The present invention relates to accessories used with firearms, and more particularly to laser sighting devices and other accessories designed for removable attachment to a barrel of a handgun.
A wide variety of accessories have been developed for users of firearms, to facilitate target visualization and improve targeting accuracy. Among these are laser sighting devices configured to generate a coherent energy beam parallel or nearly parallel to the extension of a gun barrel, with the precise alignment depending largely on the distance to the target and windage. When activated, the coherent energy beam forms a spot of light on the target, to indicate the expected point of impact of the firearm projectile. These devices can enhance the experience of any firearm user, and have considerable importance in certain law enforcement and military operations.
Typical laser sighting devices employ visible red or infrared laser frequencies, as energy at the desired frequency can be generated directly, e.g. with a neodymium-doped yttrium aluminum garnet (Nd:YAG) crystal. More recently, it has been discovered that visible light in the “green” range, e.g. having a wavelength in the 490-570 nanometer range, has much higher visibility than visible red laser energy. The more visible beam, while enhancing utility of a sighting device in general, is particularly effective for daytime use.
A difficulty that has limited the use of green laser energy in sighting devices is the need for additional components not required by visible red and infrared lasers. To generate coherent energy in the green region of the spectrum, an Nd:YAG crystal is used to generate energy at a wavelength outside the visible spectrum, e.g. 1064 nm, that is then provided to a frequency doubler, e.g. a potassium titanium oxide phosphate (KTP) or lithium triborate (LBO) crystal to generate the desired wavelength, in this case 532 nm. The additional components require a larger laser drive circuit, typically a printed circuit board, and a larger power supply to meet a higher power requirement. The resulting sighting device is larger and difficult to use with handguns, either because the handgun barrel is not long enough to accommodate the device, or because the device protrudes ahead of the barrel an excessive amount. In accessory devices incorporating green laser sighting and white light (multichromatic energy) illumination, this difficulty is magnified.
Another problem encountered with the green laser is the higher power requirement and the accompanying reduction in useful life of the power source, typically one or more batteries. A larger battery of course contributes to the size of the device; all the more so in devices that combine laser and multichromatic illumination as they typically employ separate voltage level power sources for the separate light sources.
While sighting devices and other accessories can be mounted to firearms in a variety of ways, one approach gaining increasing acceptance involves forming longitudinally extending rails on opposite sides below the barrel of a handgun ahead of the trigger guard, for example as shown in U.S. Pat. No. 6,185,854 (Solinsky et al.). The accessory or auxiliary device is provided with opposed projections, each slidable relative to one of the rails to guide the accessory for longitudinal travel relative to the barrel. The accessory also carries a transverse spring loaded bar that fits into a transverse groove formed in the barrel to secure the accessory against longitudinal travel. While this approach has proven useful for attaching a variety of accessories including laser sights and illumination devices, problems are encountered due to the differences in locations for the transverse grooves among different brands of firearms.
The disclosure pertains generally to laser sighting devices such as green laser gun sights that are configured to be easily attached to a variety of different hand guns. In some embodiments, the laser gun sights are configured to permit elevation and windage adjustment without requiring movement of an entire laser module, thereby affording use of a more compact device housing. In some embodiments, the laser gun sights are configured such that the gun sight shuts off when a gun equipped with the laser gun sight is holstered, and turns itself back on when the gun is drawn from the holster.
While multiple embodiments are disclosed, still other embodiments will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
While the disclosure is amenable to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and are described in detail below. The intention, however, is not to limit the disclosure to the particular embodiments described. On the contrary, the disclosure is intended to cover all modifications, equivalents, and alternatives thereof.
The disclosure pertains generally to laser gun sights such as green laser gun sights that are configured to be easily attached to a variety of different hand guns. In some embodiments, the green laser gun sights are configured to permit elevation and windage adjustment without requiring movement of an entire laser module, thereby affording use of a more compact device housing. In some embodiments, the laser module can be in direct contact with the housing. Because the housing can then function as a heat sink, a smaller laser module may be used.
The green laser gun sights described herein may be used with a variety of different gun styles and sizes, including handguns, rifles, shotguns and the like. For purposes of illustration,
Turning to
The housing 22 also includes features that facilitate attachment of the green laser gun sight 18 to the handgun 10. A pair of grooves 30 are formed, one on each side of the housing 22 (only one visible in this illustration). As will be explained subsequently, the grooves 30 accommodate a rail set that connects the green laser gun sight 18 to the handgun 10. The housing 22 also includes a through aperture 32 that also helps to connect the green laser gun sight 18 to the handgun 10.
As will be illustrated with respect to a subsequent drawing, the cross pin 40 also helps to secure the rail sets 36 and 38, and hence the green laser gun sight 18, to the handgun 10. It can be seen that the rail set 36 includes a mounting surface 42 and the rail set 38 includes a mounting surface 44. The mounting surfaces 42 and 44 may be configured to interact with the rail system (
The green laser gun sight 18 includes a front cover 52 that in some embodiments may be formed of a suitable polymeric material. The front cover 52 includes a portion 46 that is configured to permit laser light to emerge as well as a portion 48 that is configured to accommodate a visible light. A cover 50 seals off the larger aperture 28 (
In some embodiments, the green laser gun sight 18 includes one or more switches 80 that can be used, for example, to program the green laser gun sight 18, to turn the green laser module 34 on or off, to turn the visible light module on or off, or to vary a pulse rate for the green laser module 34 and/or vary a strobe rate for the visible light module. In some embodiments, there are a pair of switches 80, with one switch 80 arranged on each side of the green laser gun sight 18. In some embodiments, as will be discussed subsequently, the switch(es) 80 may be disposed at a remote location.
In some embodiments, the switch 80 on the right side of the green laser gun sight 18 and the switch 80 on the left side of the green laser gun sight 18 may be used interchangeably. For example, it may be more natural for a right-handed user to use their thumb to operate the switch 80 on the left side of the green laser gun sight 18 while a left-handed user may use their thumb to operate the switch 80 on the right side of the green laser gun sight 18. In some cases, a user may prefer to turn the green laser gun sight 18 on or off using a different finger, before they are holding the gun 10 in a ready-to-fire position. In some embodiments, the green laser gun sight 18 includes circuitry that enables either switch 80 to be used.
An individual can adjust the aim of the laser beam emitted by the green laser sighting device 18 by turning the elevation screw 54 and/or the windage screw 56. As a result of turning the elevation screw 54 and/or the windage screw 56, the laser collimating lens 58 may slide radially or perpendicularly with respect to the green laser module 34. In some embodiments, the elevation screw 54 and the windage screw 56 may be configured to permit the laser collimating lens 58 to pivot relative to the green laser module 34. In some embodiments, the laser collimating lens 58 may be stationary, and the elevation screw 54 and/or the windage screw 56 may be used to alter the position of an additional lens or other optical component (not illustrated) in order to fine tune aiming of the green laser module 34.
In some embodiments, the rail system 16 also includes a horizontal cross slot 68. In some embodiments, as illustrated, the rail set 36 and the rail set 38 may include, respectively, mounting apertures 70 and 72 that permit the cross pin 40 to extend through the rail set 36 and the rail set 38. In some embodiments, the horizontal cross slot 68 is sized and positioned to accommodate the cross pin 40 and thereby prevent or at least substantially prevent lateral movement of the laser sighting device 18 relative to the handgun 10. In some embodiments, each of the rail sets 36 and 38 may include several different mounting apertures to accommodate particular handguns 10 having different positions for the horizontal cross slot 68.
In some embodiments, the rail sets 36 and 38 may include an aperture 35 (only one visible in
It will be appreciated, therefore, that the green laser gun sight 18 may be attached to a variety of different handguns 10 without requiring alteration of the housing 22. Rather, the rail sets 36 and 38 may be configured to have mounting surfaces 42 and 44, respectively, that are configured to interact with the particular rail system 16 of a particular handgun 10.
The green laser gun sight 18 described with respect to
The green laser gun sight 82 includes a portion 84 that is configured to accommodate the green laser module 34. In some embodiments, the portion 84 may include a glass plate that permits the green laser light to pass through. The green laser gun sight 82 also includes a visible light module 86. In some embodiments, as illustrated, the visible light module 86 may be configured to provide substantially more visible light than that provided by the visible light module 62 (
The green laser gun sight 82 includes a first rail set 92 and a second rail set 94 that may be attached to the green laser gun sight 82 in a manner similar to that described previously with respect to the green laser gun sight 18. In some embodiments, a screw 96 attaches the first rail set 92 to the green laser gun sight 82, while a similar screw (not visible) attaches the second rail 94 to the opposing side of the green laser gun sight 82. In some embodiments, as illustrated, a pair of cross pins 98 secure the first rail set 92 to the second rail set 94 and thus secure the green laser gun sight 82 to a gun rail system. In some embodiments, it will be appreciated that larger guns have longer rail systems 102 and thus can accommodate more than one cross pin 98. In some embodiments, the green laser gun sight 82 may be physically larger and longer than, for example, the green laser gun sight 18 and thus may benefit from using more than one cross pin 98.
In some embodiments, the green laser gun sight 82 includes one or more switches 100 that can be used, for example, to program the green laser gun sight 82, to turn the green laser module 34 on or off, to turn the visible light module 86 on or off, to vary a pulse rate for the green laser module 34 and/or to vary a strobe rate for the visible light module. In some embodiments, there are a pair of switches 100, with one switch 100 arranged on each side of the green laser gun sight 82. In some embodiments, as illustrated for example in
As an illustrative but non-limiting example, the settings “A”, “B”, “C” and “D” may each be used to designate a particular function such as constant laser only, constant light only, or constant laser with constant light. In some embodiments, each of these functions may be momentary only. In some embodiments, on or more of the aforementioned settings may be used to designate independent activation between the two separate buttons 112 and 114 (discussed below with respect to
In some embodiments, the outer panel 124 and the inner panel 126 may be distinct portions that are screwed, bolted, riveted or otherwise secured together. In some embodiments, as illustrated, the outer panel 124 and the inner panel 126 may instead be outer and inner portions, respectively, of a unitary structure. In some embodiments, the outer panel 124 and the inner panel 126 are molded as a unitary structure. The holster 120 may be formed of any suitable material. In some embodiments, the holster 120 is largely molded from a relatively rigid polymer such as KYDEX® or a similar material.
The holster 120 includes a primary retention device 130 and a secondary retention device 132. In some embodiments, the primary retention device 130 is configured to releasably engage with an external component of the green laser gun sight 18. In some embodiments, as illustrated, the primary retention device 130 includes a moveable lever 134 that includes an engagement portion 136, a finger button portion 138 and an intervening pivot point 140. In some embodiments, the moveable lever 134 is movable between an engagement position in which the engagement portion 136 interacts with a portion of the green laser gun sight 18 and a disengagement position in which the engagement portion 136 is moved out of engagement with the green laser gun sight 18. In some embodiments, the moveable lever 134 is biased into the engagement portion by a spring or similarly resilient element (not illustrated). In some embodiments, the primary retention device 130 is configured such that a user may easily draw the handgun 10 from the holster 120 by depressing the finger portion with their finger to move the primary retention device 130 to a disengagement position and wherein the primary retention device 130 is positioned relative to the pocket 122 such that the gun 10 may be withdrawn from the holster 122 with the user's finger proximate a switch 80 (
In some embodiments, the secondary retention device 132 includes a resilient member 142 that forms a frictional fit with the housing 22 of the green laser gun sight 18. It will be appreciated that the secondary retention device 132 is configured to resist accidental removal of the gun 10 from the holster 120 but permits removal of the gun 10 from the holster 120 when the finger portion 138 is depressed and the gun 10 is withdrawn.
The pulsed input to laser drive circuit 174 causes the drive circuit 174 to generate a laser beam at substantially the same pulsing frequency, so that users visually perceive the beam as pulsed. Moreover, at the relatively low pulsing frequencies involved, the separate pulsing frequencies are readily visually distinguishable from one another. Consequently, in a situation in which sighting beams from several different firearms may be directed towards the same target, for example in certain law enforcement or military operations, the different pulsing rates allow each user to distinguish his or her sighting beam from the others.
More generally, the pulsing circuit 176 can be configured to provide power to the laser drive circuit 174 at several distinct pulsing frequencies, and further to provide power at several different pulsing circuit duty cycles, each associated with a different one of the pulsing frequencies. In each case, the laser drive circuit 174 provides power to the laser module according to a duty cycle controlled by its corresponding pulsing circuit duty cycle.
In some embodiments, the operator selects the desired pulsing frequency by operating the switch 184 to cycle through five distinct modes: continuous wave, pulse frequency number 1, pulse frequency number 2, pulse frequency number 3, and off. The switch 184 also is operable to control the light source 164. With further reference to
In some embodiments, the printed circuit board 176 may include a sensing circuit 184 that includes a Hall effect sensor 186. In some embodiments, as will be described, the holster 120 may include one or more magnets that are sized to produce a magnetic field that can be detected by the Hall effect sensor 186. In some embodiments, one or more magnets may be placed in a soft holster such as a pocket gun holster. In some embodiments, one or more magnets may instead be disposed on or in a flat surface such as the floor of a safe, a nightstand drawer, an automobile glove box, or the like. If the sensing circuit 184 detects a magnetic field of a particular strength, the microprocessor 185 decides that a gun 10 to which the green laser gun sight 18 has been mounted has been holstered. When the sensing circuit 184 no longer detects the magnetic field, the microprocessor 185 decides that the gun 10 has been drawn from the holster 120 or picked up from the aforementioned flat surface.
In some embodiments, the microprocessor 185 is configured to turn off the green laser gun sight 18 when detection of a magnetic field indicates that the gun 10 has been holstered or otherwise put away. In some embodiments, the microprocessor 185 is configured to turn on the green laser gun sight 18 when a lack of detection of a magnetic field indicates that the gun 10 has been drawn or picked up. In some embodiments, the microprocessor 185 is configured to turn on the green laser gun sight 18 upon removal from the holster 120 if the green laser gun sight 18 was turned on when holstered, and is configured to keep the green laser gun sight 18 turned off upon removal from the holster 120 if the green laser gun sight 18 was turned off when holstered.
In some embodiments, turning the green laser gun sight 18 on and off refers to completely shutting off the green laser gun sight 18 in order to conserve battery power. In some embodiments, this refers to turning portions of the aforementioned circuitry on or off. For example, turning off the green laser gun sight 18 may refer to stopping power to the laser module 154 and/or the LED module 164 to conserve battery power and/or prevent inadvertent detection of the gun 10 while other portions of the circuitry remain powered.
In some embodiments, the green laser gun sight 18 may be programmed using the one or more buttons 80 to automatically turn on the laser module 154 and/or the LED module 164 when the gun is drawn from the holster 120. In some embodiments, the green laser gun sight 18 may be programmed to automatically turn on the laser module 154 and/or the LED module 164 after a user programmable time delay should the user wish a short delay to, for example, better position the gun before providing a visual indication of the gun's presence.
Various modifications and additions can be made to the exemplary embodiments discussed. For example, while the embodiments described above refer to particular features, the scope of this invention also includes embodiments having different combinations of features and embodiments that do not include all of the described features. Accordingly, the scope of the disclosure is intended to embrace all such alternatives, modifications, and variations as fall within the scope of the disclosure, together with all equivalents thereof.
This application claims the benefit of U.S. Provisional Application Ser. No. 61/577,433 entitled AUTO ON GREEN LASER SIGHT and filed Dec. 19, 2011, which application is incorporated by reference herein in its entirety.
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