Trigger system for paintball marker
A paintball marker is provided including a body, a first pneumatic component, a second pneumatic component, a first control valve for controlling the flow of gas to actuate the first pneumatic component, a second control valve for controlling the flow of gas to actuate the second pneumatic component, and a trigger. The trigger is operatively connected to the first and second control valves. The marker is configured to reduce or eliminate the likelihood of a player releasing the trigger after only actuating one of the control valves.
The present invention relates to paintball markers and more particularly to a trigger system for a paintball marker.
BACKGROUND OF THE INVENTIONMany people today enjoy playing paintball games with sophisticated paintball markers. A typical paintball marker has a barrel from which paintballs are fired. A breech is provided which receives paintballs through an inlet, and which communicates with the barrel. A paintball tube holds paintballs for feeding into the breech. A bolt slides within the breech to chamber a paintball, ie. to move a paintball that has been fed into the breech, into the barrel. The bolt also controls the entry of paintballs from the paintball tube into the breech. The bolt is typically moved between an open position whereby a paintball is permitted to enter the breech and a closed position whereby the entry of paintballs into the breech is prevented. A pneumatic actuator, such as a pneumatic cylinder is typically used to move the bolt.
If a paintball does not feed correctly in the breech, the bolt can squash and rupture the paintball, releasing paint onto the interior mechanisms of the marker. As a result, the released paint can disrupt the proper functioning of the marker. Consequently, after a paintball is squashed inside a marker, it is usually required for the marker to be disassembled and cleaned to remove any paint on the interior mechanisms.
Another problem with current markers is the use of solenoid valves, which have been incorporated into markers to operate the firing valve and the bolt. Solenoid valves are favoured at least in part for their seemingly quick response time, however, several problems exist with markers in which solenoid valves are present. These markers by necessity include relatively complex electrical systems, which include a battery and typically a control circuit which assists in timing the sequence of operation of the solenoids. All of these electrical components are a source of unreliability in such paintball markers. For example, during play a battery could run out of power. Furthermore, during adverse conditions, such as wet, cold or hot conditions, the electrical components are at risk of failing. Typically, electrical components are not sufficiently robust to withstand repeated impacts, which can occur as a player inadvertently drops or otherwise impacts a marker during play.
There is, therefore, a continuing need for improved paintball markers that have a reduced tendency to squash and rupture paintballs during a loading and chambering operation. Also, in another aspect, there is a need for improved markers that are capable of firing quickly and at high frequency, but that have a reduced dependence on electrical components, such as solenoids.
SUMMARY OF THE INVENTIONIn a first aspect, the invention is directed to a paintball marker including a body, an inlet control device, a firing system, a first regulator and a second regulator. The body has a paintball inlet and a barrel for receiving a paintball from the paintball inlet. The inlet control device is movable between an open position wherein the inlet control device permits entry of a paintball through the paintball inlet, and a closed position for chambering a paintball. In the closed position the inlet control device prevents entry of a paintball through the paintball inlet. The firing system includes a firing valve that is moveable between a firing position wherein the valve permits firing gas at a selected pressure to flow to the barrel and a non-firing position wherein the firing valve prevents flow of firing gas to the barrel. The first regulator is fluidically connectable to the pressurized gas source and is configurable to provide gas at a first pressure. The first regulator is operatively connected to the firing valve for movement of the firing valve between the firing and non-firing positions. The second regulator is fluidically connectable to the pressurized gas source and is configurable to provide gas at a second pressure that is lower than the first pressure. The second regulator is operatively connected to the inlet control device for movement of the inlet control device towards the closed position. The inlet control device may be, for example, a bolt.
In a second aspect, the invention is directed to a paintball marker having a trigger and a flow control valve. The trigger is operatively connected to the flow control valve. The flow control valve includes a housing defining an interior. The housing has a first, a second, a third, a fourth and a fifth port, wherein the ports are longitudinally spaced apart. The housing further includes a first, a second, a third and a fourth housing projections extending into the interior longitudinally between the first and second ports, the second and third ports, the third and fourth ports and the fourth and fifth ports respectively. The housing projections have a first, a second, a third and a fourth housing sealing surface thereon respectively. The flow control valve further includes an elongate valve spool that is slidably mounted in the housing. The valve spool has a first, a second, a third and a fourth generally ring-shaped spool projection. The spool projections are longitudinally spaced apart. The spool projections have a first, a second, a third and a fourth spool sealing surface thereon respectively for sealing engagement with the housing sealing surfaces. The valve spool is moveable between a first position wherein the second and fourth spool sealing surfaces seal against the second and fourth housing sealing surfaces respectively to permit fluid communication between the third port and the fourth port and between the first port and the second port, and a second position wherein the first and third spool sealing surfaces seal against the first and third housing sealing surfaces respectively to permit fluid communication between the second port and the third port and between the fourth port and the fifth port. The valve spool is engageable by the trigger by at least one of a mechanical and a pneumatic connection for movement to at least one of the first and second positions, without the use of a solenoid to actuate the valve. For example, the valve spool may be engageable directly by the trigger. Furthermore, actuation of the valve spool mechanically or pneumatically by the trigger removes steps that occur in a solenoid actuated valve, namely the steps of contacting the trigger with the sensor and actuating the solenoid. Because of the configuration of the valve sealing surfaces, and because the valve spool is actuated by the trigger mechanically or pneumatically instead of through an intermediate solenoid, the overall response time of the valve is fast, and the marker does not suffer any of the problems associated with electrical components, such as their relatively poor reliability, particularly in wet, cold or hot conditions.
In a third aspect, the invention is directed to a gas storage chamber and an adjustment member. The gas storage chamber is configured for storing gas for use in firing a paintball. The adjustment member is moveably connected to the gas storage chamber for movement within a range of adjustment. The adjustment member occupies a selectable portion of the volume contained within the gas storage chamber. This permits the player to optimize the use of the air in the air tank for the marker. For example, the player can incrementally adjust down the volume of the chamber until the velocity of a fired paintball is observed to drop off. In this way, the player can obtain an increased number of shots per tank. Also, the player can adjust the chamber volume in general, in response to playing conditions.
In a fourth aspect the invention is directed to a method for controlling pneumatic operations of a paintball marker, the paintball marker having a body having a paintball inlet and an inlet control device, wherein the inlet control device is moveable between an open position and closed position for controlling the flow of paintballs through the paintball inlet and for chambering a paintball, wherein the inlet control device is movable by means of an inlet control device actuator, wherein the inlet control device actuator is pneumatically operated, the paintball marker further including a firing valve, wherein the firing valve is moveable between an open position and a closed position and is movable to at least one of the open and closed positions by a firing valve actuator, wherein the firing valve actuator is pneumatically operated, the method comprising:
-
- providing gas at a first pressure to the inlet control device actuator to move the inlet control device to an open position to permit entry of a paintball through the paintball inlet;
- providing gas at a second pressure the pneumatic cylinder to move the inlet control device to a closed position to prevent entry of a paintball through the paintball inlet and to chamber a paintball, wherein the second pressure is selected to be sufficiently low to inhibit rupturing of a paintball if, during use, the paintball is confined by the inlet control device during movement of the inlet control device towards the closed position; and
- providing gas at a third pressure to the firing valve actuator for movement of the firing valve to at least one of the open and closed positions, wherein the third pressure is higher than the second pressure.
In a fifth aspect the invention is directed to a paint ball marker having a trigger and a flow control valve. The trigger is operatively connected to the flow control valve. The flow control valve includes a housing defining an interior. The housing has a plurality of longitudinally spaced projections extending into the interior. The projections have housings sealing surfaces thereon. The flow control valve further includes an elongate valve spool that is slideably mounted in the housing. The valve spool has a plurality of longitudinally spaced generally ring shaped spool projections. The spool projections have spool sealing surfaces thereon for sealing engagement with the housing sealing surfaces. The valve spool is moveable between a first position and a second position to control the flow of pressurized gas through the valve in one direction and the exhaustion of the gas through the valve in another direction. The valve spool is engageable by the trigger by one of a mechanical and a pneumatic connection for movement to at least one of the first and second positions, without the use of a solenoid to actuate the valve. Furthermore, actuation of the valve spool mechanically or pneumatically by the trigger removes steps that occur in a solenoid actuated valve, namely the steps of contacting the trigger with the sensor and actuating the solenoid. Because of the configuration of the valve sealing surfaces, and because the valve spool is actuated by the trigger mechanically or pneumatically instead of through an intermediate solenoid, the overall response time of the valve is fast, and the marker does not suffer any of the problems associated with electrical components, such as their relatively poor reliability, particularly in wet, cold or hot conditions.
In a sixth aspect, the invention is directed to a paintball marker comprising a body, a first pneumatic component, a second pneumatic component, a first control valve for controlling the flow of gas to actuate the first pneumatic component, a second control valve for controlling the flow of gas to actuate the second pneumatic component, and a trigger. The first and second control valves are free of solenoids. The trigger is pivotally connected with respect to the body for movement about a pivot. The trigger includes a first valve actuation portion and a second valve actuation portion. The trigger is operatively connected to the first and second control valves by means of the first and second valve actuation portions. The first and second valve actuation portions are proximate the pivot.
In a seventh aspect, the invention is directed to a paintball marker comprising a body, a first pneumatic component, a second pneumatic component, a first control valve for controlling the flow of gas to actuate the first pneumatic component, a second control valve for controlling the flow of gas to actuate the second pneumatic component, and a trigger. The first control valve includes a first housing and a first spool that is movable for actuation of the first control valve. The first control valve includes a first biasing means for biasing the first spool to extend outward from the first housing. The second control valve includes a second housing and a second spool. The second spool is movable for actuation of the second control valve. The second control valve includes a second biasing means for biasing the second spool to extend outward from the second housing. The first and second control valves are free of solenoids. The trigger is movably connected with respect to the body for movement along a path. The trigger includes a first valve actuation portion and a second valve actuation portion. The trigger is operatively connected to the first and second control valves by means of the first and second valve actuation portions. The trigger includes an arm. The first and second valve actuation portions are positioned on opposing sides of the arm. The arm is movable in a direction towards one of the spools and away from the other of the spools.
In an eighth aspect, the invention is directed to a paintball marker comprising a body, a first pneumatic component, a second pneumatic component, a first control valve for controlling the flow of gas to actuate the first pneumatic component, a second control valve for controlling the flow of gas to actuate the second pneumatic component, a master valve, and a trigger. The master valve is operatively connected to the first and second control valves. The master valve and the first and second control valves are free of solenoids. The trigger is movably connected with respect to the body for movement along a path and wherein the trigger is operatively connected to the master valve.
In a ninth aspect, the invention is directed to a paintball marker comprising a body, a firing valve actuation cylinder, a bolt actuation cylinder, a first control valve for controlling the flow of gas to actuate one of the firing valve actuation cylinder and the bolt actuation cylinder, a second control valve for controlling the flow of gas to actuate the other of the firing valve actuation cylinder and the bolt actuation cylinder, a valve actuation link, a linkage cylinder, a master valve, and a trigger. The first control valve has a first housing and a first spool. The first spool is movable between a first position and a second position. The second control valve has a second housing and a second spool. The second spool is movable between a first position and a second position. The valve actuation link is movable with respect to the body between a first valve actuation link position and a second valve actuation link position. The valve actuation link is operatively connected to the first and second control valves. In the first valve actuation link position the valve actuation link urges the first spool to the first position for the first spool and the second spool is biased to the first position for the second spool. In the second valve actuation link position the valve actuation link urges the second spool to the second position for the second spool and the first spool is biased to the second position for the first spool. The linkage cylinder is operatively connected to the valve actuation link. The master valve is operatively connected to the linkage cylinder. The master valve and the first and second control valves are free of solenoids. The trigger is movably connected with respect to the body and is operatively connected to the master valve.
In a tenth aspect, the invention is directed to a paintball marker comprising a body, a first pneumatic component, a second pneumatic component, a first control valve for controlling the flow of gas to actuate the first pneumatic component, a second control valve for controlling the flow of gas to actuate the second pneumatic component, and a trigger. The trigger is operatively connected to the first and second control valves. The marker is configured to reduce or eliminate the likelihood of a player releasing the trigger after only moving it far enough to actuate one of the control valves.
BRIEF DESCRIPTION OF THE DRAWINGSThe present invention will now be described by way of example only with reference to the attached drawings, in which:
Reference is made to
The paintball marker 10 includes a body 14, an inlet control device 15, which may be, for example, a bolt 16, and an actuation system 18. The body 14 defines a chamber 20, that is typically called a breech, for holding a paintball 12 to be fired. The breech 20 has a paintball inlet 22 through which paintballs 12 are fed one at a time for firing. A paintball tube 24 may extend outwards from the body 14 for holding a plurality of paintballs 12 to be fed into the breech 20. The breech 20 may extend generally linearly and may have a front end 26, which is open. The breech 20 has a diameter that is sufficiently large that it does not hamper the movement of the paintball 12 therein.
A barrel 28 may be mounted in the front end 26 in fluid communication with the breech 20. The barrel 28 may have a diameter that is the same or optionally slightly smaller than the diameter of the paintballs 12. It will be appreciated that the diameter of the barrel 28 is also smaller than the diameter of the breech 20.
The barrel 28 has an inlet which is shown at 29. The inlet 29 includes a transition portion 29a (shown more clearly in
The breech 20 has a rear end 30 in which there is an opening 32. The bolt 16 is slideable within the breech 20 and connects to the actuation system 18 through the opening 32. The bolt 16 is moveable by means of the actuation system 18, between a closed position, as shown in
When the bolt 16 chambers a paintball 12, the bolt 16 also blocks the paintball inlet 22, and prevents other paintballs 12 from entering the breech 20, when in the closed position shown in
Reference is made to
When in the open position, the front end 35 of the bolt 16 may be positioned generally aligned with the rearmost edge of the paintball inlet 22. A detent 34 extends into the breech 20 proximate the forwardmost edge of the paintball inlet 22. When the bolt 16 is open, the detent 34 and the bolt 16 cooperate to retain a paintball 12 in the breech 20. The paintball 12 in the breech 20 is positioned in such a way as to block other paintballs 12 from entering the breech 20.
The detent 34 is resilient so as to permit the bolt 16 to push a paintball 12 therepast during closure of the bolt 16. The detent 34 may be resilient by any suitable means, such as by being spring loaded.
The detent 34 is shaped so as not to rupture the paintball 12 as it moves therepast. For example the detent 34 may be spherical.
The actuation system 18 is used to move the bolt 16 between the open and closed positions. The actuation system 18 may be any suitable type of actuation system. For example, the actuation system 18 may utilize gas pressure from a suitable gas source such as a pressurized air tank 400 (see
The actuation system 18 includes an actuator 37, which may be a pneumatic cylinder 37, a control valve 38, a first low pressure regulator 40, and a second low pressure regulator 42. The pneumatic cylinder 37 includes a housing 44 and a piston 46. Movement of the piston 46 within the housing 44 is controlled by the entry and discharge of air in the housing 44 through a first port 48 and a second port 50. A rod 52 extends from the piston 46 out from the pneumatic cylinder 37 and through the body 14 of the paintball marker 10. The rod 52 connects the piston 46 to a back plate 53, to which the bolt 16 is also connected. By virtue of the connection of the piston 46 to the bolt 16 by means of the rod 52 and the back plate 53, movement of the piston 46 in the housing 44 causes movement of the bolt 16 in the breech 20.
The first and second low pressure regulators 40 and 42 are mounted in fluid communication with the air conduit 36 to receive air from the primary regulator (not shown). More specifically, the paintball marker 10 may include a manifold 54 that has an internal air conduit 55 therein that is in fluid communication with the air conduit 36.
The manifold 54 has a first port 55a for connection to the first low pressure regulator 40 and a second port 55b for connection to the second low pressure regulator 42. The manifold 54 may optionally also include a third port 55c, which may be used as desired, or which may be plugged when not in use.
The manifold 54 may be a separate component that mounts to the body 16 of the paintball marker 10, or alternatively, the manifold 54 may be integral with the body 16. The manifold 54 may include mounting means for the first and second low pressure regulators 40 and 42, for the control valve 38 and for the pneumatic cylinder 37, as shown in
Pressurized air travels from the air tank 400 (
It is alternatively possible, however, for the primary regulator (not shown) to be connected directly into the manifold 54 using the optional port 55c, instead of being connected to the air conduit inlet 36a on the body 16. In that case, it will be appreciated that the inlet 36a on the body 16 would require plugging.
The low pressure regulators 40 and 42 reduce the pressure of the air received from the primary regulator (not shown), down to two different outlet pressures. The first low pressure regulator 40 may reduce the pressure of the air to between approximately 50 psi and approximately 100 psi, and the second low pressure regulator 42 may reduce the pressure of the air to between approximately 5 psi and approximately 50 psi. The air pressures provided by the low pressure regulators 40 and 42 may be selected based on the specific characteristics of the components of the paintball marker 10. For example, if there is significant resistance in the movement of the bolt 16 in the breech 20, the regulators 40 and 42 may be selected to provide air at higher pressures. Conversely, if for example, the bolt 16 moves with little resistance in the breech 20 then accordingly, lower pressure may be selected for the second regulator 42 and for the first regulator 40 if it is involved in movement of the bolt 16 towards its open position.
The control valve 38 controls the movement of the piston 46 by controlling the flow of air from the regulators 40 and 42 to the first and second ports 48 and 50. The control valve 38 includes a first inlet port 56, a second inlet port 58, a first outlet port 60 and a second outlet port 62. The first inlet port 56 is connected to the outlet of the regulator 40 by means of a first conduit 64. The first outlet port 60 is connected to the first port 48 of the pneumatic cylinder 37 by means of a second conduit 68. The second inlet port 58 is connected to the outlet of the regulator 42 by means of a third conduit 66. The second outlet port 62 is connected to the second port 50 of the pneumatic cylinder 37 by means of a fourth conduit 70. The conduits 64, 66, 68 and 70 may be flexible conduits, such as, for example, flexible plastic tubing. Alternatively, they may be rigid or semi-rigid conduits, such as, for example, stainless steel tubing.
When it is desired to move the bolt 16 from the closed position shown in
When it is desired to move the bolt 16 from the open position shown in
Reference is made to
Reference is made to
The valving element 74 is moveable within the internal passage 76 to direct the flow of air into and out of the control valve 38. The valving element 74 includes a first seal 86, a second seal 88, and a third seal 90. When the control valve 38 is in a first control valve position, as shown in
In the first control valve position shown in
Reference is made to
Furthermore, the first and second seals 86 and 88 cooperate to define a chamber around the first inlet port 56 and the first outlet port 60, permitting them to be in fluid communication with each other. Thus, in the position shown in
Referring to
The trigger 92 is operatively connected to the actuation system 18, and more specifically to the valving element 74 (
The paintball marker 10 shown in the embodiment in
Reference is made to
Referring to
After releasing air through the valve 302, the valving element 312 moves from the open position to the closed position (see
Any suitable means, eg. pneumatic pressure from the first low pressure regulator 40 (
Movement of the sear (not shown) may be accomplished by any means known in the art. For example, the sear may be actuated by a mechanical linkage connected to the trigger 92. Alternatively, movement of the sear may be controlled by an electric solenoid or by an electronic solenoid valve.
Reference is made to
When the trigger 92 (
The firing valve 302 may be configured to close by the same means used in the embodiment shown in
Reference is made to
Reference is made to
First and second housing sealing surfaces 332 and 334 extend on projections 332a and 334a, into the interior of the housing 324 from its inside wall 335. The housing sealing 332 and 334 may extend about the entire circumference of the housing 324. The first and second housing sealing surfaces 332 and 334 are positioned longitudinally between the inlet 328 and outlet 330, and are at selected longitudinal distances from each other in the housing 324.
The spool 326 is elongate and may be generally cylindrical. The spool 326 is movable in the housing 324 and extends through at least one end of the housing 324 to the exterior thereof. The spool 326 includes first and second spool sealing surfaces 336 and 338, which extend outwardly on projections 336a and 338a, from the spool exterior surface, shown at 340. The first and second spool sealing surfaces 336 and 338 may be spaced from each other by a distance that differs from the distance between the housing sealing surfaces 332 and 334. The spool 326 is movable in the housing between a first position (see
In the position shown in
The air storage chamber 344 shown in
The adjustment member 348 is preferably infinitely adjustable between over a range of adjustment. To provide infinite adjustability, the adjustment member 348 may, for example, include a threaded insert that sealingly engages a threaded aperture 349 in the air storage chamber 344. The volume of the chamber 344 can thus be controlled by screwing in or screwing out of the adjustment member 348. The adjustment member 348 is preferably adjustable by hand without the need for tools, to facilitate volume adjustment.
Referring to
The inlet 328 and outlet 330 on the pneumatic valve 322 may be of relatively large size on the valve 322, thereby reducing pressure drop therethrough, reducing the amount of time required to fill the firing air storage chamber 344 with firing air, and reducing the amount of time to release the firing air contained in the air storage chamber 344. One reason that the inlet 328 and outlet 330 may be sized relatively large, lies in the configuration of the sealing surfaces 332, 334, 336 and 338. Because the sealing surfaces 334 and 338 on the spool 326 do not engage or sweep past the inlet 328 or outlet 330, as they do on other types of spool valve, the inlet 328 and outlet 330 may be made relatively large without impacting the overall stroke required by the spool 326 to open or close the valve 322. The large inlet 328 and outlet 330 reduce the pressure drop thereacross, which increases the firing efficiency of the marker 10, in that less energy is lost during passage of firing air from the air storage chamber to the bolt 16. Furthermore a large inlet 328 and a large outlet 330 also reduce the amount of time required to fill the air storage chamber 344 to its target pressure, and also analogously reduces the amount of time required for the firing air to leave the air storage chamber 344.
By contrast, spool valves that incorporate sealing surfaces that sweep past the valve inlet and valve outlet (such as the spool valve 38 shown in
The spool 326 requires a relatively short stroke to move between the first or filling position shown in
The quick actuation of the valve 322 makes for an overall quicker firing of the paintball 12 from the time the trigger 92 is pulled. Furthermore, the overall cycle time to complete a firing of the paintball 12, which makes the marker 10 capable of an increased firing frequency.
The sealing surfaces 332 and 334, and 336 and 338 may have several configurations. For example, referring to
Referring to
Referring to
Referring to
In the configuration shown in
In the configurations shown in
The trigger 92 may be operatively connected to the spool 326 for movement of the spool 326 in the housing 324, by any suitable means. For example, the trigger 92 may be connected to the spool 326 by one or more of a mechanical linkage, a pneumatic connection, an electric solenoid, and an electronic solenoid valve.
An exemplary linkage 350 between the trigger 92 and the firing mechanism 300 is shown in
Preferably, the firing valve actuation valve 352 is sized to fit within the grip of the marker 10, shown at 356. The firing valve actuation valve 352 may be configured similarly to the firing valve 322, in that it contains sealing surfaces that do not sweep past the inlet and outlet ports. Referring to
The inlet 362 is connected fluidically to air from the first low pressure regulator 40 (see
The housing has first, second, third and fourth housing sealing surfaces 367, 368, 369 and 370, which are positioned on circumferential projections 367a, 368a, 369a and 370a respectively, which project into the interior of the housing 358 from its inside wall 371. The housing sealing surfaces 367, 368, 369 and 370 extend about the entire circumference of the housing 358. The sealing surface 367 is positioned longitudinally between the first exhaust port 365 and the first outlet 363. The sealing surface 368 is positioned longitudinally between the first outlet 363 and the inlet 362. The sealing surface 369 is positioned longitudinally between the inlet 362 and the second outlet 364. The sealing surface 370 is positioned longitudinally between the second outlet 364 and the second exhaust port 366. The sealing surfaces 367, 368, 369 and 370 are positioned at selected longitudinal distances from each other in the housing 358.
The spool 360 is elongate and may be generally cylindrical. The spool 360 is movable in the housing 358 and extends through at least one end of the housing 358 to the exterior thereof. The spool 360 includes first, second, third and fourth spool sealing surfaces 372, 373, 374 and 375, which are positioned on ring-shaped projections 372a, 373a, 374a and 375a, which extend outwardly from its exterior surface, shown at 376. The spool sealing surfaces 372, 373, 374 and 375 are positioned on the spool 360 at a selected spacing so that, when the spool 360 is in a firing position (see
When the spool 360 is in the non-firing position (see
The inlet 362, outlets 363 and 364, and exhaust ports 365 and 366 may be of relatively large size, thereby reducing pressure drop therethrough, and reducing the actuation time for the cylinder 354 by reducing resistance (ie. pressure drop) to air passing therethrough. The reasons for this are the same as the reasons provided above in relation to the valve 322.
Furthermore, the valve 352 requires a relatively short stroke of the spool 360 to move the spool 360 between the non-firing position shown in
The quick actuation of the valve 352 makes for an overall quicker actuation of the pneumatic cylinder 354. Because the valve 352 transmits the pulling of the trigger 92 to the valve 322 more quickly, the overall actuation of the firing valve 322 is quicker, which contributes to reducing the overall cycle time to complete a firing of the paintball 12 from the pulling of the trigger 92. The reduced firing cycle time makes for an increased firing frequency capability for the marker 10.
The sealing surfaces 367, 368, 369 and 370, and 372, 373, 374 and 375 may have several configurations. For example, referring to
Referring to
Referring to
Referring to
In the configuration shown in
In the configurations shown in
Referring to
The valve 352 may include a biasing mechanism 379 for biasing the spool 360 in the position shown in
The pneumatic cylinder 354 may be operatively connected to the spool 326 of the firing valve 322 in any suitable way. For example, the cylinder 354 may be integrally formed with the firing valve 322.
As shown in
The valve 380 may be similar in configuration to the valve 352, except that the outputs of the valve 380, shown at 382 and 384 are connected fluidically to the ports 386 and 388 on the pneumatic cylinder 390. The pneumatic cylinder 390 is operatively connected to the bolt 16. The valve may also include two exhaust ports 391 and 392, which are associated with the outlet ports 382 and 384 respectively.
The valve 380 may be configured to have a single input 393, as shown in
When the valve 380 is positioned in a second position, air from the second regulator 42 is directed through the inlet, out through the first outlet 382 and into the cylinder 390 through the port 386. In this position, air is also permitted to pass from the cylinder port 388, into the first valve 380 through the second outlet 384 and out through the second exhaust port 392. In this position, the cylinder 390 is driven to move the bolt 16 to a closed position, thereby chambering a paintball 12. It will be noted that the valve 380 configured as shown in
For quick actuation and good reliability, however, it is preferable to use at least one of the valves 322, 352 and 380 in the marker 10. Preferably, all three may be included in the marker 10 to control both the firing and the bolt movement without using solenoids.
The valve 380 may include a biasing mechanism 394 for biasing the valve 380 in either the first or second positions. Accordingly, the biasing mechanism effectively biases the bolt in either the bolt-open or bolt-closed positions. In the system shown in
The valve 380 may advantageously incorporate any of the configurations of sealing surfaces 372, 373, 274 and 375, and 367, 368, 369 and 370 shown in
Referring to
It will be noted that until the bolt 16 has chambered the paintball 12, the fluid path, shown at 396, from the firing valve 322 into the bolt 16 is closed (see
Releasing the trigger 92 returns the valves 352 and 380 to their rest positions. The bolt 16 returns to the open position to permit another paintball 12 into the breech 20. The firing valve 322 returns to the filling position for filing the air storage chamber 344.
It is alternatively possible for the marker 10 shown in
Referring to
In the embodiment shown in
Reference is made to
The first and second control valves 549a and 549b are spool valves and may be poppet-style spool valves. The first control valve 549a may, for example, be the bolt actuation valve 380 (
The first control valve 549a has a housing 553a and a spool 555a. The housing 553a of the first control valve 549a may have five gas ports, ie. an input port 557a, two outlet ports 557b and 557c and two vent ports 557d and 557e. For a given size of gas port 557a-e, a poppet-style spool valve provides for a relatively short stroke for the valve spool 555a, relative to a spool valve, such as the valve 38 shown in
The second control valve 549b may be similar to the first control valve 549a. The second control valve 549b has a housing 553b and a spool 555b. The housing 553b of the second control valve 549b may have five gas ports, ie. an input port 559a, two outlet ports 559b and 559c and two vent ports 559d and 559e.
The first and second valves 549a and 549b may have fewer than, or more than five gas ports. For example, one of the control valves 549a or 549b may be the bolt actuation valve 38, which has six ports. Alternatively, one or both of the control valves 549a and 549b may be a three port valve, and may have an input port, an outlet port and a vent port, and may be used to control a pneumatic component that uses gas to operate in one direction and a spring or some other biasing means to operate in a second direction.
The first and second valves 549a and 549b are free of solenoids (ie. they do not incorporate solenoids).
The first and second valves 549a and 549b are each movable between a first and a second position. Biasing means 561a may be provided for the valve 549a to bias the spool 555a in one of its first and second positions. Biasing means 561b may be provided for the valve 549b to bias the spool 555b in one of its first and second positions.
The first and second control valves 549a and 549b are operated sequentially by the trigger 92. The first valve 549a is the first valve of the two that is actuated by the trigger 92. The second valve 549a is the second valve of the two that is actuated by the trigger 92.
In embodiments wherein the first actuated valve 549a is the bolt actuation valve 380 (
The trigger 92 may include a finger grip portion 550, a pivot 552, a first valve actuation portion 554 and a second valve actuation portion 556. The pivot 552 permits the trigger 92 to pivot along a path with respect to the body 14 of the marker. The finger grip portion 550 is positioned for receiving one or more fingers of the player. The valve actuation portions 554 and 556 may directly actuate the spools 555a and 555b of the control valves 549a and 549b respectively, with no intermediate mechanical, pneumatic or electric linkage.
The relationship between the valve actuation portions 554 and 556 and the finger grip portion 550 is as follows. Forces F1 and F2 are the forces required to overcome the resistance of the first spool 555a and the second spool 555b respectively, thereby actuating the first valve 549a and the second valve 549b. To develop force F1 at the first valve actuation portion 554, a force Ffg1 is required to be exerted by the fingers of the user on the finger grip portion 550 of the trigger 92. The force Ffg1 required to develop the force F1 is dependent on, among other things, the moment arm shown at Mfg between the pivot 552 and the upper end shown at 576 of the uppermost locator bump shown at 578 on the finger grip portion 550, and the moment arm shown at M1 between the valve actuation portion 554 and pivot 552. The moment arm Mfg is measured from the upper end 576 of the uppermost locator bump 578 on the finger grip portion 550, because this point represents the center of the finger that would be positioned highest up on the finger grip portion 552, through which a user would exert a force to actuate the trigger. The relationship between Ffg1 and F1 is:
To develop force F2 at the first valve actuation portion 556, a force Ffg2 is required to be exerted by the fingers of the user on the finger grip portion 550 of the trigger 92. The force Ffg2 required to develop the force F2 is dependent on, among other things, the moment arm Mfg and the moment arm shown at M2 between the valve actuation portion 556 and pivot 552. Additionally, it will be noted that when actuating the second valve 549b, the user still exerts force F1 which is exerted to maintain the second position of the spool 555a in the first valve 549a. The relationship between Ffg2 and F2 is:
The valve actuation portions 554 and 556 may be positioned proximate the pivot 552 to reduce the force Ffg1 and Ffg2 required to be developed at the finger grip portion of the trigger, relative to a configuration with control valves positioned farther from the pivot 552. Reducing the force required to move the finger grip portion 550 to actuate the control valves 549a and 549b reduces the sensation of actuating a valve to a player during use, which in turn, reduces the tendency for the player to inadvertently release the trigger 92 prior to actuating both of the control valves 549a and 549b.
Positioning the valve actuation portions 554 and 556 close to the pivot 552 reduces the forces Ffg1 and Ffg2 required at the finger grip 550, as explained above. However, by positioning the valve actuation portions 554 and 556 closer to the pivot 552, the trigger 92 must travel through a correspondingly greater angular stroke for the actuation portions 554 and 556 to displace the spools 555a and 555b sufficiently to actuate the control valves 549a and 549b. It is desirable for the trigger 92 to have a relatively short stroke to effect actuation of the control valves 549a and 549b, since a shorter trigger stroke facilitates a higher firing rate for the marker 10. Accordingly, the positions of the valve actuation portions 554 and 556 may be selected so that the forces Ffg1 and Ffg2 are reduced while still providing an acceptably short trigger stroke.
The trigger 92 may have a stroke of between about 0.2 and about 5 mm, preferably between about 1 and about 3 mm and more preferably between about 1 and about 2 mm, as measured by the distance traveled by the upper end 576 of the uppermost locator bump 578 on the finger grip portion 550 between the rest position and the firing position for the trigger 92 wherein it has actuated both control valves 549a and 549b. This stroke is sufficiently short that a user can achieve a relatively high firing rate with the marker 10. Selecting the maximum travel of the trigger, accordingly affects how close the valve actuation portions 554 and 556 can be positioned to the pivot 552. In general, for a relatively longer trigger 92 stroke, the valve actuation portions 554 and 556 can be positioned relatively closer to the pivot 552. For a relatively shorter trigger 92 stroke, the valve actuation portions 554 and 556 would be positioned relatively farther to the pivot 552.
Adjustment means 558 and 560 may be provided in the valve actuation portions 554 and 556 respectively for adjusting where in the stroke of the trigger 92 each of the spools 555a and 555b are contacted. The adjustment means 558 and 560 may include set screws 562 and 564 respectively which are positioned in holes 566 and 568 respectively that pass through the trigger 92 so that they can be accessed with a suitable tool (not shown) from outside the marker. The set screws 562 and 564 have contact surfaces 570 and 572 respectively which engage and move the spools 555a and 555b respectively when the trigger 92 is pulled. The set screws 562 and 564 are individually adjustable in the holes 566 and 568 respectively to adjust where along the stroke of the trigger 92 each of the contact surfaces 570 and 572 make contact with the spools 555a and 555b respectively.
It will be appreciated that the amount of travel of the trigger 92 that exists between actuation of the two spools 555a and 555b at least in part determines the expected time interval between actuation of the valve 549a and actuation of the valve 549b. By providing two individually adjustable adjustment means 558 and 560, some control is provided for adjusting the aforementioned expected time interval.
In the embodiment shown in
Instead of positioning the control valves 549a and 549b one above the other, it is alternatively possible for the control valves 549a and 549b in a side-by-side configuration. Preferably, if the valves were side-by-side in the grip 356, they would be sufficiently thin so as not to make the grip 356 too wide to comfortably hold in one hand. The control valves 549a and 549b could alternatively be positioned side-by-side in the body 14 of the marker 10 where their width will not have an impact on the width of the grip 356. In an embodiment wherein the control valves 549a and 549b are side-by-side, they can both be positioned proximate the pivot 552 so as to provide a reduced sensation of actuation of their spools 555a and 555b during use. The trigger 92 could include actuation portions that are positioned side-by-side to engage the spools 555a and 555b.
In the embodiment shown in
It is, for example, optionally possible for the connection points to be aligned in an axially-extending row on the exterior of the control valves 549a and 549b. ‘Axially’ in this instance refers to the length direction of each of the control valves 549a and 549b. By providing all of the connection points in a row, the control valves 549a and 549b can be oriented so that their respective rows of pneumatic connection points face away from each other, thus permitting the control valves 549a and 549b to be positioned close together.
The connection points may be provided either directly on the control valves 549a and 549b themselves, or it may alternatively be provided by means of a separate manifold, shown at 573 in association with the valve 549a, and shown at 574 in association with the valve 549b. The manifolds 573 and 574 are mounted to the control valves 549a and 549b and each include a row of connection points for fluid conduits.
In the embodiment shown in
An optional biasing means 581 biases the trigger 92 towards the rest position shown in
As described above, there is a selected amount of travel of the trigger 92 that occurs after actuation of the first valve 549a and prior to actuation of the second valve 549b. The marker 10 may include any of several optional structures to prevent the spool 555a from traveling too far into the housing 553a of the first valve 549a and damaging the valve 549a during the trigger's travel towards actuation of the second valve 549b. For example, the valve 549a may be provided with the spool-type seals shown in
It is alternatively possible however, for the trigger 92 to connect to the control valves 549a and 549b indirectly by means of a mechanical connection, a pneumatic connection or a combination of the two. Reference is made to
The trigger 582 includes a finger grip portion 584, a pivot 586 about which the trigger 582 pivots along a path relative to the body 14 of the marker 10, a first valve actuation portion 588 and a second valve actuation portion 590.
The first and second valve actuation portions 588 and 590 may include set screws 562 and 564 which are positioned for engaging and actuating the control valves 549a and 549b at selected points along the stroke of the trigger 582. The set screw 562 may directly actuate the spool 555a of the valve 549a. The set screw 564 may be positioned proximate the set screw 562 and may be used to actuate the pivot arm 583, which operatively connects the trigger 582 to the valve 549b.
The pivot arm 583 pivots about a pivot 592 and has a free end 594, which is engageable by the set screw 564 on the trigger 582. The pivot arm 583 has a valve actuation portion 596 which may include a set screw 598 for engagement of the spool 555b of the valve 549b. Providing the pivot arm 583 permits the first and second valve actuation portions 588 and 590 to be positioned relatively close together. In the embodiment shown in
The set screw 598 permits adjustment of the position of the pivot arm 583 at which it engages and actuates the spool 555b.
It is optionally possible for the control valves 549a and 549b to include the manifolds 573 and 574, so that the control valves 549a and 549b are positionable relatively close together.
An optional biasing means 599 biases the trigger 582 towards the rest position shown in
In the embodiment shown in
In the embodiment shown in
Reference is made to
The trigger 600 has a finger grip portion 610, a pivot 612 and a master valve actuation portion 614. The master valve actuation portion 614 may include an adjustment means 615, eg. a set screw, which is adjustable for engaging and actuating the master valve 604 at a selected position in the stroke of the trigger 600. In the sense that the master valve actuation portion 614 actuates the master valve 604, which in turn is operatively connected to the first and second control valves 549a and 549b, the master valve actuation portion 614 is both the first and second valve actuation portions for the configuration of the marker shown in
The master valve 604 may be any suitable type of valve, such as, for example, a valve that is similar to one of the control valves 549a and 549b. For example, the valve 604 may be a spool valve, such as a poppet-style spool valve, and may have five ports, ie. an input port, two outlet ports and two vent ports. Providing a poppet-style spool valve for the valve 604 provides for a relatively short stroke for the valve spool, as explained above with respect to the control valves 549a and 549b. It is alternatively possible for the valve 604 to be a spool valve that is not a poppet-style. For example, the valve 604 could be similar to the valve 100 shown in
The master valve 604 is free of solenoids (ie. it does not incorporate a solenoid).
The master valve 604 has an input port 616 which receives input air from the first regulator 40 (see
The linkage cylinder 606 has a piston (not shown) to which a piston rod 630 is connected. The piston rod 630 extends out from the housing of the linkage cylinder 606 and is pivotally connected to a free end 632 of the pivot arm 608. The pivot arm 608 is mounted at its other end for pivotable movement with respect to the body 14 by means of a pivot 634. Actuation of the linkage cylinder 606, ie. extension and retraction of the piston (not shown) and piston rod 630, causes pivotal movement back and forth of the pivot arm 608. When the linkage cylinder 606 and the pivot arm 608 are in their respective first positions, as shown in
The pivot arm 608 includes a first set screw 638 and a second set screw 639 for engaging the spools 555a and 555b of the control valves 549a and 549b respectively. The first and second set screws 638 and 639 provide adjustability for the position of the pivot arm 608 when it actuates the two valves 549a and 549b. Providing the master valve 604 which actuates the two valves 549a and 549b eliminates the chance for inadvertent release of the trigger 600 prior to engagement of the two valves 549a and 549b.
A biasing means 640, such as a compression spring, may be included for urging the trigger 600 outwards. Furthermore, the master valve 604 may have a biasing means 641, such as a compression spring, for urging its spool, shown at 642, outwards. It is optionally possible that the biasing means 641 on the master valve 604 could be configured to act on the spool 642 with sufficient force that the spool 642 urges the trigger 600 back outwards after the trigger 600 is pulled, thereby eliminating the need for a separate biasing means 640.
Reference is made to
The trigger 643 is movable along a path between a rest position or first position, shown in
When the trigger 643 is pulled, ie. is moved in the first direction along its path, the arm 650 pushes against the spool 555a causing movement of the spool 555b into the valve housing 553b thereby actuating the valve 549b. Additionally, the arm 650 moves away from the valve housing 553a. The biasing means 561a on the valve 549a causes extension of the spool 555a from the valve housing 553a in the absence of resistance from the arm 650. Thus, movement of the arm 650 away from the valve 549a permits extension of the spool 555a to its second position.
The engagement of the spools 555a and 555b in this way reduces or eliminates the sensation of separately engaging the two spools 555a and 555b at different times.
The shapes of the arcuate surfaces 652 and 654 may be selected so that the arm 650 maintains a centered engagement on the spools 555a and 555b throughout the travel of the trigger 643.
During movement of the trigger 643 in the first direction, actuation of the valve 549a occurs when the spool 555a extends outwards sufficiently, and occurs prior to actuation of the valve 549b. After actuation of the first control valve 549a, the spool 555a may reach the end of its outward travel from the first housing 553a. The arm 650, however, continues moving against the spool 555b. After a sufficient amount of continued movement of the arm 650, the spool 555b is urged to its second position.
A biasing means 658 such as a compression spring may be positioned to urge the trigger 643 back towards its rest position. Once the trigger 643 is released by a player, the movement of the trigger 643 back to its rest position will push the spool 555a back towards the valve housing 553a. The biasing means 651b urges the spool 555b to extend outwards from the valve housing 553b. The biasing means 651b and 658 together provide sufficient force to overcome the biasing means 651 a. Movement of the arm 650 back to its rest position permits extension of the spool 555b back to its first position and urges the spool 555a back to its first position.
A manifold 662 may be provided which receives both of the control valves 549a and 549b thereon. The manifold 662 has all of the inlet and outlet ports for both valves. The inlet and outlet ports can thus all be positioned to extend outwards from the control valves 549a and 549b in a common direction. It is alternatively possible to provide two separate manifolds for the two valves 549a and 549b. It is also alternatively possible for the control valves 549a and 549b to not have manifolds.
It is not necessary for the valve actuation portions 648 and 649 to be positioned mutually opposite each other along the arm 650, or for them to be positioned at the same position axially along the length of the arm. They could alternatively be positioned at different axial positions along mutually opposed portions of the arm 650.
Reference is made to
The trigger 700 may be movable between a rest position and a second or firing position in any suitable way. For example, the trigger 700 may include a pivot 704 about which the trigger 700 pivots along a path. Instead of a pivot, the trigger 700 may alternatively slide along a path defined by guide means, such as a channel.
The trigger 700 further includes finger grip portion 706 and a valve actuation portion 708. The trigger 700 may further include an adjustment system 710 to set the limits of travel of the trigger 700 towards both the firing position and the rest position. The adjustment system 710 may include a first set screw 712 and a second set screw 714, which are both adjustable to abut the body 14 at selectable angular positions in the clockwise and counterclockwise directions of rotation of the trigger 700 about the pivot 704. The set screws 712 and 714 are preferably positioned in threaded apertures 716 and 718 which pass completely through the trigger 700 to permit access to the set screws 712 and 714 with a suitable tool without having to disassemble any portion of the body 14.
The trigger 700 may further include a biasing means 720, such as, for example, a compression spring, to bias the trigger 700 in the rest position.
The linkage 702 includes a master valve 722 to which the trigger 700 may be operatively connected by means of an intermediate link 724, which may be, for example, a pivot arm 726. The linkage 702 further includes a linkage cylinder 728, and a valve actuation link 730, which may be, for example, a pivot arm 732.
The master valve 722 is operatively connected to the first and second control valves 549a and 549b. The master valve 722 may be any suitable type of valve, such as, for example, a spool valve similar to valve 100 shown in
The master valve 722 has an inlet port 733, which may receive gas from either the first regulator 40 or alternatively from the second regulator 42 (
The master valve 722 has a housing 740 and an actuator 742, which may be, for example, a spool. The actuator 742 is movable between a first position shown in
The master valve 722 additionally includes a biasing means 744 to bias the actuator 742 to the first position. The biasing means 744 may be, for example, a compression spring.
The pivot arm 726 includes a pivot 745 about which the pivot arm 726 pivots with respect to the body 14. The pivot arm 726 has a first end 746 which is engaged by the valve actuation portion 708 on the trigger 700, and a second end 748 which engages the actuator 742 of the master valve 722.
The linkage cylinder 728 may be similar to the linkage cylinder 606 in the embodiment shown in
The piston 752 and piston rod 754 are movable between a first position (shown in
The master valve 722 and linkage cylinder 728 may together form part of a combined valve/cylinder unit 759. The combined valve/cylinder unit 759 may, for example, be similar to the valve/cylinder unit 212 shown in
The valve actuation pivot arm 732 includes a pivot 760 about which the pivot arm 732 pivots along a path with respect to the body 14. The pivot arm 732 has a first end 762 which is engageable by the linkage cylinder 728, and a second end 764 which is engageable with the control valves 549a and 549b. The first end 762 and the exposed end of the piston rod 754 may be connected by any suitable means, such as a pin connection. In an embodiment where the connection is a pin connection, a slotted hole may optionally be provided to receive the pin to permit a bit of overtravel by the cylinder 728 without causing damage to the valve 557a. Alternatively, the piston rod 754 may abut the second end 764 of the pivot arm 732 without being permanently connected thereto.
The second end 764 of the pivot arm 732 includes first and second valve actuation surfaces 766 and 768 which engage and actuate the control valves 549a and 549b during movement of the pivot arm 732 in both directions along the path about the pivot 760. The first and second valve actuation surfaces 766 and 768 may be arcuate to permit the pivot arm 732 to contact the centers of the ends of the spools 555a and 555b throughout the range of movement of the pivot arm 732. One or both of the valve actuation surfaces 766 and 768 may be on components that are spring loaded (eg. spring loaded metallic balls) that permit some movement of one or both of the actuation surfaces 766 and 768 in the event of overtravel of the cylinder 728 in either the outward or inward directions, thereby preventing damage to the valves 549a and 549b.
The pivot arm 732 is movable between a first position (shown in
A biasing means 770 may be provided to bias the pivot arm 732 towards its first position. For example, the biasing means 770 may be a compression spring positioned between the first end 762 and the cylinder housing 750. The biasing means 770 may also keep the first end 762 and the piston rod 754 in engagement with each other in embodiments wherein the piston rod 754 abuts the pivot arm 732 without being permanently attached thereto.
When the trigger 700 is depressed, the intermediate link pivot arm 726 is pivoted and pushes in the spool 742 of the master valve 722 to its second position, thereby sending gas to move the piston 752 and piston rod 754 inwards to their second positions. This, in turn, moves the pivot arm 732 to its second position whereat it permits the extension of the spool 555a to its second position and whereat it pushes the spool 555b to its second position. When the trigger 700 is released, the biasing means 720 moves the trigger 700 back to its rest position. The biasing means 744 pushes the actuator 742 of the master valve 722 outwards to its first position, which pushes the intermediate link pivot arm 726 to its first position. When the spool 742 is in the first position, the master valve 722 causes movement of the piston 752 and piston rod 754 to their respective first positions. As a result of the movement of the piston 752 and piston rod 754, the pivot arm 732 moves to its first position, eg. by means of the biasing means 770. In the first position of the pivot arm 732, it permits the extension of the spool 555b to its first position and it urges the spool 555a to its first position.
During movement of the pivot arm 732 along the path in a first direction from the first pivot arm position to the second pivot arm position, the first spool 555a is moved to its second position at a point earlier along the path than the point at which the second spool 555b is moved to its second position.
Conversely, during movement of the pivot arm 732 along the path in a second direction from the second pivot arm position to the first pivot arm position, the first spool 555a is moved to its first position at a point later along the path than the point at which the second spool 555b is moved to its first position.
The intermediate link 724 may have a structure other than the pivot arm 726 shown in
Instead of the pivot arm 732 shown in
Reference is made to
The linkage 802 includes the master valve 722 which may be engaged by the trigger 700 by means of the optional intermediate link 724, such as the pivot arm 726. The linkage 802 further includes a linkage cylinder 804, and a valve actuation link 806, which may be, for example, a pivot arm 808.
The linkage cylinder 804 may be similar to the linkage cylinder 728 (
The pivot arm 808 may be similar to the pivot arm 732 (
Depending on the operating pressures that can be used with the linkage 802, an optional regulator 828 may be provided which is configurable to operate at a different pressure than the first and second regulators 40 and 42.
A biasing means 830, such as a compression spring, may be provided to keep the pivot arm 808 in its first position, shown in
Reference is made to
The linkage 850 includes the master valve 722 which may be engaged by the trigger 700 by means of the optional intermediate link 724, such as the pivot arm 726. The master valve 722 communicates directly with the valve 549b. In the embodiment in
The pneumatic pilot section 858 is configured to move the spool 555b in one direction or the other depending on which pilot port 860 or 862 receives pressurized gas from the master valve 722. When gas is sent to one of the pilot ports 860 or 862, gas that is present in the other of the pilot ports 860 or 862 is vented through the master valve vent ports 743a and 743b.
The spool 555b is movable between a first position, shown in
When the trigger 700 is moved to its second position, ie. its firing position, the master valve 722 sends gas to the second pilot port 862 on the valve 852, thereby moving the spools 555a and 555b to their respective second positions. With their spools 555a and 555b in their respective second positions, the control valves 549a and 549b chamber and fire a paintball 12.
When the trigger 700 is released, the master valve 722 returns to its first position thereby sending gas to the first pilot port 860, which moves the spool 555b to its first position, which in turn permits the movement of the spool 555a to its first position. In the first position, the bolt 16 (
In the embodiment shown in
In the embodiments shown in
In the embodiments shown in
In the embodiments shown in
As shown in
In the embodiments shown in
In the embodiments shown in
In the embodiments shown particularly in
In the embodiments shown in
A selected set of linkages have been shown to connect the trigger to the control valves 549a and 549b in the embodiments shown in
In the embodiment shown in
The embodiment shown in
Reference is made to
It will be noted that the embodiments shown in
Reference is made to
Reference is made to
In similar fashion to the actuation system 18 (
The actuation system 96 includes a pneumatic cylinder 99, a control valve 100 and an actuation system regulator 101. The pneumatic cylinder 99 includes a housing 102 and a piston 104. The housing 102 may be similar to the pneumatic cylinder housing 44 (see
The piston 104 has a front face 110 and a rear face 112. A rod 114 may be connected at a first end to the rear face 112 of the piston 104, and at a second end to a back plate 116. The back plate 116 may, in turn, be connected to the bolt 97. The rod 114 may be a two stage rod, and may have a front portion 120 and a rear portion 121. The front portion 120 is connected to the rear face 112 of the piston 104, and extends out of the rearwardmost end of the pneumatic cylinder housing 102. Thus, the pressure bearing surface area of the rear face 112 is smaller than the pressure bearing surface area of the front face 110, because of the surface area occupied on the rear face 112 by the front portion 120 of the rod 114. For example, if the front portion 120 of the rod 114 is generally cylindrical, the pressure bearing surface area on the rear face 112 will be an annulus having a surface area that is equal to the overall surface area of the rear face 112 minus the cross-sectional area of the front portion 120. It will be noted that, the front portion 120 of the rod 114 extends out of the housing 102, throughout the range of motion of the piston 104. This provides a constant pressure bearing surface area on the rear face 112 of the piston 104, that is smaller than that of the front face 110. The pressure bearing surface areas on the rear and the front faces 112 and 110 are discussed further below.
The rear portion 121 has been described as being smaller in diameter than the front portion 120. It is alternatively possible for a rod to be provided wherein the rear portion is the same diameter as the front portion (ie. whereby the entire rod is of a constant diameter, and is suited to occupy a selected portion of the surface area on the rear face 112 of the piston 104). However, it is not necessary for the entire rod to be of a constant diameter.
The actuation system regulator 101 is mounted in fluid communication with the air conduit 98 to receive air from the primary regulator (not shown). More specifically, the paintball marker 94 may include a manifold 122 that has an internal air conduit 123 therein that is in fluid communication with the air conduit 98.
The manifold 122 has a first port 123a for connection to the actuation system regulator 101. The manifold 122 may optionally also include a second port 123b, which may be used as desired, or which may be plugged when not in use. It is alternatively possible for the primary regulator (not shown) to be connected directly into the manifold 122 using the optional port 123b, instead of being connected to the air conduit inlet 98a. In that case, it will be appreciated that the inlet 98a would require plugging.
The control valve 100 controls the movement of the piston 104 by controlling the flow of air from the regulator 101 to the first and second ports 106 and 108 on the pneumatic cylinder 99. The control valve 100 has a single inlet port 124, a first outlet port 126 and a second outlet port 128. The inlet port 124 is connected to the regulator 101 by means of a first conduit 130. The first outlet port 126 is connected to the first port 106 on the pneumatic cylinder 99 by means of a second conduit 132. The second outlet port 128 is connected to the second port 108 on the pneumatic cylinder 99 by means of a third conduit 134.
Reference is made to
Reference is made to
The movement of the valving element 138 between the first and second control valve positions may be initiated by moving a trigger 154 which may be connected to the valving element 138 by any suitable means (not shown). The connection means may be mechanical, pneumatic, hydraulic, electrical, electronic, or any combination thereof.
It will be noted that in the embodiment shown in
Reference is made to
The control valve 160 may be similar to the control valve 38 in the embodiment shown in
The regulator 162 may be similar to the regulator 42 in the embodiment shown in
The manifold 164 may be similar to the manifold 54 in the embodiment shown in
Referring to
An actuator, eg. a pneumatic cylinder 178 is operatively connected the bolt 176 for moving the bolt 176 between the open and closed positions. The pneumatic cylinder 178 includes a housing 180 and a piston 182. The housing 180 has a first port 184 and a second port 186.
A control valve 188 is used to control the movement of the piston 182 in the pneumatic cylinder 178. The control valve 188 may be similar to the control valve 100 in the embodiment shown in
The control valve 188 is used to direct air from the regulator 196 to either of the two ports 184 and 186 on the pneumatic cylinder 178. Thus, the same air pressure is used to drive the piston 182 in both directions, i.e., towards its forwardmost position, and towards its rearwardmost position. The pressure bearing surface area of the piston 182 is substantially the same on both its front face and its rear face, and as a result, the force exerted on the piston 182 by the air is substantially the same in both directions.
The paintball marker 158 may be connectable to a pressurized air tank 400 (
In order to prepare the paintball marker 158 for retrofit with the kit of parts 156, the control valve 188 is removed from the paintball marker 158. The manifold 196 may be removed from the paintball marker 158. The conduits 198, 200, and 202 are not required to be removed from the regulator 196 and the pneumatic cylinder 178, respectively.
The manifold 164 may be mounted to the body 172 so that the manifold air conduit 165 is in fluid communication with the air conduit 204. The control valve 160 (
Reference is made to
Optionally, the kit of parts 156 of
In the case where the existing manifold 206 (
Furthermore, the second regulator 162 (
Referring to
Reference is made to
The combined unit 212 has a body 218. The body 218 has a first portion 220 that serves as a cylinder housing, and a second portion 222 that serves as a control valve housing. A first port 224 and a second port 226 permit fluid communication between the cylinder housing 220 and the control valve housing 222. The first and second ports 224 and 226 serve as first and second outlet ports from the control valve 216, and also serve as first and second inlet ports for the cylinder 214.
A piston 228 is positioned in the cylinder housing 220. The piston 228 is moveable in the cylinder housing 220 between the first and second ports 224 and 226, based on the entry and discharge of pressurized air through the first and second ports 224 and 226. A rod 230 extends from the piston and may be connected directly or indirectly to a back plate on a paintball marker of the present invention.
The control valve housing 222 has a first end 232 in which there is a first vent 234, and a second end 236 in which there is a second vent 238. The first and second vents 234 and 238 permit pressurized air in the cylinder 214 to discharge as required during movement of the piston 228.
The control valve housing 222 has a first inlet port 240 and a second inlet port 242. The inlet ports 240 and 242 are positioned generally centrally, and may be circumferentially opposed to the first and second outlet ports 224 and 226, to facilitate connection to other components, such as conduits for pressurized air.
A valving element 244, which may be similar to the valving element 74, is positioned in the control valve housing 222. The valving element 244 is moveable within the control valve housing 222 to permit fluid communication between either the first inlet and outlet ports 240 and 224, or between the second inlet and outlet ports 242 and 226. If the first inlet and outlet ports 240 and 224 are permitted to communicate, eg. in the control valve position shown in
It has been described that the combined cylinder/control valve unit 212 could be provided with the paintball marker 10 (
Particular examples of flow control valve have been described above. It will be noted that any suitable type of flow control valve may be used instead of those described above.
In the embodiments described above the inlet control device 15 has comprised a bolt. It is alternatively possible for the inlet control device 15 to include any other suitable device instead of, or in addition to, a bolt. For example, referring to
As shown in
The door 420 may be operated pneumatically by the actuation system 18. The actuation system 18 may include, for example, the pneumatic cylinder 37, or may alternatively include any other suitable actuator.
Accordingly, the sliding door 420 could be operated advantageously with gas from the second regulator 42 (see
As a further alternative (not shown) to the inlet control device 15 shown in
Reference is made to
A gas outlet 440 may be provided at the aft end of the chamber 436 for releasing firing gas to the paintball for firing the paintball through the barrel 438. Referring to
In a further alternative (not shown) to the embodiment shown in
Reference is made to
When the barrel 450 moves aftwards to a closed position, it brings the paintball 12 into its inlet, since the paintball 12 is prevented from aft movement by the aft wall 454 of the breech 452. Also, in the closed position, paintballs are prevented from entry into the breech 452. Firing gas may then be released for firing of the paintball 12 from the barrel 450. The barrel 450 may be moved by means of the actuator 37, which may be a pneumatic cylinder 37. For example, the cylinder 37 may include a piston rod 458 which may be connected by any suitable means to the barrel 450 so that when the piston in the cylinder 37 moves, the barrel 450 moves.
The movable barrel may be controlled using gas at a selected sufficiently low pressure eg. by gas from the second regulator 42 (
One or both of the firing valve actuation valve 352 and the inlet control device and actuation valve 380, each of which has five ports, may alternatively be functionally replaced by two actuation valves 500a and 500b each having three ports. For example, the firing valve actuation valve 352 (
The first actuation valve 500a may be connected to the cylinder port 355a and may control filling and exhaustion of gas with respect to that port. The second actuation valve 500b may be connected to the cylinder port 355b for controlling filling and exhaustion of gas with respect to that port. The valves 500a and 500b may both be actuated directly from the trigger 92, as shown in
The valves 500a and 500b each may include a housing 501 and a spool 502. The housing 501 includes first second and third ports 503, 504 and 505. Housing sealing surfaces 506 and 507 may be positioned on housing projections 508 and 509, which are positioned between the first and second ports 503 and 504 and between the second and third ports 504 and 505 respectively. The spool 502 includes two spool projections 510 and 511, which have spool sealing surfaces 512 and 513 thereon respectively. The spool sealing surfaces 512 and 513 and the housing sealing surfaces 506 and 507 may be configured similarly to any of the configurations shown for sealing surfaces 372-375 and 367-370 in
The valve 500a may be configured so that the first port is an exhaust port, the second port 504 is connected to the cylinder port 355a, and the third port is connected to the first regulator 40.
Instead of both valves 500a and 500b being directly connected to the trigger 92, they may alternatively be mechanically or pneumatically connected to each other so that the trigger 92 engages one of the valves 500a and that valve engages the other of the valves 500a and 500b.
Referring to
In the embodiments wherein the markers have two regulators, one of which provides a higher pressure for opening the bolt, and one of which provides a lower pressure for closing the bolt. It is alternatively possible for the markers 10 and 210 to have a single regulator (not shown) that has two outputs, one output at a higher pressure and one output at a lower pressure, to replace the two separate regulators included in the markers 10 and 210.
In each of the embodiments described above, the outputs of the control valves have been shown to be connected to the ports on the pneumatic cylinder in a certain way. It is alternatively possible for the connections between the ports on the control valve and the ports on the pneumatic cylinder to be reversed, so that the control valve actuator would move forward to effect forward movement of the piston, and the control valve actuator would move rearward to effect rearward movement of the piston. Such a configuration may be used, depending on the mechanism connecting the trigger to the control valve.
It has been described as being advantageous to provide a paintball marker wherein a flow control valve is incorporated without a solenoid actuator, and with a mechanical or pneumatic connection to the trigger. One or more such flow control valves may be used to control one or both of the firing system and the inlet control device. By eliminating the solenoid, the reliability of operation of at least one of the firing system and the loading and chambering of a paintball is improved, since a solenoid or a sensor for contact by the trigger for actuating a solenoid, can be inadvertently rendered inoperative for example by a dead battery, or by damage during play from temperature conditions or from moisture. It will be appreciated that the marker in accordance with one particular embodiment of the present invention can include the one or more non-solenoid actuated flow control valves while still containing electronic components for control of other valves or other functions, such as an information display or in a loader flow assistor. In other embodiments of the present invention, the marker can include solenoid-actuated flow control valves, for example, in embodiments relating to the use of a selected low pressure used at least for closure of the inlet control device, and optionally for the opening of the inlet control device.
Reference has been made in this description to an air tank and to using air to operate the actuators in accordance with the present invention. It will be appreciated that any suitable gas may be used instead of air, to operate the actuators of the embodiments described herein.
Reference has been made to conduits throughout the description. In many instances, these conduits have been shown to be, for example, flexible hoses. The conduits may, however, be any suitable structure for conveying a fluid, eg. a compressed gas. The conduits may be flexible or solid. For example, they may be made from hose or tube, or alternatively they may be passages formed in components of the body of the marker or in some other component.
While the above description constitutes the preferred embodiments, it will be appreciated that the present invention is susceptible to modification and change without departing from the fair meaning of the accompanying claims.
Claims
1. A paintball marker, comprising:
- a body;
- a first pneumatic component;
- a second pneumatic component;
- a first control valve for controlling the flow of gas to actuate the first pneumatic component;
- a second control valve for controlling the flow of gas to actuate the second pneumatic component, wherein the first and second control valves are free of solenoids; and
- a trigger, wherein the trigger is pivotally connected with respect to the body for movement about a pivot, wherein the trigger includes a first valve actuation portion and a second valve actuation portion, wherein the trigger is operatively connected to the first and second control valves by means of the first and second valve actuation portions, and wherein the first and second valve actuation portions are proximate the pivot.
2. A paintball marker as claimed in claim 1, wherein the first and second control valves are positioned immediately adjacent one another and are directly engageable by the first and second valve actuation portions.
3. A paintball marker as claimed in claim 1, wherein the trigger is movable along a path and includes adjustment means for adjusting where along the path the trigger actuates the first and second control valves.
4. A paintball marker as claimed in claim 1, further comprising a pivot arm, wherein the pivot arm is pivotable with respect to the body, wherein the pivot arm is actuatable by one of the valve actuation portions of the trigger, and wherein the pivot arm is operatively connected to one of the control valves.
5. A paintball marker as claimed in claim 1, wherein the trigger has a finger grip portion and wherein the finger grip portion has at least one locator bump thereon, wherein one of the at least one locator bump is an uppermost locator bump, wherein the uppermost locator bump has an upper end, wherein the upper end of the uppermost locator bump is movable along a path between a rest position and a position wherein both the first and second valves are actuated, and wherein the path is between 0.2 and 5 mm long.
6. A paintball marker, comprising:
- a body;
- a first pneumatic component;
- a second pneumatic component;
- a first control valve for controlling the flow of gas to actuate the first pneumatic component, wherein the first control valve includes a first housing and a first spool, wherein the first spool is movable for actuation of the first control valve, wherein the first control valve includes a first biasing means for biasing the first spool to extend outward from the first housing;
- a second control valve for controlling the flow of gas to actuate the second pneumatic component, wherein the second control valve includes a second housing and a second spool, wherein the second spool is movable for actuation of the second control valve, wherein the second control valve includes a second biasing means for biasing the second spool to extend outward from the second housing, wherein the first and second control valves are free of solenoids; and
- a trigger, wherein the trigger is movably connected with respect to the body for movement along a path, wherein the trigger includes a first valve actuation portion and a second valve actuation portion, wherein the trigger is operatively connected to the first and second control valves by means of the first and second valve actuation portions, wherein the trigger includes an arm, wherein the first and second valve actuation portions are positioned on opposing sides of the arm and wherein the arm is movable in a direction towards one of the spools and away from the other of the spools.
7. A paintball marker as claimed in claim 6, wherein the first and second control valves are poppet-style spool valves.
8. A paintball marker as claimed in claim 6, wherein one of the first and second pneumatic components controls movement of an inlet control device for the paintball marker and wherein the other of the first and second pneumatic components controls movement of a firing valve for the paintball marker.
9. A paintball marker as claimed in claim 8, wherein the movement of the arm towards the second housing causes actuation of the first control valve prior to actuation of the second control valve taking place.
10. A paintball marker, comprising:
- a body;
- a first pneumatic component;
- a second pneumatic component;
- a first control valve for controlling the flow of gas to actuate the first pneumatic component;
- a second control valve for controlling the flow of gas to actuate the second pneumatic component;
- a master valve, wherein the master valve is operatively connected to the first and second control valves, wherein the master valve and the first and second control valves are free of solenoids; and
- a trigger, wherein the trigger is movably connected with respect to the body for movement along a path and wherein the trigger is operatively connected to the master valve.
11. A paintball marker as claimed in claim 10, further comprising a cylinder and a valve actuation link, wherein the valve actuation link is movable with respect to the body and is operatively connected to the first and second control valves, wherein the cylinder is operatively connected to the valve actuation link, and wherein the master valve is operatively connected to the cylinder.
12. A paintball marker as claimed in claim 11, wherein the first control valve has a first housing and a first spool, wherein the first spool is movable between a first position and a second position,
- wherein the second control valve has a second housing and a second spool, wherein the second spool is movable between a first position and a second position,
- wherein the valve actuation link is movable between a first valve actuation link position and a second valve actuation link position,
- wherein in the first valve actuation link position the valve actuation link urges the first spool to the first position for the first spool and the second spool is biased to the first position for the second spool,
- and wherein in the second valve actuation link position the valve actuation link urges the second spool to the second position for the second spool and the first spool is biased to the second position for the first spool.
13. A paintball marker as claimed in claim 12, wherein the valve actuation link is movable along a valve actuation link path in a first direction from the first valve actuation link position to the second valve actuation position, wherein the second spool reaches the second position for the second spool at a point along the valve actuation link path in the first direction and the first spool reaches the second position for the first spool at an earlier point along the valve actuation link path in the first direction.
14. A paintball marker as claimed in claim 13, wherein the valve actuation link is movable along a valve actuation link path in a second direction from the second valve actuation link position to the first valve actuation link position, wherein the second spool reaches the first position for the second spool at a point along the valve actuation link path in the second direction and the first spool reaches the first position for the first spool at a later point along the valve actuation link path in the second direction.
15. A paintball marker as claimed in claim 10, wherein one of the first and second pneumatic components controls movement of an inlet control device for the paintball marker and wherein the other of the first and second pneumatic components controls movement of a firing valve for the paintball marker.
16. A paintball marker as claimed in claim 10, wherein the first control valve has a first housing and a first spool, wherein the first spool is movable between a first position and a second position and wherein the second control valve has a second housing and a second spool, wherein the second spool is movable between a first position and a second position.
17. A paintball marker as claimed in claim 16, wherein the first and second control valves are poppet-style spool valves.
18. A paintball marker as claimed in claim 16, wherein the master valve has a first outlet port and a second outlet port and wherein the second control valve has a pilot section, wherein the pilot section controls the movement of the second spool, wherein the second spool is operatively connected to the first spool such that movement of the second spool to the second position for the second spool urges the first spool to the second position for the first spool.
19. A paintball marker, comprising:
- a body;
- a firing valve actuation cylinder;
- a bolt actuation cylinder;
- a first control valve for controlling the flow of gas to actuate one of the firing valve actuation cylinder and the bolt actuation cylinder, wherein the first control valve has a first housing and a first spool, wherein the first spool is movable between a first position and a second position;
- a second control valve for controlling the flow of gas to actuate the other of the firing valve actuation cylinder and the bolt actuation cylinder, wherein the second control valve has a second housing and a second spool, wherein the second spool is movable between a first position and a second position;
- a valve actuation link, wherein the valve actuation link is movable with respect to the body between a first valve actuation link position and a second valve actuation link position, wherein the valve actuation link is operatively connected to the first and second control valves, wherein in the first valve actuation link position the valve actuation link urges the first spool to the first position for the first spool and the second spool is biased to the first position for the second spool, and wherein in the second valve actuation link position the valve actuation link urges the second spool to the second position for the second spool and the first spool is biased to the second position for the first spool;
- a linkage cylinder, wherein the linkage cylinder is operatively connected to the valve actuation link;
- a master valve, wherein the master valve is operatively connected to the linkage cylinder, wherein the master valve and the first and second control valves are free of solenoids; and
- a trigger, wherein the trigger is movably connected with respect to the body and wherein the trigger is operatively connected to the master valve.
20. A paintball marker as claimed in claim 19, wherein the valve actuation link is movable along a valve actuation link path in a first direction from the first valve actuation link position to the second valve actuation position, wherein the second spool reaches the second position for the second spool at a point along the valve actuation link path in the first direction and the first spool reaches the second position for the first spool at an earlier point along the valve actuation link path in the first direction.
21. A paintball marker as claimed in claim 20, wherein the valve actuation link is movable along a valve actuation link path in a second direction from the second valve actuation link position to the first valve actuation link position, wherein the second spool reaches the first position for the second spool at a point along the valve actuation link path in the second direction and the first spool reaches the first position for the first spool at a later point along the valve actuation link path in the second direction.
22. A paintball marker as claimed in claim 21, wherein the first control valve controls the flow of gas to actuate the firing valve actuation cylinder.
23. A paintball marker as claimed in claim 21, wherein the first control valve controls the flow of gas to actuate the bolt actuation cylinder.
Type: Application
Filed: Jan 24, 2005
Publication Date: Jul 7, 2005
Inventor: Paul Jong (Markham)
Application Number: 11/039,801