The present invention relates to a launcher such as a gun to propel various kinds of projectiles. There are various kinds of guns on the market but the industry has long needed a gun that is capable of shooting projectiles at various velocities and distances in a non-lethal as well as lethal mode.
In accordance with the invention there is a provided a propellant operated gun that is capable of shooting projectiles at various velocities and distances wherein the projectile can have a lethal or non-lethal effect.
Specifically, the velocity of the projectile can be varied from a low velocity to a high velocity whereby over certain distances they will be in a lethal or non-lethal mode. This is essentially accomplished by varying the amount of the fuel that is introduced into the propellant chamber. In an embodiment of the disclosed invention both a single-shot manually reloaded model has been illustrated as well as one having a magazine to allow the operator to fire the launcher a number of times with a pumping action. It can also be provided with an automatic range finding device to automatically vary the propellant levels to achieve the desired velocity for a given distance so that the projectile is being fired at the desired lethal or non-lethal velocity.
Another embodiment disclosed in
As an example only, the gun could be set to fire a projectile at approximately 150 feet per second (low velocity) where it would be non-lethal at all but very short distances. If the velocity of the projectile was on the order of 280 feet per second (medium velocity) the projectile would be non-lethal when used for firing at distances of 30 to 100 meters. It is possible that the projectile would be lethal at close quarters on the order of 10 meters or less. If the velocity of the projectile was on the order of 450 feet per second (high velocity), it is non-lethal when used for firing at distances on the order of 50-150 meters. At such velocity it would be possibly lethal if it struck a target at a distance on the order of 30 meters or less.
In addition it is noted that various types of projectiles could be used whose function is to break apart on impact but have sufficient mass so that the impact will stop the combatant but not injure or kill. A typical projectile has a bullet shaped shell having a plastic outer sheathing and contains bismouth.
a is a rear right side perspective view of the launcher including the rangefinder assembly, a host weapon mounting rail receiver and stock adapter receiver;
b is a front left side perspective view of the launcher. It includes the rangefinder sight as well as the rangefinder emitter and rangefinder detector;
c is a left side perspective view of the launcher. the stock adaptor and M4 stock has been shown for standalone operation with the rangefinder sight and barrel being added for reference;
a is a component close-up view of the cylinder, valve sleeve and pistol grip with the valve sleeve positioned where the exhaust and intake scavenging ports are closed by the valve sleeve to exclude moisture and debris;
b is a close-up view of the shuttle plate, projectile shuttle and intake scavenging ports wherein the projectile shuttle is in alignment with the barrel to allow combustion pressure to push a projectile through the barrel;
c is a component close-up view of the cylinder and valve sleeve wherein the valve sleeve has been rotated to where the exhaust scavenging ports and intake scavenging ports are open by the valve sleeve to allow for the passage of fresh air intake into the cylinder and the flow of spent combustion by products out of the cylinder;
d is a close-up view of the shuttle plate and projectile shuttle with the projectile shuttle in alignment with the magazine wherein a single projectile can move into the projectile shuttle and moved into the position illustrated in
e is a component close-up view of the cylinder and valve sleeve wherein the valve sleeve is in a position to open the exhaust and intake ports; and
f is in a position where the projectile shuttle is in alignment with the magazine wherein a single projectile can move into the projectile shuttle and moved into the position illustrated in
Illustrated in
Turning now to
The projectile 16 is placed in the barrel 14 and pushed to the back where there is a stop 18 to restrict the projectile 16 from entering the combustion chamber 13. The fit between the projectile 16 and the barrel 14 is sufficiently tight as to allow the projectile 16 to act as a sealing unit for the combustion chamber.
In the embodiment illustrated there is shown a manually movable piston 20 by a knob 22 connected to the piston shaft 24. Extending through the shaft 24 is a fuel hose 26 that directs fuel into the chamber 13 where it is to be ignited. During the manual operation of the launcher, the knob 22 is moved forward to push the air through the exhaust passage 28 in piston 20 and past exhaust reed valves 30.
It is to be noted that the piston 20 is sealed to the interior wall of the combustion chamber housing 12 by a seal ring 32. When the knob 22 is moved rearward the exhaust reed valves 30 are closed and the intake reed valves 34 are opened to allow fresh air to enter the combustion chamber 13. Once the piston 20 is in the most rearward position then a predetermined amount of propellant is introduced as described hereinafter.
The combustion chamber 13 receives propellant fuel such as MAPP gas or other appropriate propellant through an output hose 26. The propellant is stored in the containment vessel 36 that leads to quick connect assembly 38 and flows through a solenoid operated valve 40 that is timed to provide the requisite propellant for the velocity of the launch required.
In the illustrated embodiment there are three switches 42, 44 and 46 shown which when actuated will instruct the microprocessor that is powered by batteries 48 to open the propellant solenoid operated valve 40 a predetermined number of milliseconds.
For example when switch 42 is closed the microprocessor 50 will open the propellant solenoid 40 for a predetermined number of milliseconds to provide sufficient propellant for a low velocity launch on the order of 150 feet per second that will be non-lethal at all but very short distances; when switch 44 is closed the microprocessor 50 will open the propellant solenoid 40 for an increased predetermined numbers of milliseconds to provide sufficient propellant for a medium velocity launch on the order of 280 feet per second which will be non-lethal at a typical range on the order of 30-100 meters but may possibly be lethal at a close range on the order of 10 meters or less; and when switch 46 is closed the microprocessor 50 will open propellant solenoid 40 for an increased predetermined number of milliseconds to provide sufficient propellant for a high velocity launch on the order of 450 feet per second which will be non-lethal at a typical range of 100-150 meters but may possibly be lethal at a range on the order of 30 meters or less.
The propellant then flows through high pressure output hose 52 pressure regulator 54 and check valve 55 into the output hose 26 leading into the combustion chamber 13.
When the launcher is to be operated the trigger ignition switch 56 is depressed to send an electrical signal to the ignition circuitry 58 which is powered by a battery 60 that energizes high voltage coil 62. The high voltage coil produces a spark in the combustion chamber 13 to ignite the propellant air mixture to launch the projectile from barrel 14.
The unit is cycled through to exhaust the spent gases from chamber 12 and bring fresh air into the combustion chamber for the next launch.
It is to be noted that the propellant quantity could be adjusted via an automatic rangefinder 64 that would signal the programmer 50 to adjust the velocity based on the distance to the target and whether it is to be lethal or non-lethal. Also, the rangefinder could include a safety feature therein where the weapon will not fire below a certain distance when it is to be in a non-lethal mode. Examples would be on the order of 5 meters when firing at a low velocity; 10 meters at a medium velocity and on the order of 30 meters when firing in a high velocity mode.
We turn now to
In
Current from the batteries 104 is supplied to the microprocessor 106 to control the opening of the solenoid 108. Microprocessor 106 also controls the timing of ignition unit 110 to ignite the propellant mixture contained in combustion chamber 112.
Propellant is contained under pressure in fuel canister 114. Fuel canister 114 is located in grip 116 and is held in place by a cap (not shown). Fuel canister 114 has a spring valve 118 located at its apex similar to many aerosol cans on the market. Spring valve 118 pushes against propellant output seal (not shown) and the released Propelant flows through high pressure line 115. Propellant then flows through pressure regulator 122 check valve 124 and into solenoid valve 108 and then through fuel line 109.
Connected to ignition module 110 is ignition wire 126. At the end of ignition wire 126 is a water proof boot 128. The ignition wire 126 is connected to spark point 130. Spark point 130 is attached to cylinder 132 which makes up the cylindrical walls of combustion chamber 112.
Connected to cylinder 132 is front end plate 134 held in place by fasteners (not shown). In front end plate 134 are exhaust ports 135 (see
Also in cylinder 132 is output pressure fitting 139 that includes passage 140 that directs the combustion gas to the spool valve assembly 142 via spool valve connector 144. Spool valve assembly 142 has spool 146 that controls the flow of combustion gas to the barrel 152. The spool is under spring tension by spring 148 (see
In cylinder 132 there is spring loaded piston 154 for the transfer of spent combustion gases from one side of the piston 154 to the other. See
While the above provides a general overview of the launcher we can best describe the details of the various segments of the launcher by reference to enlarged sections since the single sectional view 3A does not provide adequate space for the necessary description.
We will now cover the essential components of the launcher in detailed figures thereof.
In
Turning now to
When the operator selects a power level a signal is sent to the microprocessor 106 which in turn will open the solenoid valve 108 for an appropriate amount of time to allow the proper amount of propellant to flow into the combustion chamber 112 that once ignited will launch the projectile at an appropriate speed to have the desired effect (either lethal or non-lethal). As illustrated in
We turn now to the firing of the launcher which is best understood from
In
In
In
After a projectile has been driven the burnt gas remaining in the combustion chamber 112 must be evacuated. After a projectile has been fired the operator grips the handle 166 and the shaft 164 is moved to the position shown in
After the spent gases are exhausted the piston 154 is moved forward as shown in
In
The front plate 134 is sealed to the exterior of the cylinder 132 by o-ring 222 and the rear plate 212 is sealed to the interior of the cylinder by o-ring 224.
In
In
Following the discussion of the details of the magazine and range finder the method of operation of the projectile launcher will be described in detail.
In
Method of Operation is as Follows:
With the launcher in the position shown in
The requisite amount of gas flows into the combustion chamber 112 and the fuel therein is ignited by the ignition module 110 through the igniter wire 126. The spark point 130 ignites gas in the combustion chamber which forms an explosive mixture and flows through the outlet fitting 139 into passage 140 leading to the spool valve assembly 142. The spool 146 moves forward to allow the combustion gases to flow through port 200 around the spool 146 out port 202 and passage 204 into the barrel 152 and eject the projectile 227 at the desired velocity. The projectile is directed from the magazine 206 by the spool assembly into the barrel 152 just prior to the opening of the gas inlet port 200.
To fire a second projectile 227 the pump handle is moved to the left from that shown in
The launcher is now in the position shown in
We turn now to
In
In
In
In
In
In
In
a is a rear right side perspective view of launcher 300. Mounted on launcher 300 is rangefinder bracket 414. Rangefinder bracket 414's design is bidirectional in that it can be mounted on the right or left side of Launcher 300. In
b is a front left side perspective view of launcher 300. Rangefinder bracket 414 has been repositioned to left side of launcher 300. Rangefinder sight 416 also has been repositioned to the left side of launcher 300. On forward portion of rangefinder sight is rangefinder emitter 426 as well as rangefinder detector 428 which could have see through optics for operator sighting of intended target.
c is a left side perspective view of launcher 300. Stock adapter 340 has been added as well as M4 stock 344 for standalone operation. Rangefinder sight 416 and barrel 334 have been added for reference.
a is a component close up view of cylinder 312, valve sleeve 346, and pistol grip 314. Valve sleeve 346 has been rotated by intelligent gear box 350 through small gear 354 and large gear 356 to a position where exhaust scavenging ports 374 and intake scavenging ports 375 are closed by valve sleeve 346. This is the normal non operational position of valve sleeve 346 to exclude moisture and debris.
b is a close up view of shuttle plate 324, projectile shuttle 338, and intake scavenging ports 375. Projectile shuttle 338 is in alignment with bore of barrel 334 to allow combustion pressure to push projectile 406 through barrel 334.
c is a component close up view of cylinder 312, valve sleeve 346, and pistol grip 314. Valve sleeve 346 has been rotated by intelligent gear box 350 through small gear 354 and large gear 356 to a position where exhaust scavenging ports 374 and intake scavenging ports 375 are open by valve sleeve 346. In this position exhaust scavenging ports 374 and intake scavenging ports 375 allow for the passage of fresh intake air into the cylinder and the flow of spent combustion byproducts out of the cylinder. The valve sleeve 346 has been rotated to a position 45 degrees counter clockwise as viewed from the rear of launcher 300.
d is a close up view of shuttle plate 324, projectile shuttle 338, and exhaust scavenging ports 374. Projectile shuttle 338 is in alignment with magazine 336 in the left hand position in shuttle plate 324. In this position a single projectile 406 can move into projectile shuttle 338 and be moved into the position illustrated in
e is a component close up view of cylinder 312, valve sleeve 346, and pistol grip 314. Valve sleeve 346 has been rotated by intelligent gear box 350 through small gear 354 and large gear 356 to a position where exhaust scavenging ports 374 and intake scavenging ports 375 are open by valve sleeve 346. In this position exhaust scavenging ports 374 and intake scavenging ports 375 allow for the passage of fresh intake air into the cylinder and the flow of spent combustion byproducts out of the cylinder. The valve sleeve 346 has been rotated to a position 90 degrees clockwise as view from the rear of launcher 300 from position illustrated in
f is a close up view of shuttle plate 324, projectile shuttle 338, and exhaust scavenging ports 374. Projectile shuttle 338 is in alignment with magazine 336 in the right hand position in shuttle plate 324. In this position a single projectile 406 can move into projectile shuttle 338 and be moved into the position illustrated in
Launcher operation is accomplished through the following sequence of steps. Operator either moves power switch 321 (
Once the intended target distance or operator power level has been determined the microprocessor electronics 320 energizes scavenging propellant oxidizer mixing fan motor 364 (
Propellant regulator 390 (see
Microprocessor electronics 320 energizes propellant solenoid valve 357 for a determined amount of time through manual input from buttons low 430, medium 432, or high 434 (
Output from propellant solenoid valve 357 and oxidizer solenoid valve 359 are plumbed together to output hose 372. Output hose 372 is connected to propellant, oxidizer tube spark holder 362. Propellant, oxidizer tube spark holder 362 introduces propellant or a propellant oxidizer mixture into cylinder 312. In propellant, oxidizer introduction tube 394 is a plurality of orifice holes 396 (
During the previous operations the scavenging fan motor 364 has continued to rotate scavenging propellant oxidizer mixing fan 366 at an appropriate speed for the desired power level.
Microprocessor electronics 320 energizes ignition module 322. Ignition module 322 provides a high voltage signal to spark wire 376 (
The subsequent combustion in the cylinder 312 increases the pressure in the cylinder 312 which in turn acts upon the anterior portion of the projectile 406 to move projectile 406 through barrel 334. Although as illustrated here barrel 334 contains rifling lands 368 to impose spin on a projectile as it moved down the barrel 334 a smooth bore barrel may be used depending upon the given performance requirements.
After projectile 406 leaves barrel 334 microprocessor electronics 320 energizes intelligent gear box 350 that is mechanically connected to projectile shuttle 338 which is rotated to a position that is the projectile shuttle 338 in alignment with recess 380 for the desired magazine 336. Also connected to output of intelligent gear box 350 is small gear 354 that is in mesh with large gear 356. Small gear 354 is moved the same number of degrees as projectile shuttle 338. Large gear 356 rotates a proportional amount compared to small gear 354. Attached to large gear 356 is valve sleeve link 358 connected to valve sleeve bell crank 348 which is mechanically connected through cylinder 312 to valve sleeve 346 to open exhaust scavenging ports 374 and intake scavenging ports 375. Scavenging fan motor 364 rotates scavenging fan 366 at an appropriate speed for the desired power level to draw fresh air in to cylinder 312 and to sweep out spent combustion by products.
If operation is complete projectile shuttle 338 returns to a position in alignment with barrel 334 and scavenging fan motor 364 ceases to operate. Microprocessor electronics 320 places launcher 300 into standby mode until input from operator.
If additional launches are desired and trigger 316 has remained depressed projectile shuttle 338 is rotated to a position that aligns projectile shuttle 338 with recess 380 for the desired magazine 336. The operational cycle is repeated until trigger 316 is released. The microprocessor electronics 320 allows for different scenarios of operation with automatic escalation of force possible as well as automatic selection of different projectiles 406 with each launch.
It is intended to cover by the appended claims all embodiment that fill within the true spirit and scope of the invention.
This application is a continuation-in-part of U.S. Non-Provisional application Ser. No. 12/469,336, filed May 20, 2009, entitled Projectile Launcher, which claims the benefit of U.S. Provisional Application No. 61/054,741, filed May 20, 2008.
Number | Name | Date | Kind |
---|---|---|---|
3888159 | Elmore et al. | Jun 1975 | A |
4050348 | Graham | Sep 1977 | A |
4109557 | Zaucha | Aug 1978 | A |
4148245 | Steffanus et al. | Apr 1979 | A |
4281582 | Jaqua | Aug 1981 | A |
4341147 | Mayer | Jul 1982 | A |
4693165 | Magoon et al. | Sep 1987 | A |
4745841 | Magoon et al. | May 1988 | A |
4852458 | Bulman | Aug 1989 | A |
4930423 | Bulman | Jun 1990 | A |
4934242 | Bulman | Jun 1990 | A |
4949621 | Stephens | Aug 1990 | A |
5202530 | Stephens | Apr 1993 | A |
5333594 | Robinson | Aug 1994 | A |
5398591 | Gay | Mar 1995 | A |
5499567 | Gay | Mar 1996 | A |
5592931 | Johnson et al. | Jan 1997 | A |
5699781 | Johnson et al. | Dec 1997 | A |
5971245 | Robinson | Oct 1999 | A |
6439216 | Johnson et al. | Aug 2002 | B1 |
6752137 | Brunette et al. | Jun 2004 | B2 |
7254914 | Lund et al. | Aug 2007 | B2 |
7337774 | Webb | Mar 2008 | B2 |
7658185 | Perry | Feb 2010 | B2 |
7806113 | Skilling | Oct 2010 | B2 |
7926408 | Kley | Apr 2011 | B1 |
8015907 | Tippmann, Sr. | Sep 2011 | B2 |
8281776 | Korver et al. | Oct 2012 | B2 |
8322329 | Sikes | Dec 2012 | B1 |
8651096 | Sikes | Feb 2014 | B2 |
20050011507 | Webb | Jan 2005 | A1 |
20060266206 | Lund et al. | Nov 2006 | A1 |
20070028909 | Wood | Feb 2007 | A1 |
20070062363 | Broersma | Mar 2007 | A1 |
20070186761 | Perry | Aug 2007 | A1 |
20090199830 | Skilling | Aug 2009 | A1 |
20090241931 | Masse | Oct 2009 | A1 |
20100154766 | Skilling | Jun 2010 | A1 |
20100313742 | Silva | Dec 2010 | A1 |
20110017189 | Skilling | Jan 2011 | A1 |
20110073093 | Korver et al. | Mar 2011 | A1 |
20120031386 | Masse | Feb 2012 | A1 |
20120216697 | Jacobsen et al. | Aug 2012 | A1 |
20120298088 | Olden et al. | Nov 2012 | A1 |
20130092141 | Masse | Apr 2013 | A1 |
20130104868 | Sikes | May 2013 | A1 |
Number | Date | Country | |
---|---|---|---|
61054741 | May 2008 | US |
Number | Date | Country | |
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Parent | 12469336 | May 2009 | US |
Child | 13331470 | US |