Dot sight
By designing a thin-bottomed dot sight, the problem of existing sights obstructing the mechanical aiming mechanism has been solved, enabling aiming to still be achieved using the mechanical aiming mechanism even when it fails, thus improving shooting accuracy and user experience.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- ZHUHAI MEFO OPTICAL INSTR CO LTD
- Filing Date
- 2025-03-11
- Publication Date
- 2026-06-11
AI Technical Summary
Existing scopes, when installed, obstruct the iron sights of the pistol, affecting the user experience, especially when the iron sights are malfunctioning or damaged, making it impossible to aim using the iron sights.
Design a dot sight with a bottom thickness of less than or equal to 2.5mm. It is connected to the gun body by fasteners. The light source and battery mechanism are set on the side wall to ensure that the iron sights are not obstructed after installation, and the front sight can be observed through the rear sight and optical channel.
Even when the scope fails, the pistol can still be aimed at the target through the mechanical sights, maintaining the accuracy of the pistol while ensuring a secure installation and a good user experience.
Smart Images

Figure CN2025081956_11062026_PF_FP_ABST
Abstract
Description
Dot sight Technical Field
[0001] This invention belongs to the field of aiming scope technology, and particularly relates to a dot sight. Background Technology
[0002] Handguns, due to their lightweight and portability, and their ability to accurately hit targets at a certain distance, are one of the best choices for shooters in hunting and shooting situations. To improve shooting accuracy, most handguns on the market today are equipped with mechanical sights, making it easier for shooters to aim at targets.
[0003] For example, utility model patent CN217403266U discloses a red dot sight that facilitates ballistic adjustment. On one hand, it seals the optical channel of the scope body using a reflecting lens and a transparent baffle to prevent rainwater from entering and affecting light propagation. On the other hand, by placing the ballistic adjustment pin on the top of the scope body, it prevents the adjustment tool from obstructing the field of view during ballistic adjustment, facilitating the shooter's operation. Another example is a closed-type sight disclosed in utility model patent CN214701937U. To make the sight less susceptible to the effects of moisture and impurities in the environment, this patent's technical solution places the light source in a sealed environment and fills it with nitrogen for protection, giving the sight high stability. (The last sentence appears to be incomplete and possibly refers to another patent; it's unclear what the intended meaning is.) Patent application 117537662A discloses an optical sight that, by using a connecting component passing through a clearance hole and sealing it in the mounting hole, and by using a sealing component installed in the clearance hole, can seal the interior of the optical sight and connect it to an instrument. Compared with the prior art, installing the optical sight onto the instrument reduces the difficulty of installation and improves the installation efficiency. Furthermore, by using the connecting component and the sealing component to seal the interior of the optical sight, it is less likely for foreign objects to enter between the two lenses, thereby improving the cleanliness of the lenses and enhancing the user experience.
[0004] However, most existing scopes are mounted between the rear and front sights of the mechanical sights, and the height of the scope base is higher than the center of the rear and front sights, which will partially or even completely block the mechanical sights. When the scope fails or is damaged and cannot be used, the shooter cannot use the mechanical sights on the pistol to aim at the target, which seriously affects the shooter's user experience. Summary of the Invention
[0005] The purpose of this invention is to provide a dot sight that solves the technical problem that existing sights, after installation, obstruct the mechanical aiming mechanism of a pistol, affecting the user experience.
[0006] This invention is implemented as follows: a dot sight includes a scope body, a first lens, a light source mechanism, and a battery mechanism. The scope body has a bottom and a side wall, which together form an optical channel. The first lens is disposed within the optical channel. The light source mechanism is disposed on the side wall and is used to emit light to the first lens to provide an aiming reference for the user. The battery mechanism is disposed on the side wall and is electrically connected to the light source mechanism to supply power to it. The bottom of the scope body is connected to the gun body by fasteners. The thickness of the bottom is less than or equal to 2.5 mm. After the scope body is installed, the user can observe the front sight through the rear sight and the optical channel.
[0007] In one optional embodiment, a connecting base plate is provided between the bottom of the scope and the gun body, the connecting base plate is connected to the gun body by fasteners, and the bottom of the scope is connected to the connecting base plate and the gun body by fasteners.
[0008] In an alternative embodiment, the fastener is secured by a fastening tool, and the sidewall is provided with a clearance structure for avoiding the fastening tool.
[0009] In an optional embodiment, the sidewall includes a top surface portion and a side surface portion, the top surface portion being opposite to and spaced apart from the bottom surface portion, the side surface portion being connected between the top surface portion and the bottom surface portion, and the clearance structure including a first clearance hole disposed on the top surface portion, the position of the first clearance hole corresponding to the position of the fastener.
[0010] In an optional embodiment, the avoidance structure further includes a second avoidance hole, and the second avoidance hole is disposed on the side portion of the sidewall.
[0011] In an optional embodiment, a sealing member is further provided at the first clearance hole, the sealing member being used to seal the first clearance hole when the mirror body is in operation.
[0012] In an optional embodiment, a drainage hole is provided on the bottom for draining water accumulated in the optical channel to the outside of the lens body.
[0013] In one alternative embodiment, the sidewall includes a top portion and a side portion, the top portion being opposite to and spaced apart from the bottom portion, the side portion being connected between the top portion and the bottom portion, and the clearance structure including a second clearance hole disposed on the side portion, the position of the second clearance hole matching the position of the fastener.
[0014] In one optional embodiment, the light source mechanism includes a light source, a mounting base, a ballistic adjustment mechanism, and a wind deflection adjustment mechanism. The mounting base is movably disposed on the mirror body, the light source is disposed on the mounting base, the ballistic adjustment mechanism is disposed on the mirror body, the ballistic adjustment mechanism is used to adjust the position of the mounting base along a first direction, and the wind deflection adjustment mechanism is disposed on the mirror body, the wind deflection adjustment mechanism is used to adjust the position of the mounting base along a second direction, and the first direction and the second direction are set at an angle.
[0015] In an optional embodiment, the ballistic adjustment mechanism includes a ballistic slider, a ballistic drive unit, and a first return assembly. The ballistic slider is slidably disposed on the scope body, at least a portion of the ballistic slider abuts against the mounting base, and the ballistic drive unit is disposed on the scope body. The ballistic drive unit is used to drive the ballistic slider to move along the first direction. The first return assembly is disposed between the scope body and the mounting base, and the first return assembly is used to apply a force toward the ballistic slider to the mounting base so that the mounting base and the ballistic slider remain in contact.
[0016] In an optional embodiment, the ballistic drive unit includes a ballistic adjustment pin, which is rotatably disposed on the scope body. The axis of the ballistic adjustment pin is disposed along the first direction, and the ballistic adjustment pin has a degree of freedom to rotate about its own axis relative to the scope body. At least a portion of the ballistic adjustment pin is threadedly connected to at least a portion of the ballistic slider.
[0017] In an optional embodiment, the wind deflection adjustment mechanism includes a wind deflection slider, a wind deflection drive unit, and a second return assembly. The wind deflection slider is slidably disposed on the mirror body, and the wind deflection drive unit is disposed on the mirror body. The wind deflection drive unit is used to drive the wind deflection slider to move along the second direction. The second return assembly is disposed between the mirror body and the mounting base. The wind deflection slider and the second return assembly respectively abut against the mounting base on both sides along the second direction. The second return assembly is used to apply a force to the mounting base toward the wind deflection slider.
[0018] In an optional embodiment, the wind deflection drive unit includes a wind deflection adjustment pin, which is rotatably disposed on the mirror body. The axis of the wind deflection adjustment pin is disposed along the second direction. The wind deflection adjustment pin has a degree of freedom to rotate about its own axis relative to the mirror body. At least a portion of the wind deflection adjustment pin is threadedly connected to at least a portion of the wind deflection slider.
[0019] In an alternative embodiment, the dot sight further includes a second lens, which is spaced apart from the first lens along the length of the optical channel.
[0020] In one alternative embodiment, the periphery of the first lens is sealed to the lens body, and the periphery of the second lens is also sealed to the lens body. The first lens, the second lens, and at least a portion of the inner wall surface of the optical channel form a sealed cavity.
[0021] In an optional embodiment, the connecting base plate has a threaded hole for engaging with the fastener. The threaded hole is located on the side of the second lens opposite to the first lens and is spaced apart from the second lens. The minimum distance between the inner wall of the threaded hole and the side of the second lens opposite to the first lens is 2 mm to 5 mm.
[0022] In an optional embodiment, a power receiving component is further provided on the side wall. The power receiving component is electrically connected to the battery mechanism and is used to receive electrical energy output from the wireless power supply terminal to charge the battery mechanism.
[0023] In an optional embodiment, the connecting base plate is further provided with a positioning engagement structure, which is used to position the mirror body on the connecting base plate.
[0024] In one alternative embodiment,
[0025] The joining structure includes joining posts, and the bottom of the lens body is provided with joining holes for engaging with the joining posts. The number of joining posts is at least two, and the number of joining holes matches the number of joining posts. The connecting base plate is provided with at least two threaded holes for connecting with the lens body.
[0026] Alternatively, the joining structure includes a joining post, and the bottom of the lens body is provided with a joining hole for engaging with the joining post. The number of joining posts is at least two, the number of joining holes matches the number of joining posts, and the connecting base plate is provided with a threaded hole for connecting with the lens body.
[0027] Alternatively, the joining structure includes a joining block, the bottom of the lens body is provided with a joining groove for engaging with the joining block, and the connecting base plate is provided with at least two threaded holes for connecting with the lens body;
[0028] Alternatively, the joining structure includes a joining block, the bottom of the lens body is provided with a joining groove for engaging with the joining block, and the connecting base plate is provided with a threaded hole for connecting with the lens body.
[0029] The technical advantages of this invention compared to existing technologies are as follows: the bottom and side walls of the scope body form an optical channel, and the first lens is placed within the optical channel. A light source mechanism and a battery mechanism are also provided on the side walls of the scope body. The battery mechanism provides power to the light source mechanism, enabling it to emit light that illuminates the first lens. The first lens then processes and reflects the light, forming specific aiming marks for easy aiming. Furthermore, the bottom of the scope body is connected to the gun body via fasteners, and the thickness of the bottom is less than or equal to 2.5mm. Therefore, after the scope body is installed, the user can observe the front sight through the rear sight and the optical channel. Compared to existing scopes, this new technology connects the bottom of the scope body to the gun body or a base plate during installation. The light source and battery mechanisms are located on the side walls of the scope body, excluding the bottom. This allows for a thinner bottom, less than or equal to 2.5mm, lower than the height of the mechanical sights on the firearm. This prevents the bottom of the scope from being thicker than the center of the rear and front sights, thus avoiding obstruction of the mechanical sights. After installation, the user can observe the front and rear sights through the rear and optical channels. Therefore, even if the scope fails, the shooter can still aim at the target through the mechanical sights on the gun, maintaining the pistol's accuracy while ensuring a secure installation. Attached Figure Description
[0030] To more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments of the present invention or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0031] Figure 1 is a schematic diagram of the structure of a pistol in the prior art;
[0032] Figure 2 is a schematic diagram of the structure of a scope mounted on a pistol in the prior art;
[0033] Figure 3 is a side view of the existing technology of mounting a scope on a pistol;
[0034] Figure 4 is a schematic diagram of the installation state structure of the dot sight provided in an embodiment of the present invention;
[0035] Figure 5 is a schematic diagram of the structure of a dot sight provided in an embodiment of the present invention;
[0036] Figure 6 is a schematic diagram of the structure of a dot sight provided in one embodiment of the present invention;
[0037] Figure 7 is an exploded structural diagram of a dot sight provided in an embodiment of the present invention;
[0038] Figure 8 is an enlarged structural diagram of point A in Figure 7;
[0039] Figure 9 is a side view of a dot sight provided in an embodiment of the present invention.
[0040] Figure 10 is a schematic cross-sectional view of the structure along line BB in Figure 9;
[0041] Figure 11 is a side view of a dot sight provided in an embodiment of the present invention.
[0042] Figure 12 is a schematic cross-sectional view of the structure along line CC in Figure 11;
[0043] Figure 13 is a schematic diagram of the structure of a dot sight provided in another embodiment of the present invention;
[0044] Figure 14 is a schematic diagram of the exploded structure of a dot sight provided in another embodiment of the present invention;
[0045] Figure 15 is a second exploded structural diagram of a dot sight provided in another embodiment of the present invention;
[0046] Figure 16 is a schematic diagram of the structure of a dot sight provided in another embodiment of the present invention;
[0047] Figure 17 is an exploded structural diagram of a dot sight provided in another embodiment of the present invention;
[0048] Figure 18 is a structural schematic diagram of a dot sight provided in another embodiment of the present invention;
[0049] Figure 19 is an exploded structural diagram of a dot sight provided in another embodiment of the present invention;
[0050] Figure 20 is a second exploded structural diagram of a dot sight provided in another embodiment of the present invention;
[0051] Figure 21 is a schematic diagram of the exploded structure of a dot sight provided in another embodiment of the present invention;
[0052] Figure 22 is a schematic diagram of the structure of a dot sight provided in another embodiment of the present invention;
[0053] Figure 23 is a schematic diagram of the connecting base plate used in one embodiment of the present invention;
[0054] Figure 24 is a schematic diagram of the connecting base plate used in another embodiment of the present invention;
[0055] Figure 25 is a schematic diagram of the connecting base plate used in another embodiment of the present invention;
[0056] Figure 26 is a structural schematic diagram of the connecting base plate used in another embodiment of the present invention.
[0057] Explanation of reference numerals in the attached figures:
[0058] 100. Scope; 200. Pistol; 300. Front sight; 400. Rear sight; 500. Fastening tool; 600. Iron sight channel;
[0059] 1. Lens body; 11. Bottom; 12. Side wall; 121. Top surface; 122. Side surface; 13. Optical channel; 14. Fixing structure; 141. Locking through hole; 15. Clearance structure; 151. First clearance hole; 152. Second clearance hole; 16. Drainage hole; 17. Connecting hole; 2. First lens; 3. Light source mechanism; 31. Light source; 32. Mounting base; 33. Ballistic adjustment mechanism; 331. Ballistic slider; 332. Ballistic drive unit; 3321. Ballistic adjustment pin; 333. First return assembly; 3331. First spring; 3 332. First return assembly; 334. Snap ring; 34. Wind deflection adjustment mechanism; 341. Wind deflection sliding component; 342. Wind deflection drive unit; 3421. Wind deflection adjustment pin; 3422. Wind deflection adjustment pin sleeve; 343. Second return assembly; 3431. Second spring; 3432. Second return assembly; 3433. Return fixing component; 4. Battery mechanism; 5. Sealing component; 6. Second lens; 7. Power receiving assembly; 8. Button assembly; 9. Connecting base plate; 91. Connecting post; 92. Connecting block; 93. Threaded hole; 10. Sealing ring; 101. Fastener. Detailed Implementation
[0060] Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, and should not be construed as limiting the present invention.
[0061] In the description of this invention, it should be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.
[0062] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this invention, "a plurality of" means two or more, unless otherwise explicitly specified.
[0063] In this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.
[0064] Please refer to Figure 1. In existing firearms, especially pistols, aiming is achieved using the rear and front sights. To improve accuracy, a scope can also be mounted on the gun. Please refer to Figures 2 and 3. Currently, most existing scopes have a relatively thick base to ensure installation stability. Since the scope is generally mounted between the rear and front sights, when the base of the scope is higher than the center of the rear and front sights, it partially or completely obstructs the firearm's mechanical sights. When the scope malfunctions or is damaged, the firearm cannot be aimed using the mechanical sights, severely impacting the user experience. To address the problem of aiming failure when the scope malfunctions, this application provides a dot sight, the specific solution of which is as follows:
[0065] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to the accompanying drawings and embodiments.
[0066] Referring to Figures 4 to 12, in this embodiment of the invention, a dot sight is provided. The dot sight includes a scope body 1, a first lens 2, a light source mechanism 3, and a battery mechanism 4. The scope body 1 has a bottom 11 and a side wall 12, which together form an optical channel 13 open at both ends. The first lens 2 is disposed within the optical channel 13. The light source mechanism 3 is disposed on the side wall 12 and is used to emit light to the first lens 2 to provide an aiming reference for the user. The battery mechanism 4 is disposed on the side wall 12 and is used to electrically connect with the light source mechanism 3 to supply power to the light source mechanism 3. The bottom 11 of the scope body 1 is connected to the gun body by fasteners. The thickness of the bottom 11 of the scope body 1 is less than or equal to 2.5 mm. After the scope body 1 is installed, the user can observe the front sight through the rear sight and the optical channel 13.
[0067] Specifically, the scope body 1 refers to a shell-like component with a certain volume. The scope body 1 can be a one-piece molded structure, for example, formed by casting, die casting, or machining. The scope body 1 can also be a modular structure, with multiple components assembled by welding, fasteners, or snap-fitting. The optical channel 13 refers to a channel structure with a certain length. To facilitate the propagation of light, the optical channel 13 can be arranged in a straight line. The bottom 11 and the side wall 12 both refer to the structures that enclose the optical channel 13. The bottom 11 and the side wall 12 can be plate-like structures with a certain thickness. In particular, to facilitate connection with the gun body, the bottom 11 can be a flat plate structure. The side wall 12 refers to the other parts of the scope body 1 besides the bottom 11. The side wall 12 can be composed of multiple parts. For example, when the cross-section of the scope body 1 is rectangular, the bottom 11 refers to the side wall of the scope body 1 that is adjacent to the gun body or the connecting base plate 9. In this case, the side wall 12 refers to the sum of the other three side wall surfaces besides the bottom 11. The side wall 12 and the bottom 11 together enclose the entire scope body.
[0068] The first lens 2 refers to a mirror body 1 structure with one or more layers of light-reflecting film coated on its concave surface. This design allows the first lens 2 to process and reflect light, forming specific aiming marks for aiming. The first lens 2 can be a light-reflecting mirror. The light source mechanism 3 refers to a component that can emit light and adjust the starting position of the light. The light source mechanism 3 can emit light towards the first lens 2. The battery mechanism 4 refers to a component that can store and output electrical energy, providing power for the operation of the light source mechanism 3. When installing the battery mechanism 4, a groove structure can be provided on the side wall 12. By placing the battery mechanism 4 in the groove structure, the installation of the battery mechanism 4 can be made more convenient and secure.
[0069] The dot sight provided in this embodiment of the invention has a bottom 11 and side wall 12 of the scope body 1 forming an optical channel 13, within which a first lens 2 is disposed. A light source mechanism 3 and a battery mechanism 4 are also disposed on the side wall 12 of the scope body 1. The battery mechanism 4 provides power to the light source mechanism 3, enabling it to emit light that illuminates the first lens 2, allowing the lens 2 to process and reflect the light, forming a specific aiming mark for aiming. The bottom 11 of the scope body 1 is connected to the gun body via fasteners, and the thickness of the bottom 11 is less than or equal to 2.5 mm. Therefore, after the scope body 1 is installed, the user can observe the front sight through the rear sight and the optical channel 13. Compared to existing scopes, this design allows for a thinner bottom 11. During installation, the bottom 11 of the scope body 1 is connected to the gun body or the base plate 9, and the light source mechanism 3 and battery mechanism 4 are both located on the side wall 12 of the scope body 1, excluding the bottom 11. This results in a thickness of less than or equal to 2.5mm, lower than the height of the mechanical sight channel on the firearm. This prevents the bottom 11 from being thicker than the center of the rear sight and front sight after installation, thus avoiding obstruction of the mechanical sight mechanism. After installation, the user can observe the front sight through the rear sight and optical channel. Even when the scope fails, the shooter can still aim at the target through the mechanical sight mechanism on the gun body, ensuring the firearm maintains accuracy even with a malfunctioning scope, while also guaranteeing a secure installation of the scope.
[0070] It should be noted that in this embodiment, the scope body 1 adopts the above-described structure, which allows the thickness of the bottom 11 of the scope body 1 to be less than or equal to 2.5mm when the bottom 11 of the scope body 1 is connected to the connecting base plate 9. This ensures that the scope will not obstruct the mechanical aiming mechanism of the firearm after installation, thus improving the shooting experience.
[0071] In an optional embodiment, referring to Figures 5 to 7, the bottom 11 has a fixing structure 14. The fixing structure 14 is used for fasteners to pass through the bottom 11, and the fasteners can be completely accommodated inside the fixing structure 14. Specifically, the fixing structure 14 can be a locking through hole 141 provided through the bottom 11, and there can be multiple locking through holes 141. When installing the scope body 1, fasteners such as locking screws can be threaded through the locking through holes 141 and connected to the gun body or connecting base plate 9. The gun body or connecting base plate 9 can be provided with threaded holes for cooperating with the fasteners to achieve the fixing and installation of the scope body 1. The setting of the fixing structure 14 can make the installation and fixing of the scope body 1 more secure and reliable while ensuring that the bottom 11 has a small thickness, avoiding the risk of the scope falling off the gun body.
[0072] In one embodiment, referring to Figures 3 to 5, the fastener may be a countersunk screw. The locking through hole 141 may include a through hole portion for accommodating the main body of the countersunk screw and a receiving groove portion for accommodating the head of the countersunk screw. This allows the head of the countersunk screw to be completely recessed into the locking through hole 141 after installation, preventing the head of the countersunk screw from protruding from the bottom 11 and thus affecting aiming.
[0073] When installing or removing the lens body 1, a wrench or screwdriver or other fastening tool can be inserted into the optical channel 13 through an opening in the optical channel 13 to make it easier to tighten or loosen the fasteners.
[0074] In one embodiment, referring to Figures 4 to 9, a connecting base plate 9 is provided between the bottom 11 of the scope body 1 and the gun body. The connecting base plate 9 is connected to the gun body by fasteners, and the bottom 11 of the scope body 1 is connected to the connecting base plate 9 and the gun body by fasteners. Specifically, the connecting base plate 9 refers to a plate-like structure with a certain area. The function of the connecting base plate 9 is to install the connecting base plate 9 on the gun body when the mounting position of the gun body is not flat enough, and then install the scope body 1 onto the connecting base plate 9. The connecting base plate 9 can be installed on the gun body by fasteners. For example, the connecting base plate 9 can be provided with locking through holes for fasteners to pass through. When installing the connecting base plate 9, fasteners can be inserted into the locking through holes and then threadedly connected to the gun body to fix the connecting base plate 9 to the gun body. In addition, the connecting base plate 9 can be provided with threaded holes 93 for connecting with the scope body 1. The number of threaded holes 93 can be one or more, so that the scope body 1 can be connected to the connecting base plate 9 by fasteners. When a connecting base plate 9 is provided between the bottom 11 of the scope body 1 and the gun body, the thickness of the bottom is 1mm to 2.5mm. This ensures that even with the connecting base plate 9 present, the bottom height of the scope body 1 is still lower than the height of the mechanical sight channel on the firearm after installation. The user can observe the front sight through the rear sight and the optical channel 13, thus avoiding the bottom of the scope from obstructing the mechanical sight mechanism on the firearm.
[0075] In one embodiment, referring to Figures 5 to 7, fasteners are fixed using fastening tools. A clearance structure 15 is provided on the side wall 12 to allow the fastening tool to pass through. Specifically, the clearance structure 15 can be a structure on the side wall 12 that allows components to pass through the side wall 12 into the optical channel 13. The clearance structure 15 can be a hole structure or a slotted structure, etc. When installing the scope body 1, fasteners such as locking screws can be threaded through the locking through-hole 141 and connected to the gun body or connecting base plate 9. The gun body or connecting base plate 9 can be provided with threaded holes for engaging with the fasteners. The scope body 1 is fixed and installed using fasteners. When installing or removing the scope body 1, fastening tools such as wrenches or screwdrivers can be inserted into the optical channel 13 through the clearance structure 15, allowing the fastening tool to contact the fastener, thus making tightening and loosening the fasteners more convenient and quick.
[0076] In one embodiment, referring to Figures 5 and 7, the sidewall 12 includes a top portion 121 and a side portion 122. The top portion 121 is opposite to and spaced apart from the bottom 11. The side portion 122 is connected between the top portion 121 and the bottom 11. The clearance structure 15 includes a first clearance hole 151 provided on the top portion 121. The position of the first clearance hole 151 corresponds to the position of the fastener on the bottom 11.
[0077] Specifically, the top portion 121 and the side portion 122 both refer to plate-like structures with a certain area. The top portion 121, the side portion 122, and the bottom portion 11 can be separate structures, connected by means such as welding, fasteners, or snap-fit. The top portion 121, the side portion 122, and the bottom portion 11 can also be an integral structure, manufactured by stamping, casting, or machining. The first clearance hole 151 refers to a hole structure provided on the top portion 121. The shape of the first clearance hole 151 can be a round hole, a square hole, or an oblong hole. There can be multiple first clearance holes 151, and the number of first clearance holes 151 can match the number of locking through holes 141. By dividing the sidewall 12 into a top portion 121 and a side portion 122, the top portion 121 and the bottom portion 11 are opposite to each other and spaced apart, and the side portion 122 is connected between the top portion 121 and the bottom portion 11. There can be two side portions 122. The bottom portion 11, the top portion 121 and the two side portions 122 can be arranged to form a rectangular optical channel 13.
[0078] By setting the first clearance hole 151 on the top surface portion 121 opposite to the bottom 11, and the position of the first clearance hole 151 corresponding to the position of the fixing structure 14, for example, when the fixing structure 14 adopts the locking through hole 141, the axis of the first clearance hole 151 can be on the same straight line as the axis of the locking through hole 141, so that fastening tools such as wrenches or screwdrivers can move in a straight line through the first clearance hole 151 and contact the fastener, making the overall installation of the mirror body 1 more convenient and faster.
[0079] Based on the aforementioned first clearance hole 151, as shown in Figures 13 to 15, the clearance structure 15 also includes a second clearance hole 152, and the second clearance holes 152 are all provided on the side portion 122 of the side wall 12. Specifically, the second clearance hole 152 refers to a hole structure that penetrates the side portion 122, and the shape of the second clearance hole 152 can be a round hole, a square hole, or an oblong hole, etc. Since the side portion 122 is adjacent to the bottom 11, by providing the second clearance hole 152 on the side portion 122, during the installation of the lens body 1, fastening tools such as wrenches or screwdrivers can be inserted into the optical channel 13 through the second clearance hole 152 to contact the fasteners, allowing the fastening tools to contact the fasteners with a shorter path of movement.
[0080] In one embodiment, as shown in Figures 13 to 15, a sealing element 5 is also provided at the first clearance hole 151. The sealing element 5 is used to seal the first clearance hole 151 when the scope body 1 is in operation. Specifically, the sealing element 5 refers to a sealing component with a certain volume, and the sealing element 5 can be made of materials such as rubber, polyurethane, or plastic. Since the first clearance holes 151 are all located on the top surface portion 121 opposite to the bottom 11, the first clearance holes 151 are mostly facing upwards during the use of the firearm. Therefore, by providing the sealing element 5 at the first clearance hole 151, the first clearance hole 151 can be sealed, preventing rainwater or other moisture from entering the optical channel 13 through the first clearance hole 151. This keeps the optical channel 13 dry and makes the use of the scope safer.
[0081] In an optional embodiment, referring to Figures 13 and 15, a receiving groove is further provided on the top surface portion 121 of the sidewall 12, and the first clearance holes 151 are all provided on the bottom surface of the receiving groove. The sealing member 5 may include a main body portion and a cylindrical portion. When the sealing member 5 is installed, the main body portion can be installed in the receiving groove, while the cylindrical portion is inserted into the first clearance holes 151. By providing a receiving groove on the top surface portion 121 and dividing the sealing member 5 into a main body portion and a cylindrical portion, the contact area between the sealing member 5 and the sidewall 12 after installation can be increased, thereby improving the sealing performance of the sealing member 5.
[0082] In one embodiment, as shown in Figures 5 to 7, a drainage hole 16 is provided on the bottom 11. The drainage hole 16 is used to drain water accumulated in the optical channel 13 to the outside of the scope body 1. Specifically, the drainage hole 16 refers to a hole structure provided on the bottom 11, and the shape of the drainage hole 16 can be circular, square, or a combination of various shapes. When the firearm is in normal use, the bottom 11 is usually located at the bottom of the entire scope body 1. At this time, the drainage hole 16 on the bottom 11 allows water to be drained to the outside of the optical channel 13 when it is present, thus preventing water from affecting the use of the scope.
[0083] In one embodiment, referring to FIG15, the sidewall 12 includes a top portion 121 and a side portion 122. The top portion 121 is opposite to and spaced apart from the bottom 11. The side portion 122 is connected between the top portion 121 and the bottom 11. The clearance structure 15 includes a second clearance hole 152 provided on the side portion 122, and the position of the second clearance hole 152 matches the position of the fastener on the bottom 11.
[0084] Specifically, the top portion 121 and the side portion 122 both refer to plate-like structures with a certain area. The top portion 121, the side portion 122, and the bottom portion 11 can be separate structures, connected by means such as welding, fasteners, or snap-fit. Alternatively, the top portion 121, the side portion 122, and the bottom portion 11 can be an integral structure, manufactured by stamping, casting, or machining. The second clearance hole 152 refers to a hole structure that penetrates the side portion 122. The shape of the second clearance hole 152 can be round, square, or oblong. Since the side portion 122 is adjacent to the bottom portion 11, the second clearance hole 152 is provided on the side portion 122. During the installation of the scope body 1, fastening tools such as wrenches or screwdrivers can be inserted into the optical channel 13 through the second clearance hole 152 to contact the fasteners. This allows the fastening tools to reach the fasteners with a shorter path, improving the efficiency of disassembling and installing the scope.
[0085] In one embodiment, referring to Figures 7 to 11, the light source mechanism 3 includes a light source 31, a mounting base 32, a ballistic adjustment mechanism 33, and a windage adjustment mechanism 34. The mounting base 32 is movably mounted on the mirror body 1. The light source 31 is mounted on the mounting base 32. The ballistic adjustment mechanism 33 is mounted on the mirror body 1 and is used to adjust the position of the mounting base 32 along a first direction. The windage adjustment mechanism 34 is mounted on the mirror body 1 and is used to adjust the position of the mounting base 32 along a second direction, with the first and second directions forming an angle. Specifically, the light source 31 refers to a component that can convert electrical energy into light energy, and the light source 31 can be an LED (Light-Emitting Diode) lamp bead, etc. The mounting base 32 refers to a component with a certain volume, and the mounting base 32 can be block-shaped, plate-shaped, or column-shaped, etc., and the mounting base 32 can also be composed of a combination of various shapes. Both the ballistic adjustment mechanism 33 and the wind drift adjustment mechanism 34 are components for adjusting the position of an object. The ballistic adjustment mechanism 33 can adjust the position of the mounting base 32 along a first direction to adjust the position of the light source, thus allowing adjustment of the aiming mark according to the ballistic trajectory. Similarly, the wind drift adjustment mechanism 34 can adjust the position of the mounting base 32 along a second direction to adjust the position of the light source, allowing adjustment of the aiming mark according to the wind speed. The first direction can be vertical, and the second direction can be horizontal. When in use, the light source mechanism 3 emits light from the light source 31 onto the first lens 2. The first lens 2 processes and reflects the light, forming a specific aiming mark for aiming. Simultaneously, the ballistic adjustment mechanism 33 and the wind drift adjustment mechanism 34 can adjust the positions of the mounting base 32 and the light source 31, thereby adjusting the position of the aiming mark on the first lens 2.
[0086] It should be noted that, in order to make the use of the light source mechanism 3 more convenient, the mounting base 32 is generally movably mounted on the top surface 121 of the side wall 12. At the same time, the ballistic adjustment mechanism 33 can also be mounted on the top surface 121 of the side wall 12, and the wind deflection adjustment mechanism 34 can be mounted on the top surface 121 of the side wall 12. The wind deflection adjustment mechanism 34 can also be mounted on the top surface 121 of the side wall 12 near the light source 31 and the mounting base 32. These details will not be elaborated here.
[0087] In an optional embodiment, referring to Figures 7 to 11, the mounting base 32 can be slidably disposed on the side wall 12 of the mirror body 1. A receiving space for the mounting base 32 to slide can be provided on the side wall 12 of the mirror body 1. Furthermore, a connecting channel for light to pass through is provided between the receiving space and the optical channel 13. This makes the installation of the light source mechanism 3 safer and more reliable, and also makes it easier for the light emitted by the light source mechanism 3 to illuminate the first lens 2.
[0088] In one embodiment, referring to Figures 8 and 10, the ballistic adjustment mechanism 33 includes a ballistic slider 331, a ballistic drive unit 332, and a first return assembly 333. The ballistic slider 331 is slidably disposed on the mirror body 1, and at least a portion of the ballistic slider 331 abuts against the mounting base 32. The ballistic drive unit 332 is disposed on the mirror body 1 and is used to drive the ballistic slider 331 to move in a first direction. The first return assembly 333 is disposed between the mirror body 1 and the mounting base 32 and is used to apply a force toward the ballistic slider 331 to the mounting base 32 so that the mounting base 32 and the ballistic slider 331 remain in contact.
[0089] Specifically, the ballistic slider 331 refers to a component with a certain volume. The ballistic slider 331 can be block-shaped, plate-shaped, or strip-shaped, and can also be composed of a combination of various shapes. The ballistic drive unit 332 refers to a component or assembly that can adjust the position of an object. The ballistic drive unit 332 can be a screw structure, lever structure, or push block, etc. The first return assembly 333 refers to a component or assembly with a certain elasticity. The first return assembly 333 can be a spring, rubber part, or spring sheet, etc., and can also be a structure composed of a rigid component and a spring, rubber part, or spring sheet, etc. By abutting at least a portion of the ballistic slider 331 against the mounting base 32, and by displacing the first return assembly 333 between the mirror body 1 and the mounting base 32, and by applying a force toward the ballistic slider 331 to the mounting base 32 to keep the mounting base 32 abutting against the ballistic slider 331, the mounting base 32 and the ballistic slider 331 can be prevented from disengaging.
[0090] When the position of the mounting base 32 needs to be adjusted, the ballistic slider 331 can be driven to move along the first direction by the ballistic drive unit 332. Since at least a portion of the ballistic slider 331 abuts against the mounting base 32, the mounting base 32 will also move along with the ballistic slider 331. In addition, a first return assembly 333 is provided between the mirror body 1 and the mounting base 32. By applying a force toward the ballistic slider 331 to the mounting base 32 through the first return assembly 333, the mounting base 32 can still maintain contact with the ballistic slider 331 during movement, thus making it more convenient to adjust the position of the mounting base 32 along the first direction.
[0091] In one embodiment, referring to Figures 8 and 10, the ballistic drive unit 332 includes a ballistic adjustment pin 3321, which is rotatably mounted on the mirror body 1. The axis of the ballistic adjustment pin 3321 is arranged along a first direction, and the ballistic adjustment pin 3321 has the freedom to rotate about its own axis relative to the mirror body 1. At least a portion of the ballistic adjustment pin 3321 is threadedly connected to at least a portion of the ballistic slider 331. Specifically, the ballistic adjustment pin 3321 refers to a component with a certain length. The ballistic adjustment pin 3321 can be columnar or rod-shaped, etc., and its cross-section can be circular to facilitate rotation. The ballistic adjustment pin 3321 can be threaded by having a receiving hole on itself, into which at least a portion of the ballistic slider 331 is inserted. The threaded connection between the two is achieved by having threads on the outer wall of the portion of the ballistic slider 331 inserted into the receiving hole and threads on the inner wall of the receiving hole. Alternatively, a receiving hole can be provided on the ballistic slider 331, and the ballistic adjusting pin 3321 can be inserted into the receiving hole. The two are threadedly connected by providing threads on both the outer wall of the ballistic adjusting pin 3321 and the inner wall of the receiving hole. The ballistic adjusting pin 3321 has the degree of freedom to rotate about its own axis relative to the mirror body 1. This can be achieved by providing a retaining ring 334 between the ballistic adjusting pin 3321 and the mirror body 1. The retaining ring 334 restricts the movement of the ballistic adjusting pin 3321 along its own axis.
[0092] When the position of the ballistic slider 331 needs to be adjusted, the ballistic adjustment pin 3321 can be rotated around its own axis to drive the ballistic slider 331 to move along the axis of the ballistic adjustment pin 3321. This makes the position adjustment of the ballistic slider 331 more convenient, and in turn, makes the position adjustment of the mounting base 32 and the light source 31 more convenient.
[0093] It should be noted that the side wall 12 is provided with an installation space for installing the ballistic adjustment pin 3321. At least part of the ballistic adjustment pin 3321 can be located outside the scope body 1 to facilitate the rotation of the ballistic adjustment pin 3321.
[0094] In one embodiment, referring to Figures 8 and 10, the first return assembly 333 includes a first spring 3331 and a first return member 3332. The mounting base 32 also has a first return hole for mounting the first return member 3332. The first end of the first return member 3332 is movably disposed within the first return hole, while the first spring 3331 is disposed between the first end of the first return member 3332 and the bottom surface of the first return hole. The second end of the first return member 3332 slides against the mirror body 1. This design allows the first return assembly 333 to remain in contact with the mirror body 1 without affecting the sliding of the mounting base 32 in the second direction, making the first return assembly 333 more convenient to use. The first return hole also ensures more stable installation of the first return assembly 333.
[0095] In an optional embodiment, referring to Figures 8 and 10, a sealing ring 10 can be provided between the ballistic adjustment pin 3321 and the scope body 1. The sealing ring 10 is fitted around the periphery of the ballistic adjustment pin 3321. When a retaining ring 334 is present outside the ballistic adjustment pin 3321, the sealing ring 10 can be located outside the retaining ring 334. The sealing ring 10 can maintain the sealing of the ballistic adjustment pin 3321 while it rotates, preventing foreign objects from entering the installation space through the gap between the ballistic adjustment pin 3321 and the scope body 1, thus making the use of the entire scope safer.
[0096] In one embodiment, referring to Figures 8 and 12, the wind deflection adjustment mechanism 34 includes a wind deflection slider 341, a wind deflection drive unit 342, and a second return assembly 343. The wind deflection slider 341 is slidably disposed on the mirror body 1, and the wind deflection drive unit 342 is disposed on the mirror body 1. The wind deflection drive unit 342 is used to drive the wind deflection slider 341 to move along the second direction. The second return assembly 343 is disposed between the mirror body 1 and the mounting base 32. The wind deflection slider 341 and the second return assembly 343 respectively abut against the mounting base 32 on both sides along the second direction. The second return assembly 343 is used to apply a force to the mounting base 32 toward the wind deflection slider 341.
[0097] Specifically, the wind deflector 341 refers to a component with a certain volume. The wind deflector 341 can be block-shaped, column-shaped, or strip-shaped, and can also be composed of a combination of various shapes. The wind deflector drive unit 342 refers to a component or assembly that can adjust the position of an object. The wind deflector drive unit 342 can be a screw structure, lever structure, or push block, etc. The second return assembly 343 refers to a component or assembly with a certain elasticity. The second return assembly 343 can be a spring, rubber part, or spring sheet, etc., and can also be a structure composed of a rigid component and a spring, rubber part, or spring sheet, etc. By abutting the wind deflector 341 and the second return assembly 343 against the mounting base 32 on both sides along the second direction, and simultaneously pushing the wind deflector 341 to move along the second direction by the wind deflector drive unit 342, and the second return assembly 343 is used to apply a force to the mounting base 32 toward the wind deflector 341 so that the mounting base 32 and the wind deflector 341 can remain in contact. When the position of the mounting base 32 needs to be adjusted along the second direction, the wind deflection drive unit 342 can drive the wind deflection slider 341 to move along the second direction. Since the wind deflection slider 341 abuts against the side of the mounting base 32, the mounting base 32 will also move along with the wind deflection slider 341. At the same time, the second return assembly 343 can apply a force towards the wind deflection slider 341 to the mounting base 32 from the other side of the mounting base 32, so that the mounting base 32 can still maintain contact with the wind deflection slider 341 during the movement along the second direction, thus making it easier to adjust the position of the mounting base 32 along the second direction, and consequently making it easier to adjust the position of the light source 31.
[0098] In an optional embodiment, referring to Figures 8 and 12, two first contact surfaces are provided on the ballistic slider 331, which are arranged at an angle to each other and are both parallel to the second direction. One of the two first contact surfaces is either perpendicular to or at an angle to the first direction. Two second contact surfaces are also provided on the mounting base 32 for abutting against the two first contact surfaces, and the positions and angles of the two second contact surfaces match those of the first contact surfaces. By providing first contact surfaces on the ballistic slider 331 and second contact surfaces on the mounting base 32, it can be ensured that while the ballistic slider 331 drives the mounting base 32 to move in the first direction, it does not affect the wind deflection drive unit 342 driving the mounting base 32 to slide in the second direction.
[0099] In one embodiment, referring to Figures 8 and 12, the wind deflection drive unit 342 includes a wind deflection adjusting pin 3421, which is rotatably mounted on the mirror body 1. The axis of the wind deflection adjusting pin 3421 is arranged along a second direction, and the wind deflection adjusting pin 3421 has the freedom to rotate about its own axis relative to the mirror body 1. At least a portion of the wind deflection adjusting pin 3421 is threadedly connected to at least a portion of the wind deflection sliding member 341. Specifically, the wind deflection adjusting pin 3421 refers to a component with a certain length. The wind deflection adjusting pin 3421 can be columnar or rod-shaped, etc. For ease of rotation, the cross-section of the wind deflection adjusting pin 3421 can be circular. The wind deflection adjusting pin 3421 can be threaded by having a receiving hole on itself, inserting at least a portion of the wind deflection sliding member 341 into the receiving hole, and achieving the threaded connection between the two by having threads on the outer wall of the portion of the wind deflection sliding member 341 inserted into the receiving hole and threads on the inner wall of the receiving hole. Alternatively, a receiving hole can be provided on the wind deflection slider 341, and the wind deflection adjusting pin 3421 can be inserted into the receiving hole. The two are threadedly connected by providing threads on both the outer wall of the wind deflection adjusting pin 3421 and the inner wall of the receiving hole. When it is necessary to adjust the position of the wind deflection slider 341, simply rotate the wind deflection adjusting pin 3421 around its own axis to drive the wind deflection slider 341 to move along the axial direction of the wind deflection adjusting pin 3421, making the position adjustment of the wind deflection slider 341 more convenient, and thus making the position adjustment of the mounting base 32 and the light source 31 more convenient.
[0100] It should be noted that the side wall 12 is provided with an installation space for mounting the wind deflection adjustment pin 3421. At least a portion of the wind deflection adjustment pin 3421 can be located outside the mirror body 1 to facilitate rotation of the wind deflection adjustment pin 3421. A wind deflection adjustment pin 3421 sleeve can also be provided within the installation space. The wind deflection adjustment pin 3421 sleeve is fixedly installed within the installation space, and the wind deflection adjustment pin 3421 passes through the wind deflection adjustment pin 3421 sleeve. The wind deflection adjustment pin 3421 sleeve only has the degree of freedom to rotate around its own axis relative to the wind deflection adjustment pin 3421 sleeve. The installation of the wind deflection adjustment pin 3421 sleeve makes its installation more stable and precise, thereby allowing for more accurate adjustment of the wind deflection drive unit 342.
[0101] In one embodiment, referring to Figures 8 and 12, the second return assembly 343 includes a second spring 3431, a second return member 3432, and a return fixing member 3433. A second return hole for accommodating the second return member 3432 is also provided on the mirror body 1. The first end of the second return hole communicates with the accommodating space of the mounting base 32, and the second end of the second return hole communicates with the outside of the mirror body 1. During installation, the second return member 3432 can be installed into the second return hole from the second end, with one end of the second return member 3432 abutting against the side of the mounting base 32. Then, the return fixing member 3433 is sealed to the second end of the second return hole, and the second spring 3431 is positioned between the return fixing member 3433 and the second return member 3432. The second return assembly 343 adopts the above structure and mates with the second return hole, making the installation of the second return assembly 343 more convenient.
[0102] In an optional embodiment, referring to Figures 8 and 12, a wind deflection hole for mounting a wind deflection adjustment pin 3421 is provided on the scope body 1. A sealing ring 10 can also be provided between the wind deflection adjustment pin 3421 and the inner wall of the wind deflection hole. The sealing ring 10 is fitted around the outer periphery of the wind deflection adjustment pin 3421 and abuts against the inner wall of the wind deflection hole. This can maintain the sealing of the wind deflection adjustment pin 3421 while it rotates, preventing foreign objects from entering the installation space through the gap between the wind deflection adjustment pin 3421 and the scope body 1, thus making the use of the entire scope safer.
[0103] In one embodiment, referring to Figure 10, the dot sight further includes a second lens 6, which is spaced apart from the first lens 2 along the length of the optical channel 13. Specifically, the second lens 6 is a transparent component with a certain thickness, and can be made of glass, acrylic, or other materials with good light transmittance. By placing the second lens 6 within the optical channel 13, and by spacing it apart from the first lens 2 along the length of the optical channel 13, the first lens 2 can be protected, preventing rainwater or stains from affecting its use.
[0104] In one embodiment, referring to Figure 10, the periphery of the first lens 2 is sealed to the scope body 1, and the periphery of the second lens 6 is also sealed to the scope body 1. The first lens 2, the second lens 6, and the inner wall surface of at least a portion of the optical channel 13 form a sealed cavity. Specifically, the periphery of the first lens 2 is sealed to the scope body 1, and the periphery of the second lens 6 is also sealed to the scope body 1. Furthermore, the first lens 2, the second lens 6, and the inner wall surface of at least a portion of the optical channel 13 form a sealed cavity. When the scope is in use, nitrogen or other inert gases can be filled into the sealed cavity to prevent moisture from entering the space and causing the first lens 2 to fog up, thereby improving shooting accuracy.
[0105] In one embodiment, referring to Figure 10, the connecting base plate 9 has a threaded hole 93 for engaging with the fastener 101. The threaded hole 93 is located on the side of the second lens 6 facing away from the first lens 2 and is spaced apart from the second lens 6. The minimum distance between the inner wall of the threaded hole 93 and the side of the second lens 6 facing away from the first lens 2 is 2mm to 5mm. Specifically, during the use of the scope, the light source mechanism 3 is usually located in the top area of the scope body 1 near the eye. The light emitted by the light source mechanism 3 passes through the optical channel above the scope body and is directed at an angle towards the first lens 2. After being reflected by the first lens 2, the light passes through the second lens 6 and enters the human eye. Through existing assembly tests, it is ensured that the second lens 6 does not obstruct the upper optical channel. The position of the fastener 101 connecting the scope body 1 and the connecting base plate 9 should be as close as possible to the second lens 6 to ensure a more balanced force between the scope body 1 and the connecting base plate 9. In this embodiment, by setting the minimum distance between the inner wall of the threaded hole 93 and the side of the second lens 6 away from the first lens 2 to 2mm to 5mm, it is possible to ensure the balance of force between the lens body 1 and the connecting base plate 9, as well as the strength of the connecting base plate 9 and the lens body 1, making the installation of the lens body 1 more secure.
[0106] In one embodiment, referring to Figures 16 to 21, a power receiving component 7 is also provided on the side wall 12. The power receiving component 7 is electrically connected to the battery mechanism 4 and is used to receive electrical energy output from the wireless power supply terminal to charge the battery mechanism 4. Specifically, the power receiving component 7 refers to a component that can receive electrical energy output from the wireless power supply terminal, and the power receiving component 7 can be an induction coil, etc. By providing a power receiving component 7 on the scope body 1 and using wireless charging, the power receiving component 7 on the scope acts as a power receiving device, and the portable wireless charging device acts as a power transmitting device. When the power receiving component 7 of the scope is attached to the charging surface of the power transmitting device, the power receiving component 7 in the charging assembly receives the electrical energy transmitted by the power transmitting device and transmits the electrical energy to the battery mechanism 4 to achieve charging, thereby maintaining the normal power supply in the scope.
[0107] In an optional embodiment, referring to Figures 16 to 21, the power receiving component 7 may be disposed on one side portion 122 of the sidewall 12, and the battery mechanism 4 may be disposed on the top portion 121 of the sidewall 12 or on the other side portion 122 of the sidewall 12.
[0108] In one embodiment, referring to Figures 16 to 21, a button assembly 8 is also provided on the side wall 12 of the mirror body 1. The button assembly 8 is used to adjust the brightness of the light source 31. Referring to Figure 22, the button assembly 8 can be located on the top surface 121 of the side wall 12, while the battery mechanism 4 can be located on the side surface 122 of the side wall 12. Referring to Figure 21, the button assembly 8 can be located on the side surface 122 of the side wall 12, while the battery mechanism 4 can be located on the top surface 121 of the side wall 12, making the overall external structural arrangement of the mirror body 1 more rational. It should be noted that, referring to Figure 21, when the power receiving assembly 7, the button assembly 8, and the battery mechanism 4 are all present, the battery mechanism 4 can be located on the top surface 121 of the side wall 12, and the button assembly 8 and the power receiving assembly 7 can be respectively located on the two side surface 122 of the side wall 12, making the structural layout of the mirror body 1 more rational.
[0109] In one embodiment, referring to Figure 7, a connecting structure is also provided on the side of the connecting base plate 9 that contacts the scope body 1. Simultaneously, a connecting hole 17 that mates with the connecting structure is provided on the bottom 11. The connecting structure can be a column or a block, etc. When the scope body 1 and the connecting base plate 9 are fixed together, the connecting structure can be inserted into the connecting hole 17 on the side wall 12, making the installation between the scope body 1 and the connecting base plate 9 more secure. The insertion of the connecting column 91 and the connecting hole 17 can also serve a positioning function, ensuring the accurate position of the bottom 11 on the connecting base plate 9 and the accurate position of the aiming scope. In one embodiment, referring to Figure 23, the connecting structure includes a connecting column 91, and the bottom 11 of the scope body 1 is provided with a connecting hole 17 for mates with the connecting column 91. The number of connecting columns 91 is at least two, and the number of connecting holes 17 matches the number of connecting columns 91. The connecting base plate 9 is provided with at least two threaded holes 93 for connecting with the scope body 1. Specifically, the connecting column 91 refers to a columnar component with a certain height dimension, and the cross-section of the connecting column 91 is usually circular. The connecting post 91 can be integrally formed with the connecting base plate 9. The threaded hole 93 refers to a hole structure with a certain depth and a threaded structure on the inner wall. Furthermore, there are at least two connecting posts 91. The two connecting posts 91 can be evenly distributed in the region near the first end of the connecting base plate 9, or evenly distributed in the region near the second end of the connecting base plate 9, or one can be located in the region near the first end of the connecting base plate 9 and the other in the region near the second end of the connecting base plate 9. This arrangement can be freely configured according to design requirements, thereby making the connection between the mirror body 1 and the connecting base plate 9 more convenient and secure.
[0110] In one embodiment, referring to 24, the joining structure includes joining posts 91, and the bottom 11 of the mirror body 1 is provided with joining holes 17 for engaging with the joining posts 91. There are at least two joining posts 91, and the number of joining holes 17 matches the number of joining posts 91. A threaded hole 93 for connecting to the mirror body 1 is provided on the connecting base plate 9. The joining post 91 refers to a columnar component with a certain height dimension, and the cross-section of the joining post 91 is usually circular. The joining post 91 can be integrally formed with the connecting base plate 9. The threaded hole 93 refers to a hole structure with a certain depth and a threaded structure on its inner wall. Furthermore, there are at least two joining posts 91. The two joining posts 91 can be evenly distributed in the region near the first end of the connecting base plate 9, or evenly distributed in the region near the second end of the connecting base plate 9, or one can be located in the region near the first end of the connecting base plate 9 and the other in the region near the second end of the connecting base plate 9. The arrangement can be freely configured according to design requirements.
[0111] In one embodiment, referring to 25, the joining structure includes a joining block 92. The bottom 11 of the mirror body 1 is provided with a joining groove for engaging with the joining block 92, and the connecting base plate 9 is provided with at least two threaded holes 93 for connecting with the mirror body. Specifically, the joining block 92 refers to a block-shaped component with a certain height. The shape of the joining block 92 is not limited here and can be set according to the actual situation. The joining block 92 can be integrally formed with the connecting base plate 9. The two joining blocks 92 can be distributed in the area near the first end of the connecting base plate 9, or they can be distributed in the area near the second end of the connecting base plate 9, which can be freely set according to design requirements.
[0112] In one embodiment, referring to 26, the joining structure includes a joining block 92. The bottom 11 of the mirror body 1 is provided with a joining groove for engaging with the joining block 92, and the connecting base plate 9 is provided with a threaded hole 93 for connecting with the mirror body. The joining block 92 refers to a block-shaped component with a certain height. The shape of the joining block 92 is not limited here and can be set according to the actual situation. The joining block 92 can be integrally formed with the connecting base plate 9. The two joining blocks 92 can be distributed in the area near the first end of the connecting base plate 9, or they can be distributed in the area near the second end of the connecting base plate 9, and can be freely set according to design requirements.
[0113] The above are merely preferred embodiments of the present invention, and only specifically describe the technical principles of the present invention. These descriptions are only for explaining the principles of the present invention and should not be construed as limiting the scope of protection of the present invention in any way. Based on this explanation, any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention, as well as other specific embodiments of the present invention that can be conceived by those skilled in the art without creative effort, should be included within the scope of protection of the present invention.
Claims
1. A dot sight, characterized in that, The scope includes a scope body, a first lens, a light source mechanism, and a battery mechanism. The scope body has a bottom and a side wall, which together form an optical channel. The first lens is disposed within the optical channel. The light source mechanism is disposed on the side wall and is used to emit light to the first lens to provide an aiming reference for the user. The battery mechanism is disposed on the side wall and is used to electrically connect with the light source mechanism to supply power to it. The bottom of the scope body is connected to the gun body by fasteners. The thickness of the bottom is less than or equal to 2.5 mm. After the scope body is installed, the user can observe the front sight through the rear sight and the optical channel.
2. The dot sight as described in claim 1, characterized in that, A connecting base plate is provided between the bottom of the scope and the gun body. The connecting base plate is connected to the gun body by fasteners. The bottom of the scope is connected to the connecting base plate and the gun body by fasteners.
3. The dot sight as described in claim 1 or 2, characterized in that, The fastener is fixed by a fastening tool, and the side wall is provided with a avoidance structure to avoid the fastening tool.
4. The dot sight as described in claim 3, characterized in that, The sidewall includes a top surface portion and a side surface portion. The top surface portion is opposite to and spaced apart from the bottom surface portion. The side surface portion is connected between the top surface portion and the bottom surface portion. The clearance structure includes a first clearance hole provided on the top surface portion. The position of the first clearance hole corresponds to the position of the fastener.
5. The dot sight as described in claim 4, characterized in that, The avoidance structure further includes a second avoidance hole, and the second avoidance hole is provided on the side portion of the side wall.
6. The dot sight as described in claim 5, characterized in that, A sealing element is also provided at the first clearance hole, which is used to block the first clearance hole when the mirror body is working.
7. The dot sight as described in claim 6, characterized in that, A drainage hole is provided on the bottom, which is used to drain the water accumulated in the optical channel to the outside of the lens body.
8. The dot sight as described in claim 3, characterized in that, The sidewall includes a top surface portion and a side surface portion. The top surface portion is opposite to and spaced apart from the bottom surface portion. The side surface portion is connected between the top surface portion and the bottom surface portion. The clearance structure includes a second clearance hole provided on the side surface portion, and the position of the second clearance hole matches the position of the fastener.
9. The dot sight as described in claim 1 or 2, characterized in that, The light source mechanism includes a light source, a mounting base, a ballistic adjustment mechanism, and a wind deflection adjustment mechanism. The mounting base is movably mounted on the mirror body. The light source is mounted on the mounting base. The ballistic adjustment mechanism is mounted on the mirror body. The ballistic adjustment mechanism is used to adjust the position of the mounting base along a first direction. The wind deflection adjustment mechanism is mounted on the mirror body. The wind deflection adjustment mechanism is used to adjust the position of the mounting base along a second direction. The first direction and the second direction are set at an angle.
10. The dot sight as described in claim 9, characterized in that, The ballistic adjustment mechanism includes a ballistic slider, a ballistic drive unit, and a first return assembly. The ballistic slider is slidably disposed on the scope body, and at least a portion of the ballistic slider abuts against the mounting base. The ballistic drive unit is disposed on the scope body and is used to drive the ballistic slider to move along the first direction. The first return assembly is disposed between the scope body and the mounting base and is used to apply a force toward the ballistic slider to the mounting base so that the mounting base and the ballistic slider remain in contact.
11. The dot sight as described in claim 10, characterized in that, The ballistic drive unit includes a ballistic adjustment pin, which is rotatably mounted on the mirror body. The axis of the ballistic adjustment pin is arranged along the first direction, and the ballistic adjustment pin has a degree of freedom to rotate about its own axis relative to the mirror body. At least a portion of the ballistic adjustment pin is threadedly connected to at least a portion of the ballistic slider.
12. The dot sight as described in claim 9, characterized in that, The wind deflection adjustment mechanism includes a wind deflection slider, a wind deflection drive unit, and a second return assembly. The wind deflection slider is slidably disposed on the mirror body, and the wind deflection drive unit is disposed on the mirror body. The wind deflection drive unit is used to drive the wind deflection slider to move along the second direction. The second return assembly is disposed between the mirror body and the mounting base. The wind deflection slider and the second return assembly respectively abut against the mounting base on both sides along the second direction. The second return assembly is used to apply a force to the mounting base toward the wind deflection slider.
13. The dot sight as described in claim 12, characterized in that, The wind deflection drive unit includes a wind deflection adjustment pin, which is rotatably disposed on the mirror body. The axis of the wind deflection adjustment pin is arranged along the second direction. The wind deflection adjustment pin has a degree of freedom to rotate about its own axis relative to the mirror body. At least a portion of the wind deflection adjustment pin is threadedly connected to at least a portion of the wind deflection slider.
14. The dot sight as described in claim 2, characterized in that, The dot sight further includes a second lens, which is spaced apart from the first lens along the length of the optical channel.
15. The dot sight as described in claim 14, characterized in that, The periphery of the first lens is sealed to the mirror body, and the periphery of the second lens is also sealed to the mirror body. The first lens, the second lens, and at least a portion of the inner wall surface of the optical channel form a sealed cavity.
16. The dot sight as described in claim 14, characterized in that, The connecting base plate has a threaded hole for engaging with the fastener. The threaded hole is located on the side of the second lens away from the first lens and is spaced apart from the second lens. The minimum distance between the inner wall of the threaded hole and the side of the second lens away from the first lens is 2mm to 5mm.
17. The dot sight as described in claim 1 or 2, characterized in that, A power receiving component is also provided on the side wall. The power receiving component is electrically connected to the battery mechanism and is used to receive electrical energy output from the wireless power supply terminal to charge the battery mechanism.
18. The dot sight as described in claim 2, characterized in that, The connecting base plate is provided with a joining structure, which is used to position the mirror body on the connecting base plate.
19. The dot sight as described in claim 18, characterized in that, The joining structure includes joining posts, and the bottom of the lens body is provided with joining holes for engaging with the joining posts. The number of joining posts is at least two, and the number of joining holes matches the number of joining posts. The connecting base plate is provided with at least two threaded holes for connecting with the lens body. Alternatively, the joining structure includes a joining post, and the bottom of the lens body is provided with a joining hole for engaging with the joining post. The number of joining posts is at least two, the number of joining holes matches the number of joining posts, and the connecting base plate is provided with a threaded hole for connecting with the lens body. Alternatively, the joining structure includes a joining block, the bottom of the lens body is provided with a joining groove for engaging with the joining block, and the connecting base plate is provided with at least two threaded holes for connecting with the lens body; Alternatively, the joining structure includes a joining block, the bottom of the lens body is provided with a joining groove for engaging with the joining block, and the connecting base plate is provided with a threaded hole for connecting with the lens body.