled in the art that changes may be made to the construction of the invention without departing from the spirit of it. It is intended, therefore, that the description and drawings be interpreted as illustrative and that the following claims are to be interpreted in keeping with the spirit of the invention, rather than the specific details. set forth.
It is also to be understood that the following claims are intended to cover all the generic and specific features of the invention herein described and all statements of the scope of the invention that, as a matter of language, might be said to fall therebetween.
This application is a continuation-in-part of U.S. patent application Ser. No. 11/183,548, filed Jul. 18, 2005, which claims the benefit of U.S. Provisional Nos. 60/588,912 and 60/654,262 filed Jul. 16, 2004 and Feb. 18, 2005 respectively, and also claims the benefit of U.S. Provisional No. 60/654,120 filed Feb. 18, 2005, which are incorporated by reference as if fully set forth.
Number | Date | Country | |
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60588912 | Jul 2004 | US | |
60654262 | Feb 2005 | US | |
60654120 | Feb 2005 | US |
Number | Date | Country | |
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Parent | 11183548 | Jul 2005 | US |
Child | 11358649 | Feb 2006 | US |