Automatic pistol slide with laser

Abstract

A slide for an automatic pistol includes a cavity, a housing in the cavity, a laser module at least partially received in the housing, a power source, circuitry, and a striker. The slide has a first mode in which it emits laser light and a second mode in which it does not emit laser light. The striker has a first position in which it does not cause the laser module to emit laser light. When the pistol's trigger is pulled, the pistol's firing pin contacts the striker and moves the striker backwards from the first position to a biased position. When the firing pin moves out of contact with the striker, the striker moves forward to a second position and causes the circuitry to transmit power from the power source to the laser module, which causes the laser module to emit laser light.

Description

FIELD OF THE INVENTION

The present invention relates to a laser trainer used with an automatic pistol having a slide.

BACKGROUND OF THE INVENTION

Conventional firearm training can be dangerous, expensive (considering the prices for ammunition and replacement targets) and can only be performed in certain areas, such as shooting ranges. The present invention allows firearm training to be performed safely, inexpensively, and almost anywhere without the use of live ammunition. Incorporated herein by reference is an exploded Figure of a Glock 17 Nomenclature Anglais/Francais and U.S. Pat. No. 9,170,079 entitled LASER TRAINER CARTRIDGE, to the extent these disclosures are not inconsistent with the disclosure in this application.

SUMMARY OF THE INVENTION

Aspects of the invention are directed to a slide that fits on an automatic pistol (or “pistol” or “gun”). Included as part of the slide is a housing in which a laser, printed circuit board (“PCB”) or other circuitry, and a power source are positioned. A striker has a (1) first position, wherein power from the power source powers the laser, and (2) second position, wherein power from the power source does not power the laser.

In a preferred embodiment, when the pistol's trigger is pulled it causes the firing pin of the pistol to contact the striker and move the striker backwards away from its first position. This creates tension (preferably by expanding a spring) to move the striker forward when the firing pin disengages from the striker. The striker preferably has a portion that acts as a cam and eventually moves away from the firing pin as the striker is pulled back. When the firing pin moves away from and disengages the striker, the tension on the striker causes it to move forward past its first position to its second position. When in the second position it preferably contacts a switch, such as a momentary switch, that contacts the PCB and completes a circuit to send power from the power source to the laser. This causes the laser to emit light for a short duration, such as about 0.1 seconds, although any suitable duration may be utilized. After the striker moves to its second position, it moves back to its first position, preferably due to being biased by the spring, which is compressed when the striker is in its second position.

The slide may also include a trigger reset assembly, which would preferably be included in the housing. The trigger reset assembly applies force as the trigger is pulled. The force approximates or equals the normal force of pulling the trigger when using live ammunition. When the trigger is pulled and the firing pin is activated, the trigger reset assembly biases the trigger forward back to the trigger's reset position, so it can again be pulled without having to adjust the slide to reset the trigger.

The slide can either be mounted on the pistol when the pistol is sold, or the slide can be provided separately. If a slide according to the aspects of the invention is provided separately, any slide already on the pistol is removed. The pistol barrel and recoil spring are then removed from the slide that was on the pistol, and those are positioned in a slide according to aspects of the invention. The slide according to aspects of the invention is then placed on the pistol. The method of removing a slide, barrel and recoil spring, and assembling the barrel and recoil spring onto a slide and replacing a slide on an automatic pistol is known by those skilled in the art. Such a method is also usually included as part of the owner's manual for an automatic pistol.

A gun using the invention can hold a fully-loaded magazine, which helps target practicing with a gun having its normal weight when using live ammunition.

A slide according to aspects of the invention may also include a gun barrel and/or recoil spring already mounted on it. Further, a slide according to aspects of the invention could be included as part of a kit that includes multiple nose assemblies to fit various automatic pistol calibers and/or multiple slides.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an assembled view of a slide according to aspects of the invention.

FIG. 2 is an exploded view of the slide of FIG. 1.

FIGS. 3A-3C are different nose assemblies that can be used as part of a slide according to aspects of the invention.

FIG. 4 is an assembled view of a housing according to aspects of the invention that includes a laser.

FIG. 5 is an exploded view of the housing of FIG. 4.

FIG. 6 is an assembled view of a striker in accordance with aspects of the invention.

FIG. 7 is an exploded view of the striker of FIG. 6.

FIG. 8 is a bottom view of the slide of FIG. 1.

FIG. 9 is an alternate bottom view of the slide of FIG. 1.

FIG. 10 is a side view of an exemplary automatic pistol.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Turning now to the Figures, wherein the purpose is to describe preferred embodiments of the invention and not to limit same, FIG. 1 shows a slide 10 in accordance with aspects of the invention. Slide 10 has a first end 12, a second end 14, and a body 16. Body 16 has a partial cavity 18 to assist in gripping and moving slide 10. First end 12 is part of a nose assembly 20. Nose assembly 20 is interchangeable with other nose sections 60, 80, and 100, so slide 10 can fit different pistols, such as (for example) a Glock 17, a Glock 19, a Glock 21, or a Smith & Wesson 40 caliber automatic.

Nose assembly 20 has four openings 22 through which screws 24 pass and are threadingly received in openings 26 at an inner first end 28 of body 16. Nose assembly 20 also has a first opening 23 that aligns with the bore of the gun on which slide 10 is attached, and through which a bullet passes when fired if live ammunition is used. When slide 10 is on a gun, the gun cannot fire live ammunition and when laser module 260 is activated, laser light from laser module 260 is emitted through opening 23.

Nose assembly 20 also has a lower ring 25 with an opening 27. Opening 27 is configured so that a recoil rod (not shown) can move through the opening when the pistol fires live ammunition and the slide recoils backwards when the pistol is fired. Optional nose assemblies 60, 80, and 100 have the same structure as nose assembly 20, and differ only in that they are sized differently for different guns. FIG. 10 shows an exemplary automatic pistol 400 that a disclosed nose assembly and/or one or more slides can be used. As shown in FIG. 10, an exemplary automatic pistol 400 has a trigger 402, a barrel 404, a recoil spring 406 and a firing pin 410. FIGS. 3A-3C show, respectively, optional nose assemblies 60, 80 and 100. As shown, nose assembly 20 fits a Gen 1 Glock 17. Nose assembly 60 fits a Gen 4 Glock 19 and a Smith & Wesson 40 caliber automatic. Nose assembly 80 fits a Gen 1, 2, and 3 Glock 23. Nose assembly 100 fits a Gen 1, 2, and 3 Glock 17 and 22. A slide according to the invention may be provided as part of a kit with multiple nose assemblies and/or one or more other slides.

Body 16 is three-sided with an open bottom and has a cavity 30. Body 16 has a top surface 36, a first-side surface 34, and a second-side surface 38.

The top surface 36 has an opening 40 that is closed by a cap 42. Cap 42 is preferably threadingly received in opening 40 and, in the embodiment shown, is screwed in or out by using an Allen wrench although any suitable fastener and driving device may be used. Opening 40 is used to remove and replace power source 110, which as shown comprises three batteries 112. Power source 110 as shown is preferably three size 392 silver oxide batteries.

Body 16 also includes an opening 50A on top surface 36, an opening 50B on side surface 34, and an opening (not shown) on side surface 38. Openings 50A and the opening not shown on side surface 38 receive set screws 52 that can be tightened or loosened to move a first end 302 of the laser module 260 in order to align light emitted from laser module 260 with the longitudinal axis of a barrel of the automatic pistol on which side 10 is positioned.

Housing 200 is preferably received in cavity 30 of slide 10 and is retained in cavity 10 by fasteners 202 that are received in screw bosses (not shown).

Referring to FIGS. 4 and 5, an assembled view and exploded view of housing 200 are shown. Housing 200 is formed of any suitable material such as rigid plastic or a metal, such as steel or aluminum. Housing 200 includes a body 204, a trigger reset assembly 240, a laser module sub-assembly 260, a PCB 270, a module cushion ball 280, and laser pocket cover 290.

Body 204 has a bottom 206, an inner cavity 208, openings 210 through which fasteners 202 pass, a first side 212, and a second side 214. A power source sleeve 216 has a cylindrical opening 218 to receive batteries 112, and a lengthwise slot 220, so the power source 110 can be connected to PCB 270. The inside surface of sleeve 216 is preferable insulated.

Trigger reset assembly 240 replaces the trigger reset assembly on an automatic pistol when the pistol's original slide is used. Trigger reset assembly 240 creates force that approximates, and most preferably replicates, the force of a trigger when pulled using live ammunition. Trigger reset assembly 240 includes a spring 242 having a connector loop 244 that connects to housing 200. Reset assembly 240 also has a trigger bar engagement 246. Trigger bar engagement 246 has a first side 248 that is connected to spring 242, a central portion 250 that has an outer surface that includes a receiving opening 251 for accepting a tool to move trigger reset assembly 240, and an extended portion 252. Opening 251 aligns with opening 50B in side surface 34 of body 16. The purpose of opening 251 is to use the head of a driving tool, such as an Allen wrench, in order to move the trigger bar engagement forward to engage the trigger bar of the pistol.

When installed on a pistol, in order to position trigger bar engagement 246, the slide including trigger reset assembly 240 is pulled back, which moves the trigger bar of the pistol back. A tool is then inserted through opening 50B into opening 251 and used to turn and move trigger bar engagement 246 downward (which is clockwise as shown in FIGS. 4-5) and behind the trigger bar of the pistol. The slide is then moved forward and trigger bar engagement 246 remains behind the trigger bar of the gun unless the slide is removed from the pistol. In this position trigger reset assembly 240 creates resistive force when the trigger of the pistol is pulled, and urges the trigger forward into a reset position after the trigger has been pulled. Then the trigger can be pulled again to again activate the pistol's firing pin. Without the trigger reset assembly 240, once the trigger of the pistol is pulled, the trigger may not fully reset to its forward position and the slide would have to be moved to reset the trigger.

Laser module sub-assembly 260 includes a laser, and has a first end 262 from which laser light is emitted, a second end 264, and an electrically conductive portion 266, which is in communication with PCB 270 to provide power to sub-assembly 260.

PCB 270 includes circuitry necessary to connect the power source 110 to laser module sub-assembly 260 as described and claimed herein. A switch (not shown) which is preferably a momentary switch, may be located on the side of PCB 270 opposite laser sub-assembly 260. Laser module cushion ball 280 fits over first end 262 of laser module sub-assembly 260 to cushion and protect laser module sub-assembly 260. Set screws, such as screws 50A, are positioned against cushion ball 280 when the set screws are received in openings in body 16. Tightening the set screws applies force to cushion ball 280 that causes it to move, which causes first end 262 of laser sub-assembly 260 to move, thereby adjusting the axis along which light emitted from laser sub-assembly 260 travels.

Laser pocket cover 290 covers and retains the trigger bar reset assembly 240, laser module sub-assembly 260, and module cushion ball 280. An opening 292 allows set screw 50A to pass through and contact cushion ball 280.

FIGS. 6 and 7 show, respectively, a striker 300 assembled and in exploded view. Striker 300 includes a striker body 301 having a first end 302, a second end 304, a first body portion 303, a second body portion 305, and a third body portion 307. As shown in this embodiment, first body portion 303 has first diameter and second body portion 305 has a second diameter that is smaller than the first diameter of first body portion 303. Third body portion 307 as shown is basically semi-circular in shape. An opening 306 is at end 302. At end 304 a receiving portion 303A is connected to or formed as part of first body portion 303. Receiving portion 303A extends downward from first body portion 303 and includes an opening 303B and a cavity (not shown).

Striker 300 also includes a striker sear catch spring 308, a striker sear catch 310 having a shoulder 310A and a flat surface 310B, a striker spacer sleeve 312 having a first end 312A, a second end 312B, an opening 313 therethrough and a bottom slot (not shown), a striker spring 314, a tip 316, a spring cup 318 shown as formed from two parts 318A, 318B, and a striker catch dowel pin 320.

When assembled striker sear catch spring 308 is positioned in the cavity of receiving portion 303A and striker sear catch 310 is pressed into the cavity under sear catch spring 308. Striker sear catch spring 308 presses against the shoulder 310A of striker sear catch 310, and biases striker sear catch 310 downwards. Striker sear catch 310 and striker sear catch spring 308 are retained in the cavity by dowel pin 320 that is received in opening 303B. Cushioning tip 316 is preferably positioned in opening 306, and may be comprised of any suitable material, such as rubber or soft plastic.

Striker 300 is received in the opening 313 of striker spacer sleeve 312 so that third body portion 307 and second body portion 305 extend through opening 313 past first end 312A. First body portion 303 is positioned inside of opening 313. A slot (not shown) in striker spacer sleeve 312 permits receiving portion 303A to be positioned below striker spacer sleeve 312 inside of second end 312B.

Striker spring 314 is positioned on second body portion 305 between first end 312A of striker spacer sleeve 312 and third body portion 307. Spring cup 318 is positioned on second body portion 305 so that striker spring 314 is partially positioned over portion 319 and rests against and is retained by shoulder 321.

In use, before the trigger of the pistol is pulled, striker 300 is in a first position wherein it does not cause power to flow from the power source 110 to the laser sub-assembly 260. When the trigger of the automatic pistol is pulled it causes the gun's firing pin to move, contact striker sear catch 310, and move sear catch 310 backward. This causes striker 300 to move backward from its first position creating tension by expanding striker spring 314. The sear striker catch 310 is configured to allow the firing pin to cam (or move) away from contact with striker sear catch 310 as striker 300 is pushed farther back. When the gun's firing pin no longer contacts striker sear catch 310, spring 314 urges striker 300 forward past its first position and to its second position in which striker 300 causes power to be directed from power source 110 to laser sub-assembly 260. This is preferably caused by conformable tip 316 striking a switch (not shown), such as a momentary switch, that contacts PCB 270. That causes PCB 270 to go from a first mode, wherein it does not transfer power from power source 110 to laser sub-assembly 260, to a second mode in which it does transfer power from power source 110 to laser sub-assembly 260. Spring 314 then returns striker 300 to its first position in which conformable tip 316 is not touching a switch or otherwise causing power to be directed to laser sub-assembly 260.

Striker 300 replaces the striker associated with the original striker of the automatic pistol and interacts with the firing pin of the pistol in the same manner, but when it moves out of contact with the firing pin and moves forward to its second position it causes power to be directed to laser module sub-assembly 260. In contrast, the pistol's original striker strikes the back of a bullet housing, which causes the bullet to fire.

The circuitry, such as circuitry on the PCB, is configured to power the laser sub-assembly 260 for any suitable period of time, such as about 0.1 seconds, or any range from about 0.05 to 0.3 seconds, or any other suitable time, so a user can preferably see laser light projected on a target.

Having thus described some embodiments of the invention, other variations and embodiments that do not depart from the spirit of the invention will become apparent to those skilled in the art. The scope of the present invention is thus not limited to any particular embodiment, but is instead set forth in the appended claims and the legal equivalents thereof. Unless expressly stated in the written description or claims, the steps of any method recited in the claims may be performed in any order capable of yielding the desired result.

Claims

1. A slide configured to fit on an automatic pistol, the slide comprising: (a) a cavity, (b) a housing in the cavity, (c) a laser module positioned at least partially in the housing, the laser module having a first end that emits laser light and a second end, (d) a power source, (e) circuitry, (f) a striker, wherein the striker has a first position and a second position, in the first position the striker does not contact the power source and thereby does not provide power to the laser module, while in the second position the striker contacts the power source to provide power from the power source to the laser module; and a trigger reset assembly in the cavity, the trigger reset assembly having a trigger reset bar and a spring having a first end attached to the housing and a second end attached to the trigger reset bar, the trigger reset assembly configured to bias a trigger of the automatic pistol to a forward position after the trigger has been pulled, without the slide housing moving.

2. The slide of claim 1, wherein the trigger reset bar is connected to the housing.

3. The slide of claim 1, wherein the striker is configured to move to the second position when contacted and moved backwards from the first position by a firing pin of the automatic pistol and then released by the firing pin.

4. The slide of claim 3, wherein the striker includes a spring, wherein the spring is not compressed when the striker is in the first position, and the spring moves the striker to the second position when the striker is released by the firing pin.

5. The slide of claim 3, wherein the striker includes a striker sear catch and the firing pin contacts the strike sear catch.

6. The slide of claim 3, wherein the striker returns to the first position after moving to the second position.

7. The slide of claim 1, wherein the first end of the laser module is received in a module cushion ball, wherein the module cushion ball and the first end of the laser module are moveable up and down and sideways.

8. The slide of claim 7, wherein set screws are positioned against the module cushion ball, and are configured to be moved in order to cause the module cushion ball and the first end of the laser module to move up and down, and sideways.

9. The slide of claim 8, further comprising a top wall, a first side wall and a second side wall, an opening in the top wall and an opening in the second side wall, wherein the openings are configured to receive the set screws.

10. The slide of claim 1, wherein the circuitry is on a printed circuit board (PCB).

11. The slide of claim 1, wherein the housing includes a laser module top cover.

12. The slide of claim 1, wherein the power source is one or more batteries.

13. The slide of claim 12, wherein the power source is configured to be removed and replaced with another power source.

14. The slide of claim 1, further comprising a top wall and a cap in the top wall, wherein the cap is removable to expose the power source.

15. The slide of claim 1, further comprising a removable nose piece.

16. The slide of claim 15, further comprising a body to which the removable nose piece is attached.

17. The slide of claim 1, wherein the striker has a body that is aligned with a longitudinal axis of a barrel of the automatic pistol.

18. A kit including the slide of claim 1 and one or more interchangeable nose pieces configured to fit an automatic pistol.