Mounting and adjusting structure of laser gunsight

Abstract

The utility model discloses a kind of installation and adjustment structure of laser gun sight, comprising: laser indicator, slide rail is provided on laser indicator;Clamping seat, one end of clamping seat is provided with clamping groove, to be mounted on gun body for clamping seat, the other end of clamping seat is provided with the sliding slot for the installation of slide rail;Clamping assembly, clamping assembly is set on clamping seat, clamping assembly includes clamping piece and telescopic piece, one end of telescopic piece and clamping seat abut, the other end of telescopic piece and clamping piece abut;Telescopic piece is configured to be deformed between first state and second state;When in first state, clamping piece and slide rail abut, to lock and fix slide rail in sliding slot;When in second state, clamping piece and slide rail dynamic contact, slide rail can be moved along the direction that sliding slot is set to adjust the installation position of laser indicator.The structure of the present application is simple, the adjustment and locking and fixing of laser indicator position can be quickly realized, ensure that laser indicator is in stable state when gun body is used.

Description

Technical Field

[0001] This utility model relates to the field of laser gun aiming technology, and in particular to a mounting and adjustment structure for a laser gun aiming. Background Technology

[0002] A laser sight is a device that uses a laser beam to assist aiming. It is widely used in firearms, crossbows, and other projectile weapons. By projecting a laser point onto the target, it helps the user to quickly and accurately aim at the target.

[0003] In existing technology, laser sights are mounted on the gun body via an adjustment mechanism. To accommodate different gun models and user adjustment needs, the laser sight needs to slide back and forth on the adjustment mechanism to bring it closer to the trigger guard, making it easier for the user to press the laser sight's power button. However, existing adjustment mechanisms have many components, resulting in a complex structure. Furthermore, when using existing adjustment mechanisms to mount the laser sight on the gun body, if the user's grip is unstable or the gun shakes after firing, the adjustment mechanism cannot effectively fix the laser sight, causing it to wobble on the adjustment mechanism and affecting the effectiveness of subsequent firing.

[0004] Therefore, existing technologies still need to be improved and enhanced. Utility Model Content

[0005] In view of the shortcomings of the prior art, the purpose of this utility model is to provide a simple and stable installation and adjustment structure for a laser gun sight.

[0006] To achieve the above objectives, the present invention adopts the following technical solution:

[0007] A mounting and adjustment structure for a laser gun sight includes:

[0008] A laser pointer, wherein a slide rail is provided on the laser pointer;

[0009] A clamping seat, one end of which is provided with a slot for mounting the clamping seat on the gun body, and the other end of which is provided with a groove for mounting the slide rail;

[0010] A clamping assembly is disposed on the clamping seat. The clamping assembly includes a clamping member and a telescopic member. One end of the telescopic member abuts against the clamping seat, and the other end of the telescopic member abuts against the clamping member.

[0011] The telescopic member is configured to deform between a first state and a second state; in the first state, the clamping member abuts against the slide rail to lock the slide rail in place within the slide groove; in the second state, the clamping member dynamically contacts the slide rail, and the slide rail can move along the direction of the slide groove to adjust the installation position of the laser pointer.

[0012] The clamping assembly also includes a fastener located on one side of the clamping member, and the fastener is adjusted to allow the telescopic member to switch between the first state and the second state.

[0013] In the first state, the fastener abuts against the clamping member; in the second state, the fastener and the clamping member have no interaction force.

[0014] The fastener is a screw, and the clamping seat is provided with a threaded hole for fitting the fastener.

[0015] The fastener is a kimming screw, and the depth of the threaded hole is not less than the length of the fastener.

[0016] The telescopic component is a compression spring.

[0017] The second state is the compressed state of the compression spring.

[0018] The slide rail is provided with a first protrusion, and the clamping member is provided with a second protrusion that matches the first protrusion; when the telescopic member is in the second state and the laser indicator is adjusted along the direction of the slide groove, the first protrusion and the second protrusion are in continuous contact.

[0019] The clamping base is provided with a receiving groove for placing the clamping member, and a gap is defined between the clamping member and the receiving groove to allow the clamping member to approach or move away from the slide rail; the receiving groove is provided with an opening, and the opening is located on one side of the slide rail; when the telescopic member is in the first state, the clamping member enters the opening and abuts against the slide rail.

[0020] Two telescopic components are provided and located on the mounting surface of the clamping component. The mounting surface is at least partially arc-shaped, and the mounting surface forms a T-shaped structure at the upper end of the clamping component. One end of the telescopic component abuts against the inner wall of the receiving groove, and the other end of the telescopic component abuts against the end of the T-shaped structure. A cover plate is provided above the clamping component to confine the telescopic component within the space defined by the cover plate and the clamping component.

[0021] Compared to existing technologies, this utility model provides a mounting and adjustment structure for a laser gun sight, comprising:

[0022] A laser pointer, wherein a slide rail is provided on the laser pointer;

[0023] A clamping seat, one end of which is provided with a slot for mounting the clamping seat on the gun body, and the other end of which is provided with a groove for mounting the slide rail;

[0024] A clamping assembly is disposed on the clamping seat. The clamping assembly includes a clamping member and a telescopic member. One end of the telescopic member abuts against the clamping seat, and the other end of the telescopic member abuts against the clamping member.

[0025] The telescopic member is configured to deform between a first state and a second state; in the first state, the clamping member abuts against the slide rail to lock the slide rail in place within the slide groove; in the second state, the clamping member dynamically contacts the slide rail, and the slide rail can move along the direction of the slide groove to adjust the installation position of the laser pointer.

[0026] This application features a simple structure and convenient operation, enabling rapid adjustment and locking of the laser designator's position, ensuring its stability during gun use. Specifically, in the first state, the clamping member abuts against the slide rail to lock it securely within the groove, preventing the laser gun from wobbling on the clamping seat due to gun vibration, thus affecting the effectiveness and accuracy of firing. In the second state, the clamping member dynamically contacts the slide rail, preventing the slide rail from detaching from the groove during laser designator position adjustment along its direction, facilitating rapid positioning after laser designator adjustment. Attached Figure Description

[0027] Figure 1 A schematic diagram of the mounting and adjustment structure for the laser gun sight provided by this utility model.

[0028] Figure 2 An exploded view of the mounting and adjustment structure for the laser gun sight provided by this utility model.

[0029] Figure 3 This is an exploded view of the clamping base and clamping components in the installation and adjustment structure of the laser gun sight provided by this utility model.

[0030] Figure 4 This is a schematic diagram of the assembly of the cover plate, clamping assembly, and clamping base in the installation and adjustment structure of the laser gun sight provided by this utility model.

[0031] Figure 5 A schematic diagram of the clamping component in the mounting and adjustment structure of the laser gun sight provided by this utility model.

[0032] Attached icon number

[0033] Laser pointer 1, slide rail 11, first protrusion 111, clamping seat 2, fixed clamping block 201, movable clamping block 202, locking component 203, slot 21, slide groove 22, threaded hole 23, receiving groove 24, opening 241, clamping assembly 3, clamping component 31, mounting surface 311, telescopic component 32, fastener 33, step portion 34, second protrusion 341, cover plate 4. Detailed Implementation

[0034] To make the objectives, technical solutions, and effects of this utility model clearer and more explicit, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain this utility model and are not intended to limit this utility model.

[0035] It should be noted that when a component is referred to as being "mounted on," "fixed to," or "set on" another component, it can be directly on the other component or may have an intervening component present. When a component is referred to as being "connected to" another component, it can be directly connected to the other component or may have an intervening component present.

[0036] It should also be noted that the directional terms such as left, right, up, and down in the embodiments of this utility model are only relative concepts or are based on the normal use state of the product, and should not be considered as restrictive.

[0037] A laser gun sight is a device that uses a laser beam to assist aiming. It is widely used in firearms, crossbows, and other projectile weapons. By projecting a laser point onto the target, it helps the user to quickly and accurately aim at the target. A gun light is a flashlight used with firearms to help the user identify and illuminate targets in low-light environments.

[0038] In existing technologies, quick-release mechanisms (i.e., mounting and adjustment mechanisms) for gun lights are typically applied to laser sights. To accommodate different gun models and user adjustment needs, the laser sight needs to slide back and forth on the mounting and adjustment mechanism to bring it closer to the trigger guard, making it easier for the user to press the laser sight's on / off button. However, existing mounting and adjustment mechanisms have many components, resulting in a complex structure. Furthermore, the primary function of a gun light is to roughly illuminate the area in front, rather than precisely pointing to a specific point. Even if the gun light shakes slightly after firing, as long as the beam covers the target area, it still meets the illumination requirements. Laser sights, on the other hand, require the laser beam to fall precisely on the desired point of impact for quick positioning and improved accuracy. Therefore, gun lights and laser sights have different stability requirements when mounted on the gun. However, when using existing mounting and adjustment mechanisms to mount laser sights, if the user's grip is unstable or the gun shakes after firing, the mounting and adjustment mechanism cannot effectively secure the laser sight, causing it to wobble on the mounting and adjustment mechanism and affecting the effectiveness of subsequent firings.

[0039] In view of the shortcomings of the prior art, this utility model provides a mounting and adjustment structure for a laser gun sight. Please refer to [link / reference]. Figures 1-5 ,include:

[0040] Laser pointer 1, wherein a slide rail 11 is provided on the laser pointer 1;

[0041] The clamping seat 2 has a slot 21 at one end for mounting the clamping seat 2 on the gun body, and a slide groove 22 at the other end for mounting the slide rail 11.

[0042] A clamping assembly 3 is disposed on the clamping base 2. The clamping assembly 3 includes a clamping member 31 and a telescopic member 32. One end of the telescopic member 32 abuts against the clamping base 2, and the other end of the telescopic member 32 abuts against the clamping member 31.

[0043] The telescopic member 32 is configured to deform between a first state and a second state; in the first state, the clamping member 31 abuts against the slide rail 11 to lock the slide rail 11 in the slide groove 22; in the second state, the clamping member 31 is in dynamic contact with the slide rail 11, and the slide rail 11 can move along the direction set by the slide groove 22 to adjust the installation position of the laser pointer 1.

[0044] This application features a simple structure and convenient operation, enabling rapid adjustment and locking of the laser designator 1's position, ensuring its stability during gun use. Specifically, in the first state, the telescopic member 32 engages with the slide rail 11 to lock it securely within the slide groove 22, preventing the laser gun from wobbling on the clamping seat 2 due to gun body vibration, thus affecting the effectiveness and accuracy of firing. In the second state, the telescopic member 32 engages with the slide rail 11 in dynamic contact, preventing the slide rail 11 from detaching from the slide groove 22 during laser designator 1's position adjustment along its direction, facilitating rapid positioning of the laser designator 1 after adjustment. In this application, the upper end of the clamping seat 2 extends to form a fixed clamping block 201. The fixed clamping block 201 is provided with a movable clamping block 202 on the opposite side of the clamping seat 2. The movable clamping block 202 is detachably mounted on the clamping seat 2 by a locking member 203. One end of the locking member 203 passes through the through hole on the clamping seat 2 and is screwed into the fixed threaded hole on the movable clamping block 202. The upper end of the clamping seat 2, the fixed clamping block 201 and the movable clamping block 202 define a slot 21 for mounting on the gun body.

[0045] Furthermore, the clamping assembly 3 also includes a fastener 33 located on one side of the clamping member 31. The fastener 33 is adjusted to allow the telescopic member 32 to switch between the first state and the second state. In the first state, the fastener 33 abuts against the clamping member 31; in the second state, there is no interaction force between the fastener 33 and the clamping member 31.

[0046] In this application, the top of the clamping base 2 is provided with a slot 21 for the clamping base 2 to be installed on the gun body, and the bottom of the clamping base 2 is provided with a groove 22 for the slide rail 11 on the laser pointer 1 to be installed. The slide rail 11 is fixed to the upper end of the laser pointer 1 by screwing. When the fastener 33 is installed on the clamping base 2 and the slide rail 11 of the laser pointer 1 is installed in the groove 22 of the clamping base 2, the fastener 33 and the slide rail 11 are located on opposite sides of the clamping member 31.

[0047] When the drive fastener 33 moves toward the side of the slide rail 11 and its end contacts the clamping member 31, the fastener 33 pushes the clamping member 31 to squeeze the side of the slide rail 11. As the movement of the fastener 33 increases, the clamping member 31 abuts against the slide rail 11. The clamping member 31 and the side wall of the slide groove 22 cooperate to lock the slide rail 11 in the slide groove 22. At this time, the telescopic member 32 is in the first state, and the laser pointer 1 cannot adjust its installation position along the direction set by the slide groove 22. Based on the above structure, when the user takes the gun out of the holster or after the gun is fired, the fastener 33 locks the slide rail 11 in the slide groove 22 through the clamping member 31, thereby preventing the slide rail 11 from shaking in the slide groove 22 and ensuring the stable installation of the laser pointer 1.

[0048] When the fastener 33 moves away from the slide rail 11 and there is no interaction force between the fastener 33 and the clamping member 31, the telescopic member 32 is in the second state. Under the action of the telescopic member 32, the clamping member 31 dynamically contacts the slide rail 11. The laser pointer 1 can be adjusted on the clamping seat 2 by the slide rail 11 along the setting direction of the slide groove 22, so that the laser pointer 1 can be adapted to different gun types or usage requirements. In this application, the cooperation relationship between the fastener 33 and the clamping member 31 is adjusted to allow the telescopic member 32 to switch between the first state and the second state. The structure is simple and the adjustment is convenient. It ensures that the slide rail 11 is locked and fixed in the slide groove 22 when the telescopic member 32 is in the first state, and that the slide rail 11 is in the slide groove 22 and can move along the setting direction of the slide groove 22 to adjust the position of the laser pointer 1 when the telescopic member 32 is in the second state.

[0049] Furthermore, the fastener 33 is a screw, and the clamping seat 2 is provided with a threaded hole 23 for fitting the fastener 33. In this embodiment, a screw is used as the fastener 33, which has a simple structure and is easy to assemble and disassemble; the lateral force applied by the screw pushes the clamping member 31 to abut against the side wall of the slide rail 11, so that the slide rail 11 is locked and fixed in the slide groove 22, ensuring that the laser pointer 1 will not be affected by the vibration of the gun body and its stability on the clamping seat 2.

[0050] In one embodiment of this application, the fastener 33 is a Kimi screw, the head of which has an internal hexagonal socket design, and the depth of the threaded hole 23 is not less than the length of the fastener 33. The reason for using a Kimi screw as the fastener 33 is that, after installation, the head of the Kimi screw can be embedded in the threaded hole 23 or flush with the end face of the threaded hole 23, making the clamping base 2 appear flat and aesthetically pleasing. This prevents the screw head from protruding and affecting the installation and removal of the laser pointer 1, and also prevents scratching the user or other parts of the gun body. It also helps maintain the overall aesthetics and streamlined shape of the laser gun sight. Furthermore, the internal hexagonal socket design of the Kimi screw head provides greater torque when tightening the screw, reducing the likelihood of slippage and making the installation and removal process smoother, thus improving the efficiency of laser gun sight assembly and disassembly. Of course, other screws or structures that can abut the clamping member 31 against the slide rail 11 and lock the slide rail 11 in the slide groove 22 can also be used; this application does not limit the specific use of these screws.

[0051] Furthermore, the telescopic member 32 is a circular compression spring. The second state is the compressed state of the compression spring. Only when it is in the compressed state can the telescopic member act on the clamping member 31, ensuring that the clamping member 31 is dynamically connected to the slide rail 11.

[0052] Preferably, in one embodiment of this application, the first state is a compressed spring state. In this case, the distance by which the fastener 33 drives the clamping member 31 to move and abut against the slide rail 11 is still less than the deformation length of the compressed spring changing from the compressed state to the extended state. At this time, the compressed spring in the first state is slightly extended compared to the compressed spring in the second state, but is still in a compressed state (the compressed state and extended state here are described in comparison with the state in which the compressed spring is not under force). In this embodiment, when the spring is in the second state... There is no interaction force between the fastener 33 and the clamping member 31. One end of the telescopic member 32 abuts against the clamping seat 2, and the other end of the telescopic member 32 abuts against the clamping member 31. At this time, the clamping member 31 is always in contact with the side wall of the slide rail 11 under the elastic force of the telescopic member 32. By generating an adjustable squeezing force on the side wall of the slide rail 11 or the friction force generated by the contact between the two, the slide rail 11 is prevented from falling out of the slide groove 22. Thus, when the slide rail 11 moves along the setting direction of the slide groove 22, the clamping member 31 can quickly position the slide rail 11.

[0053] Furthermore, the slide rail 11 is provided with a first protrusion 111, and the clamping member 31 is provided with a second protrusion 341 that is adapted to the first protrusion 111; when the telescopic member 32 is in the second state and the laser indicator 1 is adjusted along the direction of the slide groove 22, the first protrusion 111 and the second protrusion 341 are in continuous contact.

[0054] In this embodiment, when the telescopic member 32 is in the second state, the telescopic member 32, under the action of elasticity, drives the second protrusion 341 on the clamping member 31 to engage with the two adjacent first protrusions 111 on the side wall of the slide rail 11. The protrusions on the clamping member 31 and the slide rail 11 increase the contact area between the clamping member 31 and the slide rail 11, further improving the stability of the slide rail 11 assembled in the slide groove 22 when the telescopic member 32 is in the second state. In addition, when the telescopic member 32 is in the second state, the first protrusion 111 and the second protrusion 341 are in continuous contact. When the laser pointer 1 adjusts its position along the direction set by the slide groove 22, the continuous first protrusion 111 on the slide rail 11 will move along the direction set by the slide groove 22 and dynamically contact the second protrusion 341 on the clamping member 31, generating a clear collision sound or tactile feedback, which is beneficial for the laser pointer 1 to achieve rapid positioning during adjustment.

[0055] Furthermore, the clamping base 2 is provided with a receiving groove 24 for placing the clamping member 31, and a gap is defined between the clamping member 31 and the receiving groove 24 to allow the clamping member 31 to approach or move away from the slide rail 11; the receiving groove 24 is provided with an opening 241, and the opening 241 is located on one side of the slide groove 22. When the telescopic member 32 is in the first state, the clamping member 31 enters the opening 241 and abuts against the slide rail 11.

[0056] The gap defined between the clamping member 31 and the receiving cavity in this application provides space for dynamic adjustment of the clamping member 31 when the slide rail 11 moves along the setting direction of the slide groove 22. The setting of the telescopic member 32 makes the position adjustment of the clamping member 31 in the receiving groove 24 faster, which is conducive to the clamping member 31 quickly positioning the slide rail 11 in the slide groove 22 and improving the efficiency of the position adjustment of the laser pointer 1. The lower end of the clamping member 31 is provided with a step portion 34, and the side wall of the step portion 34 facing the slide rail 11 is provided with a second protrusion 341. The second protrusion 341 can contact and cooperate with the first protrusion 111 when the clamping member 31 moves towards the slide rail 11 to limit the slide rail 11 in the slide groove 22.

[0057] In this embodiment, two telescopic members 32 are provided and located on the mounting surface 311 of the clamping member 31. The mounting surface 311 forms a T-shaped structure at the upper end of the clamping member 31. One end of the telescopic member 32 abuts against the inner wall of the receiving groove 24, and the other end of the telescopic member 32 abuts against the end of the T-shaped structure. A cover plate 4 is provided above the clamping member 31 to confine the telescopic member 32 within the space defined by the cover plate 4 and the clamping member 31. In the second state, the two telescopic members 32 help improve the stability of the dynamic contact between the clamping member 31 and the slide rail 11, ensuring that the clamping member 31 and the slide rail 11 remain in continuous contact during the movement of the slide rail 11, so that the slide rail 11 can be quickly locked and positioned when the second state is changed to the first state. The mounting surface 311 is at least partially curved, which on the one hand makes the axis of the telescopic member 32 consistent with the direction of force during the deformation process, which helps to improve the conversion efficiency of the telescopic member 32 between the first state and the second state and ensures the smoothness of the conversion. On the other hand, it can make the end of the telescopic member 32 evenly distributed, avoiding excessive local stress that could cause the telescopic member 32 to wear, deform or even break.

[0058] In this application, the clamping member 31 is first placed in the receiving groove 24, and then two telescopic members 32 are placed on the mounting surface 311 of the clamping member 31 respectively. The cover plate 4 is fixed above the clamping member 31 by screwing, so as to ensure that the telescopic members 32 are stably placed in the space defined by the cover plate 4 and the clamping member 31. The overall structure is simple, compact, and easy to assemble and disassemble. The receiving groove 24 plays a guiding and limiting role in the process of the clamping member 31 moving closer to or away from the slide rail 11, so that the clamping member 31 can move quickly along the receiving groove 24, thereby facilitating the clamping member 31 to quickly position the slide rail 11.

[0059] In summary, the laser gun sight mounting and adjustment structure provided by this utility model includes:

[0060] A laser pointer, wherein a slide rail is provided on the laser pointer;

[0061] A clamping seat, one end of which is provided with a slot for mounting the clamping seat on the gun body, and the other end of which is provided with a groove for mounting the slide rail;

[0062] A clamping assembly is disposed on the clamping seat. The clamping assembly includes a clamping member and a telescopic member. One end of the telescopic member abuts against the clamping seat, and the other end of the telescopic member abuts against the clamping member.

[0063] The telescopic member is configured to deform between a first state and a second state; in the first state, the clamping member abuts against the slide rail to lock the slide rail in place within the slide groove; in the second state, the clamping member dynamically contacts the slide rail, and the slide rail can move along the direction of the slide groove to adjust the installation position of the laser pointer.

[0064] This application features a simple structure and convenient operation, enabling rapid adjustment and locking of the laser designator's position, ensuring its stability during gun use. Specifically, in the first state, the clamping member abuts against the slide rail to lock it securely within the groove, preventing the laser gun from wobbling on the clamping seat due to gun vibration, thus affecting the effectiveness and accuracy of firing. In the second state, the clamping member dynamically contacts the slide rail, preventing the slide rail from detaching from the groove during laser designator position adjustment along its direction, facilitating rapid positioning after laser designator adjustment.

[0065] It is understood that those skilled in the art can make equivalent substitutions or changes based on the technical solution and inventive concept of this utility model, and all such substitutions or changes should fall within the protection scope of the appended claims of this utility model.

Claims

1. A mounting and adjustment structure for a laser gun sight, characterized in that, include: A laser pointer (1) is provided with a slide rail (11). The clamping seat (2) has a slot (21) at one end for mounting the clamping seat (2) on the gun body, and a slide groove (22) at the other end for mounting the slide rail (11). A clamping assembly (3) is disposed on the clamping seat (2). The clamping assembly (3) includes a clamping member (31) and a telescopic member (32). One end of the telescopic member (32) abuts against the clamping seat (2), and the other end of the telescopic member (32) abuts against the clamping member (31). The telescopic member (32) is configured to deform between a first state and a second state; in the first state, the clamping member (31) abuts against the slide rail (11) to lock the slide rail (11) in the slide groove (22); in the second state, the clamping member (31) makes dynamic contact with the slide rail (11), and the slide rail (11) can move along the direction set by the slide groove (22) to adjust the installation position of the laser pointer (1).

2. The mounting and adjustment structure for the laser gun sight according to claim 1, characterized in that, The clamping assembly (3) also includes a fastener (33) located on one side of the clamping member (31), and the fastener (33) is adjusted to allow the telescopic member (32) to switch between the first state and the second state.

3. The mounting and adjustment structure for the laser gun sight according to claim 2, characterized in that, In the first state, the telescopic member (32) abuts against the clamping member (31); in the second state, the telescopic member (32) has no interaction force with the clamping member (31).

4. The mounting and adjustment structure for the laser gun sight according to claim 3, characterized in that, The fastener (33) is a screw, and the clamping seat (2) is provided with a threaded hole (23) for adapting to the fastener (33).

5. The mounting and adjustment structure for the laser gun sight according to claim 4, characterized in that, The fastener (33) is a kimming screw, and the depth of the threaded hole (23) is not less than the length of the fastener (33).

6. The mounting and adjustment structure for a laser gun sight according to any one of claims 1-5, characterized in that, The telescopic component (32) is a compression spring.

7. The mounting and adjustment structure for the laser gun sight according to claim 6, characterized in that, The second state is the compressed state of the compression spring.

8. The mounting and adjustment structure for the laser gun sight according to claim 6, characterized in that, The slide rail (11) is provided with a first protrusion (111), and the clamping member (31) is provided with a second protrusion (341) that is adapted to the first protrusion (111); when the telescopic member (32) is in the second state and the laser pointer (1) is adjusted along the direction of the slide groove (22), the first protrusion (111) and the second protrusion (341) are in continuous contact.

9. The mounting and adjustment structure for the laser gun sight according to claim 6, characterized in that, The clamping seat (2) is provided with a receiving groove (24) for placing the clamping member (31). A gap is defined between the clamping member (31) and the receiving groove (24) for the clamping member (31) to approach or move away from the slide rail (11). An opening (241) is provided in the receiving groove (24), and the opening (241) is located on one side of the slide groove (22). When the telescopic member (32) is in the first state, the clamping member (31) enters the opening (241) and abuts against the slide rail (11).

10. The mounting and adjustment structure for a laser gun sight according to claim 9, characterized in that, Two telescopic members (32) are provided and located on the mounting surface (311) of the clamping member (31). The mounting surface (311) is at least partially arc-shaped, and the mounting surface (311) forms a T-shaped structure at the upper end of the clamping member (31). One end of the telescopic member (32) abuts against the inner wall of the receiving groove (24), and the other end of the telescopic member (32) abuts against the end of the T-shaped structure. A cover plate (4) is provided above the clamping member (31) to confine the telescopic member (32) within the space defined by the cover plate (4) and the clamping member (31).

Images