CN114322658A - Sighting telescope - Google Patents

Abstract

The invention discloses a sighting telescope, and belongs to the technical field of sighting telescopes. The sighting telescope comprises a body assembly, a ballistic adjusting assembly and a windage yaw adjusting assembly. The body assembly comprises a mirror body, a support and a laser range finder, and the laser range finder is located on the mirror body. The ballistic adjusting assembly includes a ballistic adjusting knob rotatably disposed on one end of the mirror body and a ballistic adjusting screw having one end fixed to the mount. The windage yaw adjusting assembly comprises a windage yaw adjusting knob and a windage yaw adjusting screw, the windage yaw adjusting knob is coaxially sleeved on one end of the windage yaw adjusting screw, the windage yaw adjusting screw horizontally penetrates through the support and is in threaded fit with the support, and the other end of the windage yaw adjusting screw is rotatably inserted into the other end of the mirror body. The sighting telescope provided by the invention not only can realize correction of the trajectory and windage yaw of the sighting telescope, but also can avoid the problem that the optical axis of the sighting telescope and the optical axis of the laser range finder form an included angle in the correction process.

Description

Sighting telescope

Technical Field

The invention belongs to the technical field of sighting telescope, and particularly relates to a sighting telescope.

Background

The lens body of an optical sighting telescope is provided with at least three optical lens groups, namely an objective lens group, a correcting lens group and an eyepiece lens group. The objective lens group is responsible for collecting light, when the objective lens group is bigger, the scenery in the sighting telescope is brighter, and the eyepiece lens group is responsible for changing the light rays into parallel light rays so that the eyes can focus, and the maximum visual field is created; the correcting lens group corrects the image of the objective lens from upside down and left and right opposite to correct the image to the correct direction and is responsible for adjusting the multiplying power.

However, when the existing sighting telescope adjusts the left position, the right position, and the height position of the telescope body, the optical axis of the telescope body (i.e. the optical axis of the correction lens group) and the position of the laser range finder are also changed, so that an included angle is generated between the optical axis of the telescope body and the optical axis of the laser range finder, and the laser range finder needs to be adjusted repeatedly to be parallel to the optical axis of the telescope body, so as to prevent the result obtained by the laser range finder from being incapable of reflecting a real distance value.

Disclosure of Invention

Aiming at the defects or the improvement requirements of the prior art, the invention provides the sighting telescope, which aims to realize convenient correction of the trajectory and the windage yaw of the sighting telescope and avoid the problem that the optical axis of the sighting telescope and the optical axis of the laser range finder form an included angle in the correction process.

The invention provides a sighting telescope, which comprises a body assembly, a trajectory adjusting assembly and an air deflection adjusting assembly, wherein the body assembly is provided with a body;

the body assembly comprises a mirror body, a support and a laser range finder, wherein the mirror body is positioned above the support, and the laser range finder is positioned on the mirror body;

the ballistic adjusting assembly comprises a ballistic adjusting knob and a ballistic adjusting screw, the ballistic adjusting knob is rotatably arranged on one end of the mirror body, one end of the ballistic adjusting screw is vertically fixed on the support, and the other end of the ballistic adjusting screw is coaxially inserted into the ballistic adjusting knob and is in threaded fit with the ballistic adjusting knob;

the windage yaw adjusting assembly comprises a windage yaw adjusting knob and a windage yaw adjusting screw, the windage yaw adjusting knob is coaxially sleeved on one end of the windage yaw adjusting screw, the windage yaw adjusting screw horizontally penetrates through the support and is in threaded fit with the support, and the other end of the windage yaw adjusting screw is rotatably inserted into the other end of the mirror body.

Optionally, a first connecting screw is inserted into the support, and the first connecting screw is fixedly connected with one end of the ballistic adjusting screw.

Optionally, the endoscope body is provided with a ballistic adjusting support, a snap ring is inserted into the ballistic adjusting support, and one side of the ballistic adjusting knob is provided with a boss which is rotatably and coaxially inserted into the snap ring.

Optionally, the ballistic adjusting support is provided with a limiting member, the limiting member includes a spring and a ball, two ends of the spring are respectively connected to the ballistic adjusting support and the ball, the extension direction of the spring is parallel to the axis of the ballistic adjusting screw, one side of the ballistic adjusting knob facing the ballistic adjusting support is provided with a plurality of counter bores arranged at intervals, and the plurality of counter bores are arranged in a circular shape to accommodate the ball.

Optionally, the number of the counter bores is 60.

Optionally, the windage yaw adjusting assembly further includes a second connecting screw, and the second connecting screw is coaxially inserted into the windage yaw adjusting knob and the windage yaw adjusting screw to connect the windage yaw adjusting knob and the windage yaw adjusting screw.

Optionally, a connecting shaft is inserted into the support, a threaded hole is formed in the connecting shaft, and the windage yaw adjusting screw is coaxially inserted into the threaded hole.

Optionally, the lens body includes a lens barrel, an objective lens group, a correction lens group and an eyepiece lens group, the lens barrel is located above the support, the ballistic adjusting knob is rotatably arranged at one end of the lens barrel, the other end of the windage yaw adjusting screw is rotatably inserted into the other end of the lens barrel, and the objective lens group, the correction lens group and the eyepiece lens group are sequentially inserted into the lens barrel at intervals.

Optionally, the body assembly further comprises a connecting spring, one end of the connecting spring is connected with the mirror body, and the other end of the connecting spring is connected with the support.

Optionally, a liquid crystal display screen is inserted into the mirror body, and the laser range finder is electrically connected with the liquid crystal display screen.

The technical scheme provided by the embodiment of the invention has the following beneficial effects:

when the sighting telescope provided by the embodiment of the invention is used, the support is fixedly arranged on a target position needing to be aimed, such as a gun body. For ballistic conditioning: because the trajectory adjusting knob is rotationally arranged on the mirror body, one end of the trajectory adjusting screw is fixed on the support, and the other end of the trajectory adjusting screw is coaxially inserted into the trajectory adjusting knob and is in threaded fit with the trajectory adjusting knob, the trajectory adjusting knob can be screwed to lift the trajectory adjusting knob, so that the right side of the mirror body of the sighting telescope is driven to be adjusted upwards or downwards, namely the optical axis of the mirror body is adjusted upwards and downwards, and the trajectory is corrected. At this time, the sighting telescope can rotate by taking the windage yaw adjusting screw as a rotating shaft.

And for windage yaw adjustment: because windage yaw adjusting knob coaxial sleeve establishes on one end of windage yaw adjusting screw, windage yaw adjusting screw level run through the support and with support screw-thread fit, windage yaw adjusting screw's the other end rotationally the cartridge in the other end of mirror body, thereby can drive windage yaw adjusting screw to rotate through revolving windage yaw adjusting knob, then can convert windage yaw adjusting screw's rotary motion into windage yaw adjusting screw's linear motion (for the support) this moment, thereby make the mirror body left side of gun sight swing left or right side, realize the left and right adjustment of mirror body optical axis promptly, and then realize windage yaw's correction. At this time, the scope rotates about the trajectory adjusting screw.

Furthermore, the laser range finder is located the mirror body, when adjusting the mirror body optical axis (before adjusting, the optical axis of laser range finder position is parallel with the mirror body optical axis), can drive the optical axis of laser range finder position and move as a whole together. Therefore, when the optical axis of the mirror body is adjusted, the optical axis of the mirror body and the optical axis of the laser range finder cannot form an included angle, and therefore the result obtained by the laser range finder can reflect a real distance numerical value.

That is to say, the sighting telescope provided by the invention not only can realize convenient correction of the trajectory and windage yaw of the sighting telescope, but also can avoid the problem that the optical axis of the sighting telescope and the optical axis of the laser range finder form an included angle in the correction process.

Drawings

FIG. 1 is a schematic structural diagram of a sighting telescope provided by an embodiment of the invention;

FIG. 2 is a cross-sectional view of a scope provided by an embodiment of the present invention;

FIG. 3 is a sectional view taken along line A-A of a scope according to an embodiment of the present invention;

fig. 4 is a sectional view of a scope according to an embodiment of the present invention taken along line B-B.

The symbols in the drawings represent the following meanings:

1. a body assembly; 11. a mirror body; 111. a ballistic adjusting support; 1111. a snap ring; 1112. a spring; 1113. a ball bearing; 112. a lens barrel; 113. an objective lens group; 114. a correction lens group; 115. an eyepiece group; 116. a liquid crystal display screen; 12. a support; 121. a first connection screw; 122. a connecting shaft; 13. a laser range finder; 14. a connecting spring; 15. a battery pack; 2. a ballistic conditioning assembly; 21. a trajectory adjustment knob; 22. a ballistic adjusting screw; 3. a windage yaw adjustment assembly; 31. a windage yaw adjustment knob; 32. a windage yaw adjusting screw; 33. a second connection screw; 34. and a limiting screw.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. In addition, the technical features involved in the embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Fig. 1 is a schematic structural diagram of a sighting telescope provided by an embodiment of the invention, and as shown in fig. 1, the sighting telescope comprises a body assembly 1, a ballistic adjusting assembly 2 and a wind deflection adjusting assembly 3.

The body assembly 1 comprises a mirror body 11, a support 12 and a laser range finder 13, wherein the mirror body 11 is positioned above the support 12, and the laser range finder 13 is positioned on the mirror body 11.

Fig. 2 is a cross-sectional view of a sighting telescope according to an embodiment of the present invention, and as shown in fig. 2, the ballistic adjusting assembly 2 includes a ballistic adjusting knob 21 and a ballistic adjusting screw 22, the ballistic adjusting knob 21 is rotatably disposed at one end of the telescope body 11, one end of the ballistic adjusting screw 22 is vertically fixed on the support 12, and the other end of the ballistic adjusting screw 22 is coaxially inserted into the ballistic adjusting knob 21 and is in threaded engagement with the ballistic adjusting knob 21.

Fig. 3 is a sectional view of a sighting telescope along the direction a-a, as shown in fig. 3, the windage yaw adjusting assembly 3 includes a windage yaw adjusting knob 31 and a windage yaw adjusting screw 32, the windage yaw adjusting knob 31 is coaxially sleeved on one end of the windage yaw adjusting screw 32, the windage yaw adjusting screw 32 horizontally penetrates through the support 12 and is in threaded fit with the support 12, and the other end of the windage yaw adjusting screw 32 is rotatably inserted into the other end of the telescope body 11.

When the sighting telescope provided by the embodiment of the invention is used, the support 12 is fixedly arranged on a target position needing to be aimed, such as a gun body. For ballistic conditioning: because the ballistic adjusting knob 21 is rotatably arranged on the mirror body 11, one end of the ballistic adjusting screw 22 is fixed on the support 12, and the other end of the ballistic adjusting screw 22 is coaxially inserted into the ballistic adjusting knob 21 and is in threaded fit with the ballistic adjusting knob 21, the ballistic adjusting knob 21 can be lifted and lowered by screwing the ballistic adjusting knob 21, so that the right side of the mirror body 11 of the sighting telescope is driven to be adjusted upwards or downwards, namely, the optical axis of the mirror body 11 is adjusted upwards and downwards, and the ballistic correction is further realized. At this time, the left side of the mirror body 11 can rotate by using the windage yaw adjusting screw 32 as a rotating shaft.

And for windage yaw adjustment: because windage yaw adjusting knob 31 coaxial cover is established on one end of windage yaw adjusting screw 32, windage yaw adjusting screw 32 level runs through support 12 and with support 12 screw-thread fit, windage yaw adjusting screw 32's the other end rotationally cartridge in the other end of mirror body 11 to can drive windage yaw adjusting screw 32 and rotate through revolving windage yaw adjusting knob 31, then can convert the rotary motion of windage adjusting screw 32 into the rectilinear motion of windage adjusting screw 32 (for support 12) this moment, thereby make the mirror body 11 left side of gun sight swing left or right side, realize the left and right control of mirror body 11 optical axis promptly, and then realize the correction of windage yaw. At this time, the right side of the mirror body 11 is rotated about the trajectory adjusting screw 22.

Further, the laser range finder 13 is located on the mirror body 11, and when the optical axis of the mirror body 11 is adjusted (before adjustment, the optical axis of the laser range finder 13 is parallel to the optical axis of the mirror body 11), the optical axis of the laser range finder 13 is driven to move integrally together. Therefore, when the optical axis of the mirror body 11 is adjusted, the optical axis of the mirror body 11 and the optical axis of the laser range finder 13 do not form an included angle, so that the result obtained by the laser range finder 13 can reflect a real distance value.

That is to say, the sighting telescope provided by the invention not only can realize convenient correction of the trajectory and windage yaw of the sighting telescope, but also can avoid the problem that the optical axis of the sighting telescope and the optical axis of the laser range finder 13 form an included angle in the correction process.

It is easy to understand that, when trajectory correction is performed, the mirror body 11 rotates around the windage yaw adjusting screw 32; when wind deflection correction is carried out, the mirror body 11 rotates by taking the trajectory adjusting screw 22 as a shaft, so that the trajectory adjusting component 2 and the wind deflection adjusting component 3 can be matched with each other, and the structure is simpler.

Illustratively, the horizontal spacing of the ballistic adjustment screw 22 and the wind deflection adjustment screw 32 is 120 mm.

In this embodiment, after the windage yaw adjusting knob 31 is adjusted in place, the windage yaw adjusting knob 31 can be limited on the mirror body 11 by the limiting screw 34 and the elastic washer, so as to prevent the recoil generated by shooting from causing the windage yaw adjusting knob 31 to rotate accidentally.

Referring again to fig. 2, a first connection screw 121 is inserted into the support 12, and the first connection screw 121 is fixedly connected to one end of the ballistic adjustment screw 22.

In the above embodiment, the first connection screw 121 functions to mount the ballistic adjusting screw 22.

In this embodiment, the endoscope body 11 has a trajectory adjusting seat 111, a snap ring 1111 is inserted into the trajectory adjusting seat 111, and a boss is provided on one side of the trajectory adjusting knob 21 and is rotatably and coaxially inserted into the snap ring 1111.

In the above embodiment, the installation of the ballistic adjusting knob 21 is achieved by the ballistic adjusting mount 111 and the snap ring 1111, facilitating the rotation of the ballistic adjusting knob 21.

Illustratively, the inner peripheral wall of the snap ring 1111 is sleeved in a groove of the outer peripheral wall of the boss, and an elastic washer is inserted in the groove.

In addition, the ballistic adjusting support 111 has a limiting member, the limiting member includes a spring 1112 and a ball 1113, two ends of the spring 1112 are respectively connected to the ballistic adjusting support 111 and the ball 1113, and a telescopic direction of the spring 1112 is parallel to an axis of the ballistic adjusting screw 22, one side of the ballistic adjusting knob 21 facing the ballistic adjusting support 111 has a plurality of counter bores arranged at intervals, and the plurality of counter bores are arranged in a circular shape to accommodate the ball 1113.

In the above embodiment, the control of the rotation of the ballistic adjusting knob 21 is achieved by the cooperation of the ball 1113 and the counterbore.

Illustratively, the number of the counter bores is 60, that is, the ballistic adjusting knob 21 has 60 steps, and the adjusting amount of each step is about 0.5 minutes, that is, the angle of the mirror body 11 swinging up and down is about 0.5 minutes per 1 step of screwing.

Referring to fig. 3 again, the windage yaw adjusting assembly 3 further includes a second connecting screw 33, and the second connecting screw 33 is coaxially inserted into the windage yaw adjusting knob 31 and the windage adjusting screw 32, so that the windage yaw adjusting knob 31 and the windage adjusting screw 32 can be conveniently connected.

Similarly, the windage yaw adjusting knob 31 has a spring and a ball, and the mirror body 11 has a plurality of counter bores, so that the windage yaw adjusting knob 31 can be controlled similarly.

Illustratively, the counter bores on the mirror body 11 are also 60, that is, the windage yaw adjusting knob 31 has 60 steps in total, and the adjustment amount of each step is about 0.5 minutes, that is, the angle of the mirror body 11 swinging left and right is about 0.5 minutes per 1 step of screwing.

In this embodiment, a connecting shaft 122 is inserted into the support 12, a threaded hole is formed in the connecting shaft 122, and the windage yaw adjusting screw 32 is coaxially inserted into the threaded hole, so that the connecting shaft 122 plays a role in driving the windage yaw adjusting screw 32 and the support 12, and the rotary motion of the windage yaw adjusting screw 32 can be converted into the linear motion relative to the support 12.

Referring to fig. 1 again, the lens body 11 includes a lens barrel 112, an objective lens group 113, a correcting lens group 114 and an eyepiece lens group 115, the lens barrel 112 is located above the support 12, the ballistic adjusting knob 21 is rotatably disposed on one end of the lens barrel 112, the other end of the windage yaw adjusting screw 32 is rotatably inserted into the other end of the lens barrel 112, and the objective lens group 113, the correcting lens group 114 and the eyepiece lens group 115 are sequentially inserted into the lens barrel 112 at intervals.

In the above embodiment, the lens barrel 112 protects the objective lens group 113, the correcting lens group 114, and the eyepiece lens group 115.

Illustratively, the correcting lens group 114 may include a focusing lens group, a field lens group, a front image rotating lens group and a rear image rotating lens group.

In this embodiment, the body assembly 1 further includes a connecting spring 14, one end of the connecting spring 14 is connected to the mirror body 11, and the other end of the connecting spring 14 is connected to the support 12.

In the above embodiment, the connection spring 14 can eliminate the clearance of the screw fit between the lens body 11 and the support 12, and can play a role of buffering and damping.

Illustratively, the number of the connecting springs 14 is 2, and the 2 connecting springs 14 are arranged at intervals.

Illustratively, a liquid crystal display 116 is inserted into the mirror body 11, and the laser distance measuring instrument 13 is electrically connected with the liquid crystal display 116, so that the distance value measured by the laser distance measuring instrument 13 can be displayed on the liquid crystal display 116.

Fig. 4 is a B-B cross-sectional view of a sighting telescope according to an embodiment of the present invention, and as shown in fig. 4, the laser range finder 13 is located on the left side of the telescope 11, and the right side of the telescope 11 is provided with a battery pack 15 for supplying power to the laser range finder 13 and the lcd 116.

It will be understood by those skilled in the art that the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the invention, and that any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. Sighting telescope, characterized in that it comprises a body assembly (1), a ballistic adjustment assembly (2) and a wind-yaw adjustment assembly (3);

the body assembly (1) comprises a mirror body (11), a support (12) and a laser range finder (13), wherein the mirror body (11) is positioned above the support (12), and the laser range finder (13) is positioned on the mirror body (11);

the ballistic adjusting assembly (2) comprises a ballistic adjusting knob (21) and a ballistic adjusting screw (22), wherein the ballistic adjusting knob (21) is rotatably arranged on one end of the mirror body (11), one end of the ballistic adjusting screw (22) is vertically fixed on the support (12), and the other end of the ballistic adjusting screw (22) is coaxially inserted into the ballistic adjusting knob (21) and is in threaded fit with the ballistic adjusting knob (21);

windage yaw adjusting part (3) are including windage yaw adjust knob (31) and windage yaw adjusting screw (32), windage yaw adjust knob (31) coaxial cover is established one of windage yaw adjusting screw (32) is served, windage yaw adjusting screw (32) level runs through support (12), and with support (12) screw-thread fit, the other end of windage yaw adjusting screw (32) rotationally the cartridge is in the other end of mirror body (11).

2. Sighting telescope according to claim 1, characterised in that a first connecting screw (121) is inserted into the support (12), the first connecting screw (121) being fixedly connected to one end of the ballistic adjusting screw (22).

3. The sight of claim 1, wherein the body (11) has a ballistic adjusting mount (111), a snap ring (1111) is inserted into the ballistic adjusting mount (111), and a boss is provided on one side of the ballistic adjusting knob (21), and the boss is rotatably and coaxially inserted into the snap ring (1111).

4. A sighting telescope according to claim 3, characterised in that the ballistic adjusting support (111) has a stop element comprising a spring (1112) and a ball (1113), the spring (1112) is connected at its two ends to the ballistic adjusting support (111) and the ball (1113), respectively, and the spring (1112) has a direction of extension parallel to the axis of the ballistic adjusting screw (22), and the ballistic adjusting knob (21) has a plurality of spaced-apart counter bores on the side facing the ballistic adjusting support (111), the counter bores being arranged in a circular shape to receive the ball (1113).

5. The sight of claim 4, wherein the number of counter bores is 60.

6. A sighting telescope according to claim 1, wherein the windage yaw adjusting assembly (3) further comprises a second connecting screw (33), and the second connecting screw (33) is coaxially inserted into the windage yaw adjusting knob (31) and the windage yaw adjusting screw (32) to connect the windage adjusting knob (31) and the windage adjusting screw (32).

7. A sighting telescope according to claim 1, characterised in that a connecting shaft (122) is inserted into the support (12), the connecting shaft (122) having a threaded bore therein, and the windage yaw adjustment screw (32) being coaxially inserted into the threaded bore.

8. A sighting telescope according to any one of claims 1 to 7, characterized in that the telescope body (11) comprises a lens barrel (112), an objective lens group (113), a correction lens group (114) and an eyepiece lens group (115), the lens barrel (112) is located above the support (12), the ballistic adjusting knob (21) is rotatably arranged at one end of the lens barrel (112), the other end of the windage yaw adjusting screw (32) is rotatably inserted into the other end of the lens barrel (112), and the objective lens group (113), the correction lens group (114) and the eyepiece lens group (115) are sequentially inserted into the lens barrel (112) at intervals.

9. A sighting telescope according to any one of claims 1-7, characterised in that the body assembly (1) further comprises a connecting spring (14), one end of the connecting spring (14) being connected to the scope body (11) and the other end of the connecting spring (14) being connected to the abutment (12).

10. A sighting telescope according to any one of claims 1-7, characterised in that a liquid crystal display (116) is inserted in the mirror body (11), and the laser distance measuring device (13) is electrically connected to the liquid crystal display (116).

Images