An optic guard is described in U.S. patent application Ser. No. 17/156,504, published on Jul. 29, 2021, which is herein incorporated by reference in its entirety. A lower section, such as a bracket, may be arranged to attach to a firearm assembly. An upper section may protect top or opposite sides of an optic sight, in some embodiments.
The ′504 application describes a frame with one or more protrusions that may be welded to mating openings in a bracket, which may provide a desired durability for the optic guard. It would be advantageous to use a frame coupling method that may provide the desired durability without requiring welding. Various embodiments described herein may include a frame coupling interface that may provide the desired durability without requiring welding. Also, any frame coupling interface described herein may be applied for other firearm parts besides optic guards, such as for non-releasably coupling a mechanical sight mount (e.g., a rear iron sight mount) to an optic mounting adapter (e.g., an optic plate) or other optic mounting device.
The ′504 application also describes a mechanical sight (e.g., a rear iron sight) located on a bottom frame member of the frame of the optic guard. This may allow co-witnessing of the mechanical sight and the optic sight (e.g., an operator may view the mechanical sight through the optic sight). Also, in contrast to some other firearm assemblies in which the rear mechanical sight is nearer to the operator's eye than the optic sight (e.g., located behind the optic sight), in the embodiments described in the ′504 application the rear mechanical sight is located in front of the optic sight. Some operator's eyes may be momentarily distracted by a rear mechanical sight located between their eye and the optic sight—and this can be avoided in embodiments in which the rear mechanical sight is located in front of the optic sight (e.g., when both of the rear mechanical sight and the front mechanical sight are viewable through the optic sight).
In any optic guard (e.g., one that includes the frame coupling interface, or some other optic guard), it would be advantageous to use a modular mechanical sight mount that allows the mechanical sight to be installed or removed without requiring removal of the optic guard from the firearm, and/or without requiring removal of the optic sight from an optic mounting device of the firearm. Various embodiments described herein may include a mechanical sight device that can be attached or removed from an optic guard without removing the optic guard from the firearm and/or without removing the optic sight from an optic mounting device of the firearm.
Also, in contrast to some known firearm assemblies where a removable mechanical sight may need to be re-zero after re-attachment, various embodiments are arranged to laterally self-center the mechanical sight device in exactly the same lateral position each time it is removed and re-attached. Some known firearm assemblies may not laterally constrain a removable mechanical sight device to a center position (e.g., a same lateral position), which may necessitate that the operator re-zero a firearm after re-attaching a mechanical sight device to correct windage error. Various embodiments may also vertically constrain the mechanical sight device, so that the operator need not re-zero the firearm after re-attaching a mechanical sight device to correct elevation error. The fore/after position of the mechanical sight device may also be exactly repeating through a removal/reattachment of the mechanical sight device.
Although various embodiments described herein provide a modular rear mechanical sight device mountable to an optic guard, some embodiments may provide a modular mechanical sight device mountable to some other part of an optic assembly, particularly one that does not locate the rear mechanical sight between the operator's eye and the optic sight (e.g., a rearmost part of the rear mechanical sight may be positioned in front an emitter of the optic sight). For example, in various embodiments a modular mechanical sight device may be mountable to a front of at least one body of the optic sight (or a mechanical sight device may be integrally formed on a front of the at least one body). In other embodiments, at least one body of the optic sight may be affixed to an optic mounting device (e.g., an optic mounting plate), and the modular mechanical sight device may be mountable to a front section of the optic mounting device (in which the rear mechanical sight is located in front of the optic sight).
Referring to
Referring briefly to
In this embodiment, the frame 11 is edge-mounted to the mounting plate 10, e.g., at least part of the protrusion is received by an aperture (e.g., opening 49) defined by an edge of the mounting plate 10; however, this is not required. In other embodiments, a plate may define a key-through hole opening extending from top to bottom of the plate, and the protrusion can be inserted downward through a larger part of the key-through opening and then laterally press-fit into a smaller part of the keyhole opening.
In this embodiment, the openings 49 and the pockets 48 are at least partially formed in different surfaces of the mounting plate 10. For example, the openings 49 are located on a surface of a front edge of the mounting plate 10, while the pockets 48 are defined at least by a bottom surface of the mounting plate 10. In other examples, openings and pockets may be formed in a same surface of a mounting device (such as with a key-through hole embodiment).
Referring again to
In this example, a male press fit lug interface (e.g., protrusions 17) is defined by the frame 11. However, in other examples it may be possible and practical to provide the male press fit lug interface on the plate, with corresponding openings and/or pockets defined by the frame. Also, in various embodiments, protrusions may be distributed amongst the plate and the frame with each having at least one protrusion to mate with an opening and/or pocket on the other of the plate and the frame.
In embodiments in which there is more than one protrusion (not required—it may be possible and practical to have a single protrusion), at least one of the protrusions may have a head or other endmost section having a different size, shape, or orientation than a head or other endmost section of at least one other protrusion of the protrusions. Referring to
In some embodiments, one of a frame and optic mounting plate/device may include one or more mechanically deformable posts arranged to slip fit into openings in the other of the frame or optic mounting plate/device. A length of the posts may be greater than a length of the slip fit openings so that a protruding part of the post may be mechanically deformed (e.g., at least partially flattened) to non-releasably and/or non-weldingly join the posts to the openings.
In other embodiments, a non-releasable and/or non-weldingly coupling may be provided using at least one fastener arranged to itself mechanically deform, or arranged to mechanically deform a component it is driven into. In an example in which the fasteners are mechanically deformable, rivets may be provided in through holes in the frame or optic mounting plate/device, and their ends may then be deformed (e.g., flattened) to non-releasably join the frame to the optic mounting plate/device. Any other mechanically deformable fastener, now known or later developed may be used instead of rivets in other examples. In examples in which a fastener produces mechanical deformation of another component, a fastener may be used to produce mechanical deform a part of the frame or the optic mounting plate/device to non-releasably join the frame to the optic mounting plate/device (e.g., a part of a protrusion may be mechanically deformed by a fastener driven into a hole in the protrusion, to provide a fixable coupling).
In various embodiments described above, an optic guard including a frame having an opening (to provide a line of sight through the optic sight and the frame) may utilize any press fit lug interface or mechanical-deformation interface described herein. In other embodiments, some other firearm-mountable device may use any press fit lug interface or mechanical-deformation interface described herein (an optic guard frame is not required). For example, a mechanical sight mount may be fixably coupled to a mounting plate or other mounting device using any press fit interface or mechanical-deformation interface described herein. In such an embodiment, the mechanical sight mount for providing a co-witnessable rear mechanical sight in front of an optic sight may utilize any press fit interface or mechanical-deformation interface described herein (e.g., the mechanical sight mount may be a lower section similar to a lower section of the frame 11 without the side frame members and/or the top frame member).
The mechanical sight device 12 includes a mechanical sight 62 and an attachment section 61. In this embodiment, the attachment section 61 includes a dovetail 65 slidingly receivable by a dovetail groove 55 (
With reference to
With the fasteners 16 threaded down, the mechanical sight device 12 may be slidingly inserted into the dovetail groove (
These tool through holes 56 remain accessible when an optic sight is installed onto the mounting plate 10 and/or when the mounting plate 10 is installed on a firearm assembly (e.g., a slide, not shown). Since the mounting plate 10 need not be detached and the optic sight need not be detached, the operator may not need to re-zero the optic sight after attaching/removing the mechanical sight device 12. Also, the dovetail interface, or some other similar alternative slidingly engagable interface, may ensure that the mechanical sight device 12 is self-centering in the same position relative to the firearm, which allows the user to detach the mechanical sight device 12 as frequently as desired without having to re-zero the mechanical sight 62.
Using the driving tool (not shown), each of the fasteners 16 can be driven down until an end 27 (e.g., a nose end, such as a cup point end, in this embodiment) of the fastener 16 is located in a recess 67 (
It should be understood that any mechanical sight device feature described herein can be applied to any optic guard whether or not the optic guard includes a mounting plate. For example, the ′504 application describes an optic guard mountable in a dovetail slot defined by a slide (in front of an optic mounting platform defined by the slide). Other examples in which a modular mechanical sight device is used in an optic guard different than the optic guard of
Referring again to
In this embodiment, the mechanical sight device 72 may have an attachment section that is similar in any respect to the attachment section 61 (
Referring now to
Referring again to
In contrast to other optic guards described herein (which may be fixably coupled to a mounting device, such as a mounting plate), this optic guard 1111 is releasably coupled to a mounting device 1110. The optic guard 1111 has an upper section that may be similar in various respects to the upper section of the optic guard 71 of
Unlike the upper section of the optic guard 71 (
Other features of the optic guard 1111 may be similar to the optic guard 71 (
In the various embodiments illustrated above, the part of the optic assembly receiving the modular mechanical sight device is an optic guard. However, as described earlier, this is not required. In another example, a mechanical sight mount may be fixably coupled, releasably coupled, or integrally formed on, or in, a front section of an optic mount device/plate, and this mechanical sight device may include any interface described herein for mounting a modular mechanical sight device between a corresponding front mechanical sight and at least part of the optic sight. In another example, the part of the optic assembly may be the optic sight (e.g., part of the body of the optic sight, such as a front of the body, may provide a mount for the modular mechanical sight device). A receiving device for a modular mechanical sight device may be any firearm part in various embodiments.
By way of background, optic sights may be closed emitter optic sights or open emitter optic sights. In closed emitter optic sights, an emitter (e.g., a beam emitter) may be located in an environmentally-isolated cavity within the closed emitter optic sight. A beam may be projected on a front light transmissive window/pane (e.g., a lens, a window, glass, or the like). In an open emitter optic sight, the beam travels through open air to a light transmissive window/pane on which the beam is projected.
Any mechanical sight device described herein may be used with a closed emitter optic sight or an open emitter optic sight. When used in a closed emitter optic sight, the mechanical sight device may be located (e.g., permanently located) within the environmentally-isolated cavity, e.g., between any two light transmissive panes/windows of the optic sight, such as between a rear window of the optic sight and a front light transmissive pane/window on which the beam is projected. In either type of emitter optic sight arrangement (e.g., open or closed), the mechanical sight device may be a modular mechanical sight device located in front of the light transmissive window/pane on which the beam is projected.
Integrally formed on a front end of the body are grip serrations that may be similar to, and may be used similarly as, any grip serrations of any optic guard described in the ′504 application. The deep front cavity may protect the front light transmissive window/pane from smudging/scratching/dirtying if a user grips the body of the optic sight similar to how a user may grip any optic guard described herein. Also, the front surface of the mechanical sight device is recessed relative to the front surface of the body of the optic sight (as illustrated in
In any embodiment of an optic sight and a mechanical sight device (modular or integrally formed), the mechanical sight device may be located in front of an emitter of the optic sight. For example, referring to
A part of the optic sight 1706 (e.g., a part of a body of the optic sight 1706, such as a lower front of the body) may include an attachment interface for mounting an optic guard 1711 thereon, e.g., the optic guard is carried by the optic sight 1706. In this example, the attachment interface is arranged for releasably coupling (e.g., slidingly coupling) the optic guard 1711 to the optic sight 1706. In other examples, an attachment interface on an optic sight may non-releasably couple (e.g., fixably attach, e.g., press fit, interface fit, or the like) an optic guard to an optic sight.
In this example, the attachment interface includes a protrusion 1731 on the optic sight 1706 (e.g., a dovetail), which is received by a back end of the optic guard 1711. As shown in
Referring again to
Although the illustrated embodiment includes an attachment interface with a protrusion or aperture, and a fastener opening for a fastener, this may not be required in other embodiments. In other embodiments, any attachment interface now known or later developed may be used.
Referring to
In various embodiments, the optic guard 1771 may have a frame defining an opening, in which the frame includes a top frame member, side frame members, and a base (e.g., a bottom frame member) as illustrated. The gap may be located behind at least one of the frame members, in various embodiments. In this example, the gap is provided behind the side frame members and the top frame member, which may allow the optic guard 1771 to flex (reducing the chance of damage to the optic sight 1706).
Referring now to
Any rear mechanical sight configuration described herein may be used in combination with an optic guard releasably or non-releasably mounted on (e.g., directly mounted on) an optic sight. In the illustrated embodiment, the rear mechanical sight is integrally formed on the optic guard, but in other examples the rear mechanical sight may be located on, or within, the optic sight. In other embodiments, any modular rear mechanical sight configuration may be used. A rear mechanical sight for an optic assembly is, of course, not required.
Similar to the embodiment described with reference to
In some firearm assemblies, an optic sight may be long enough that a bottom of the optic sight completely or substantially fills in a recess in which the optic sight is located.
In cases where there is not sufficient space in front of the recess, or for other reasons, it may be desirable to mount a modular optic guard to a part of the optic sight that protrudes above the recess (e.g., to a front of the body). Referring to
Referring to
Any other optic guard features described herein or in the ′504 application may be used in an optic assembly including a cantilevered modular optic guard. Also, of course, it may be possible and practical to provide a non-modular optic guard fixably attached or integrally formed on a front of an optic sight, in which the optic sight is similar to the optic assembly illustrated in
Any rear mechanical sight configuration described herein may be used in combination with an optic guard integrally formed on an optic sight. In the illustrated embodiment, the rear mechanical sight is integrally formed on the optic guard, but in other examples the rear mechanical sight may be integrally formed on, or inside, the optic sight. In other embodiments, any modular rear mechanical sight configuration described herein may be used.
Any modular or non-modular optic guard described herein may have any grip features described herein or in the ′504 application, and/or any grip features later developed. An optic guard mounted on an optic sight may be used for racking the firearm, similar to how an optic guard mounted to a slide may be used for racking the firearm.
In the various illustrated embodiments, an optic guard is connected to a linear section of a body of the optic sight (e.g., a length of a lower section of the body), which provides a gap between a back of the optic guard and an upper section of the body. In other examples, it may be possible and practical to attach an optic guard to some other linear section of the body of the optic sight.
Connecting via a linear section of a body of an optic sight is not required, however. In some other examples, it may be possible and practical to connect an optic guard to body of an optic sight at points (or other non-linear sections), and still provide a gap between a back of the optic guard (e.g., in linear sections between the connection points). For example, in one embodiment an optic guard may be connected to a body of an optic sight at three points, e.g., bottom left, bottom right, and a top point. In this example, a gap may be provided between a back of the optic guard and a lower section of the body between the points, and between a back of the optic guard and an upper section around the top point.
In the illustrated embodiments, the variously described gaps contain air. In other embodiments, any gap described herein may contain some other material that is different than adjacent materials (in one example, a compressible solid material is located in the gap).
Optic Sight Body with Flexing Member
U.S. Pat. No. 8,082,688 describes an optic housing that is ruggedized to prevent an optic lens from being fractured should the optic housing be dropped or suffer an impact event. This ruggedization is provided using posts that extend from a main body of the optic a greater distance than a cross member that joins the posts. In this way, force is transferred into the posts, rather than the cross member. While this arrangement may reduce the chance of a fracture of the optic lens, it may be still be possible for the optic lens to fracture should the optic housing be dropped or suffer an impact event.
The optic sight 2000 also includes a flexing member 2050 and a gap 2051 between the flexing member 2050 and a part of the OE-framing. In this example, the gap 2051 is between the flexing member 2050 and a top OE-frame member 2002. Due to the gap 2051, the flexing member 2050 may flex in response to an impact without contacting the top OE-frame member 2002. This flexing may dampen the force of the impact (e.g., spring action) and prevent the OE 2096 from fracturing.
When a midsection of the flexing member 2050 is located higher then end sections of the flexing member 2050 (e.g., a convex shape as illustrated or some other shape that locates the midsection higher than the end sections), flexing may be optimized. However, the flexing member can have any shape in other examples (such as non-curved shape). Also, in this example, the gap has a uniform width, as illustrated; however, this is not required—in other examples the gap may have a varying width.
In this embodiment, a flexing member 2150 may operate similar as flexing member 2050 (
The OE 2155 is mounted in OE-framing including side OE-frame members, as illustrated. The optic sight 2100 defines a gap 2151 between a top edge of the OE 2155 and the flexing member 2150. In this example the gap 2151 has varying width, but in other examples the gap 2151 may have a uniform width. In this embodiment, OE 2155 has corners, and thus multiple sides, but in other examples an OE may be round. In a round embodiment, a part of the round OE may be exposed by framing of an optic sight, and the optic sight may have a gap between the exposed part and a flexing member, similar to the illustrated embodiment.
This embodiment includes a non-modular optic guard 2271 and flexing members 2250A and 2250B. The flexing member 2250A may be similar in any respect to flexing member 2050 (
In this embodiment the optic guard 2271 is non-modular. However, in other embodiments a modular optic guard may have any flexing member features described herein, e.g., may be used in combination with one or more flexing members.
As described previously herein, a rear mechanical sight (e.g., a rear iron sight) may be separate from an optic sight, or may be part of an optic sight. This, of course, adds an additional part to the firearm, along with the related costs and increases to weight, but it is still desirable so that the user may have a backup sight should the optic sight fail.
However, it may also be possible and practical to provide an on-OE rear backup sight, instead. An on-OE backup sight may be provided by adding material to the OE of the optic sight, or removing material from the OE in the case of engraving a rear backup sight on-OE.
For example, an image or other representation of a rear backup sight may be printed on, or by otherwise adding ink or other material on, a glass surface of an OE of the optic sight. This on-OE rear backup sight may form a sight pair with a mechanical front sight (e.g., a front mechanical sight) of the firearm. The on-OE rear backup sight may be located on a lens, on a window, or on another OE surface of the optic sight, including between OEs in optic sights with multiple OEs. In other examples, the rear backup sight may be provided on-OE by removing material from the OE, for example by engraving.
An on-OE rear backup sight may be formed using any techniques now known, or later developed, for forming a reticule on-OE. In other embodiments, a rear backup sight may be projected on the OE (e.g., from an emitter) using any techniques now known, or later developed, for projecting a reticule on the OE.
In the case of an on-OE provided by adding or removing material from an OE of a battery-powered optic sight, this rear backup sight may remain usable even if the battery is disconnected. Therefore, an operator may utilize a backup sight by looking through the optic sight even in the event of battery failure.
We claim all modifications and variations coming within the spirit and scope of the following claims.
This application claims priority to U.S. Provisional Application No. 63/439,087 filed on Jan. 14, 2023, and U.S. Provisional Application No. 63/444,850 filed on Feb. 10, 2023, each of which is incorporated by reference herein.
Number | Date | Country | |
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63439087 | Jan 2023 | US | |
63444850 | Feb 2023 | US |