CN112378292A

CN112378292A - Sighting telescope mounting base

Info

Publication number: CN112378292A
Application number: CN202011056733.9A
Authority: CN
Inventors: 陈蔡朋; 黄立; 徐峰; 刘蒙; 李永涛; 张前进
Original assignee: Wuhan Guide Infrared Co Ltd
Current assignee: WUHAN GUIDE SENSMART TECH Co.,Ltd.
Priority date: 2020-09-30
Filing date: 2020-09-30
Publication date: 2021-02-19
Also published as: WO2022068843A1

Abstract

The invention provides a sighting telescope mounting seat which is used for mounting a sighting telescope in one of a pickup truck and a dovetail, and comprises an upper bracket, a lower bracket and a guide rod spring assembly, wherein the upper bracket is used for being fixedly connected with the sighting telescope, the lower bracket is used for being fixedly connected with one of the pickup truck and the dovetail, the guide rod spring assembly is connected with the upper bracket and the lower bracket, and the guide rod spring assembly has elasticity. Because the guide rod spring assembly has elasticity, when the lower support is impacted, the guide rod spring assembly can be used for buffering, the upper support and the sighting telescope fixedly connected with the upper support are prevented from being impacted, and therefore the reliability of the sighting telescope is improved.

Description

Sighting telescope mounting base

Technical Field

The invention relates to the technical field of sighting telescope, in particular to a sighting telescope mounting base.

Background

The scope, or optical sighting device, is typically attached to the pick-up or dovetail block of the gun by a rigid scope mount or a near-parallelogram scope mount. Under the condition that the sighting telescope is connected to a pickup or a dovetail seat of the gun through the rigid sighting telescope mounting seat, strong impact generated when the gun shoots directly acts on the sighting telescope; in the case where the scope is attached to a pickup or a dovetail base of the gun through the approximately parallelogram-shaped scope mount, the approximately parallelogram-shaped scope mount can reduce a small part of the impact when the gun is fired. Under the two conditions, the sighting telescope can bear great impact, and particularly for the infrared sighting telescope, a core device infrared detector is easy to be punched out of a dead point and even damaged; meanwhile, the zero walking momentum of the sighting telescope is easy to exceed standard due to larger impact and ten thousands of times of shooting, and the sighting precision is influenced.

Therefore, there is a need for improvement of the existing sighting telescope mounting base to reduce the impact on the sighting telescope and improve the reliability of the sighting telescope.

Disclosure of Invention

The invention aims to provide a sighting telescope mounting base to solve the problems that the existing sighting telescope is high in impact and low in reliability.

In order to solve the technical problem, the invention provides a sighting telescope mounting base for mounting a sighting telescope in one of a pickup truck and a dovetail, the sighting telescope mounting base comprises an upper bracket, a lower bracket and a guide rod spring assembly, the upper bracket is used for being fixedly connected with the sighting telescope, the lower bracket is used for being fixedly connected with the pickup truck and the dovetail, the guide rod spring assembly is connected with the upper bracket and the lower bracket, and the guide rod spring assembly has elasticity.

Optionally, the guide rod spring assembly includes a guide rod and a spring, the upper bracket and the lower bracket are slidably connected through the guide rod, and the spring is sleeved on the guide rod and located between the upper bracket and the lower bracket.

Optionally, the upper bracket includes an upper bracket body and an upper sleeve connected to the upper bracket body, the lower bracket includes a lower bracket body and a lower sleeve connected to the lower bracket body, the upper sleeve, the lower sleeve and the spring are sleeved on the guide rod, the guide rod is axially fixed relative to the lower sleeve, the upper sleeve can axially reciprocate relative to the guide rod along the guide rod, and the spring is located between the upper sleeve and the lower sleeve.

Optionally, the number of the lower sleeves on one guide rod is three, the number of the upper sleeves on one guide rod is two, the number of the springs on one guide rod is two, the two upper sleeves are respectively arranged in two gaps formed by the three lower sleeves, the two springs are sequentially arranged in two gaps formed by the three lower sleeves, one of the springs is located on two sides of the guide rod, one of the lower sleeves is adjacent to one of the upper sleeves, and the other spring is located between the lower sleeve and the other upper sleeve.

Optionally, the number of the guide rods is two.

Optionally, the gun sight mount pad still includes the blotter, the blotter cover is established on the guide arm, one on the guide arm the quantity of blotter is two, go up the sleeve with form four clearances between the sleeve down, the spring with the blotter is crisscross to be set up four in the clearance.

Optionally, the sighting telescope mount further includes a bushing, and the bushing is disposed between the guide rod and the upper sleeve, and between the guide rod and the lower sleeve.

Optionally, the lower bracket body comprises a bracket main body, a fixing block, a pressing block and an adjusting assembly, the lower sleeve is fixedly connected with the bracket main body, one side of the bracket main body is fixedly connected with the fixing block, the other side of the bracket main body is detachably connected with the pressing block through the adjusting assembly, the fixing block, the bracket main body and the pressing block form a clamping groove, the clamping groove is used for clamping the pickup or the dovetail, and the adjusting assembly is used for adjusting the size of the clamping groove.

Optionally, the adjusting assembly comprises a screw and a locking nut, the screw is fixedly arranged on the support main body, the pressing block and the nut are sleeved on the screw, the pressing block is located between the support main body and the nut, and the screw is matched with the locking nut and used for adjusting the distance between the pressing block and the support main body.

Optionally, the lower bracket body further comprises a reset assembly, the reset assembly comprises a reset spring and an ejector rod, the bracket body is provided with a reset hole, one end of the reset spring and one end of the ejector rod are arranged in the reset hole, the reset spring is sleeved on the ejector rod, the ejector rod is used for compressing the reset spring, and the other end of the ejector rod is abutted against the pressing block under the action of the reset spring.

The sighting telescope mounting base provided by the invention has the following beneficial effects:

because the guide rod spring assembly has elasticity, when the lower support is impacted, the guide rod spring assembly can be used for buffering, the upper support and the sighting telescope fixedly connected with the upper support are prevented from being impacted, and therefore the reliability of the sighting telescope is improved.

Drawings

FIG. 1 is a schematic diagram of a sighting telescope mount according to an embodiment of the present invention;

FIG. 2 is a schematic view of another arrangement of a sighting telescope mount in an embodiment of the present invention;

FIG. 3 is a cross-sectional view of a front sight mount with an upper support moved relative to a lower support in an embodiment of the present invention;

FIG. 4 is a partial cross-sectional view of a scope mount in an embodiment of the invention;

FIG. 5 is another partial cross-sectional view of a scope mount in an embodiment of the present invention;

FIG. 6 is a cross-sectional view of a sighting telescope mount after movement of the upper support relative to the lower support in an embodiment of the present invention;

FIG. 7 is a schematic view of an embodiment of the present invention showing a scope mounted to a scope mount;

fig. 8 is a schematic structural diagram of the sighting telescope mounting base provided with the sighting telescope and the pickup truck in the embodiment of the invention.

Description of reference numerals:

100-an upper bracket; 110-an upper bracket body; 120-an upper sleeve; 121-a first upper sleeve; 122-a second upper sleeve; 130-pin;

200-lower support; 210-lower bracket body; 211-a stent body; 213-fixing block; 214-briquetting; 215-adjusting the component; 216-screw rod; 217-locking nut; 218-a return spring; 219-mandril; 220-lower sleeve; 221-a first lower sleeve; 222-a second lower sleeve; 223-a third lower sleeve; 230-a stop;

300-a guide rod spring assembly; 310-a guide rod; 320-a spring; 321-a first spring; 322-a second spring;

400-a cushion pad; 410-a first cushion; 420-a second cushion;

500-a liner;

600-pick up card;

700-sighting telescope.

Detailed Description

The scope mount according to the present invention will be described in further detail with reference to the accompanying drawings and specific embodiments. The advantages and features of the present invention will become more apparent from the following description. It is to be noted that the drawings are in a very simplified form and are not to precise scale, which is merely for the purpose of facilitating and distinctly claiming the embodiments of the present invention.

The present embodiments provide a scope mount for mounting a scope in one of a pickup and a dovetail. Referring to fig. 1, 2 and 3, fig. 1 is a schematic structural view of a scope mount according to an embodiment of the present invention, fig. 2 is another schematic structural view of a scope mount according to an embodiment of the present invention, fig. 3 is a cross-sectional view of a scope mount before an upper bracket 100 moves relative to a lower bracket 200 according to an embodiment of the present invention, the scope mount including an upper bracket 100, a lower bracket 200, and a guide bar spring assembly 300, the upper bracket 100 being for fixed connection with a scope 700, the lower bracket 200 being for fixed connection with one of a pickup 600 and a dovetail, the guide bar spring assembly 300 connecting the upper bracket 100 and the lower bracket 200, and the guide bar spring assembly 300 having elasticity.

Since the guide bar spring assembly 300 has elasticity, when the lower bracket 200 is impacted, the guide bar spring assembly 300 can buffer the impact, so that the impact on the upper bracket 100 and the sighting telescope 700 fixedly connected with the upper bracket 100 can be avoided, and the reliability of the sighting telescope 700 can be improved.

Referring to fig. 3, the guide rod spring assembly 300 includes a guide rod 310 and a spring 320, the upper bracket 100 and the lower bracket 200 are slidably connected through the guide rod 310, and the spring 320 is sleeved on the guide rod 310 and located between the upper bracket 100 and the lower bracket 200. Because the upper bracket 100 and the lower bracket 200 are slidably connected through the guide rod 310, the spring 320 is sleeved on the guide rod 310 and is located between the upper bracket 100 and the lower bracket 200, so that when the lower bracket 200 is impacted and slides relative to the upper bracket 100, the lower bracket 200 can press the spring 320, the impact force received by the spring 320 is transmitted to the upper bracket 100, and the impact received by the upper bracket 100 and the impact received by the sighting telescope 700 fixedly connected with the upper bracket 100 can be effectively buffered due to the action of the spring 320, thereby improving the reliability of the sighting telescope 700.

Specifically, the upper bracket 100 includes an upper bracket body 110 and an upper sleeve 120 connected to the upper bracket body 110. The lower bracket 200 includes a lower bracket body 210 and a lower sleeve 220 connected to the lower bracket body 210. The upper sleeve 120, the lower sleeve 220 and the spring 320 are sleeved on the guide rod 310, the guide rod 310 is axially fixed relative to the lower sleeve 220, the upper sleeve 120 can reciprocate relative to the guide rod 310 along the axial direction of the guide rod 310, and the spring 320 is located between the upper sleeve 120 and the lower sleeve 220.

As shown in fig. 3, the number of the lower sleeves 220 on one of the guide rods 310 is three, the number of the upper sleeves 120 on one of the guide rods 310 is two, and the number of the springs 320 on one of the guide rods 310 is two. The two upper sleeves 120 are respectively disposed in two gaps formed by the three lower sleeves 220. The two springs 320 are sequentially disposed in two gaps formed by the three lower sleeves 220, one spring 320 is located between one lower sleeve 220 and an adjacent upper sleeve 120 of the lower sleeves 220 at two sides of the guide rod 310, and the other spring 320 is located between the middle lower sleeve 220 and the other upper sleeve 120.

Referring to fig. 1 and 2, in the present embodiment, the number of the guide rods 310 is two, so that the stability of the scope mount can be improved.

Referring to fig. 3, the sighting telescope mounting base further comprises a buffer pad 400, and the buffer pad 400 is sleeved on the guide rod 310. The number of the buffer pads 400 on one guide bar 310 is two. Four gaps are formed between the upper sleeve 120 and the lower sleeve 220, and the springs 320 and the buffering pads 400 are alternately disposed in the four gaps. Wherein, the cushion 400 can prevent the upper bracket 100 and the lower bracket 200 from rigidly colliding.

Hereinafter, for convenience of description, the three lower sleeves 220 of fig. 3 are sequentially referred to as a first lower sleeve 221, a second lower sleeve 222 and a third lower sleeve 223 from left to right, the two upper sleeves 120 of fig. 3 are sequentially referred to as a first upper sleeve 121 and a second upper sleeve 122 from left to right, the two springs 320 of fig. 3 are sequentially referred to as a first spring 321 and a second spring 322 from left to right, and the two cushion pads 400 of fig. 3 are sequentially referred to as a first cushion 410 and a second cushion 420 from left to right. As shown in fig. 3, the first upper sleeve 121 is disposed in a gap formed by the first lower sleeve 221 and the second lower sleeve 222, and the second upper sleeve 122 is disposed in a gap formed by the second lower sleeve 222 and the third lower sleeve 223. The first spring 321 is disposed in a gap formed between the first lower sleeve 221 and the first upper sleeve 121, and the second spring 322 is disposed in a gap formed between the second lower sleeve 222 and the second upper sleeve 122. The first cushion 410 is disposed in the gap formed by the second lower sleeve 222 and the first upper sleeve 121, and the second cushion 420 is disposed in the gap formed by the third lower sleeve 223 and the second upper sleeve 122.

The cushion pad 400 may be made of rubber.

Referring to fig. 3, the scope mount further includes a bushing 500. The bushing 500 is disposed between the guide rod 310 and the upper sleeve 120, and between the guide rod 310 and the lower sleeve 220. The bushing 500 serves to reduce friction between the guide rod 310 and the upper sleeve 120, and between the guide rod 310 and the lower sleeve 220, to improve the lifespan of the scope mount.

The material of the bushing 500 is copper.

In this embodiment, the upper bracket body 110 and the upper sleeve 120 are integrally disposed, and the lower bracket body 210 and the lower sleeve 220 are integrally disposed. In other embodiments, the upper bracket body 110 is fixedly connected to the upper sleeve 120, and the lower bracket body 210 is fixedly connected to the lower sleeve 220, which is not limited in the present invention.

The upper bracket body 110 is provided with a mounting through hole, and a fastener penetrates through the mounting through hole to fixedly connect the sighting telescope 700 and the upper bracket body 110 together.

The upper bracket 100 further includes a pin 130, and the pin 130 is fixedly disposed on the upper bracket body 110. The sighting telescope 700 is provided with a pin hole which is in interference fit with the pin 130. Therefore, the shearing resistance of the sighting telescope mounting seat can be improved while the sighting telescope mounting seat is positioned.

Referring to fig. 4 and 5, fig. 4 is a partial sectional view of an scope mount according to an embodiment of the present invention, and fig. 5 is another partial sectional view of the scope mount according to an embodiment of the present invention, and the lower bracket body 210 includes a bracket main body 211, a fixing block 213, a pressing block 214, and an adjusting member 215. The lower sleeve 220 is fixedly connected with the bracket body 211. One side and fixed block 213 fixed connection of support main part 211, the opposite side and the briquetting 214 of support main part 211 pass through adjustment subassembly 215 can dismantle the connection, fixed block 213 the support main part 211 with briquetting 214 forms a clamp groove, the clamp groove is used for pressing from both sides the pick up 600 or forked tail to realize the connection of gun sight mount pad and pick up 600 or forked tail, adjustment subassembly 215 is used for adjusting the size of clamp groove.

The adjusting assembly 215 comprises a screw 216 and a locking nut 217, the screw 216 is fixedly arranged on the bracket main body 211, the pressing block 214 and the nut are sleeved on the screw 216, the pressing block 214 is positioned between the bracket main body 211 and the nut, and the screw 216 is matched with the locking nut 217 to adjust the distance between the pressing block 214 and the bracket main body 211, namely, the distance between the pressing block 214 and the fixing block 213, so as to adjust the size of the clamping groove.

As shown in fig. 1 and 2, the number of the adjusting components 215 is two.

The adjusting assembly 215 further includes a washer, the washer is sleeved on the screw 216, and the washer is located between the pressing block 214 and the nut.

As shown in fig. 4 and 5, the clip slots are dovetail slots to facilitate securing the scope mount to a pickup 600 or dovetail. Fixed block 213 has first inclined plane, briquetting 214 has the second inclined plane, the scope mount pad is fixed to the pick up 600 or the forked tail on the back, first inclined plane with the forked tail perhaps inclined plane on the pick up 600 is inconsistent, the second inclined plane with the forked tail perhaps inclined plane on the pick up 600 is inconsistent. The structure in which the lock nut 217 locks the pressing block 214 to clamp the pickup truck 600 through the clamping groove is shown in fig. 4, and the structure in which the lock nut 217 does not lock the pressing block 214 is shown in fig. 5.

Referring to fig. 5, the lower bracket body 210 further includes a reset assembly. The return assembly includes a return spring 218 and a push rod 219. Reset holes are formed in the support main body 211, the reset spring 218 and one end of the ejector rod 219 are arranged in the reset holes, the reset spring 218 is sleeved on the ejector rod 219, the ejector rod 219 is used for compressing the reset spring 218, and the other end of the ejector rod 219 is abutted against the pressing block 214 under the action of the reset spring 218. Thus, when the locking nut 217 is tightened, the pressing block 214 pushes the ejector rod 219 to compress the return spring 218, and when the locking nut 217 is loosened, the return spring 218 returns to push the ejector rod 219 to eject the pressing block 214, so that the quick disassembly of the sighting telescope mounting base is realized.

In other embodiments, the return assembly includes a return spring. Reset holes have been seted up to support main part 211, reset spring's one end sets up in the reset holes, and with the pore wall fixed connection in reset holes, reset spring's the other end with briquetting 214 fixed connection. Furthermore, the reset assembly further comprises a spring sleeve, the spring sleeve is sleeved on the reset spring, and part of the spring sleeve is located in the reset hole and used for avoiding the reset spring from bending.

Referring to fig. 2, the lower bracket 200 further includes a stopper 230, and the stopper 230 is fixedly disposed on the bracket main body 211 in the lower bracket body 210 and is located in the clamping groove. The stopper 230 is used to limit the movement of the scope mounting base along the length direction of the pickup 600. This improves the mounting stability of the scope mount.

Referring to fig. 3, 6, 7 and 8, fig. 6 is a cross-sectional view of the scope mount after the upper bracket 100 moves relative to the lower bracket 200 according to an embodiment of the present invention, fig. 7 is a schematic structural view of the scope mount with the scope 700 mounted thereon according to an embodiment of the present invention, fig. 8 is a schematic structural view of the scope mount with the scope 700 and the pickup 600 mounted thereon according to an embodiment of the present invention, and the working principle of the scope mount will be described below by taking the scope mount mounted on the pickup 600 as an example.

When the lower carriage 200 is subjected to a large impact, for example, when shooting, the impact on the gun is transmitted to the lower carriage 200 through the pickup 600, so that the lower carriage 200 suddenly moves backward rapidly, and the upper carriage 100 and the scope 700 move forward due to inertia. As shown in fig. 6, the lower bracket 200 is rapidly moved to the right with respect to the upper bracket 100, and the upper bracket 100 and the scope 700 are rapidly moved to the left with respect to the lower bracket 200. At this time, the four springs 320 fitted over the two guide rods 310 are gradually compressed to buffer the impact applied to the lower bracket 200. The upper bracket 100 and the scope 700 continue to move in a decelerated motion relative to the lower bracket 200, and the spring 320 continues to be compressed. When the spring 320 is compressed to the shortest, the resistance against the leftward movement of the upper bracket 100 and the scope 700 with respect to the lower bracket 200 is maximized. Thereafter, the spring 320 starts to bounce, the upper bracket 100 and the sighting telescope 700 start to move rightwards relative to the lower bracket 200 until the original positions are restored, and the structural schematic diagram of the upper bracket 100 and the lower bracket 200 which are restored to the original positions is shown in fig. 3.

The sighting telescope mounting base has a good buffering effect. Through tests and actual target shooting tests, the sighting telescope mounting base can reduce the impact magnitude transmitted to the sighting telescope by 12.7mm and other large-caliber firearms by over 70 percent. Moreover, after shooting for many times, the sighting telescope can still keep high sighting accuracy. In addition, the sighting telescope mounting base disclosed by the invention has the characteristics of small volume, light weight and high cost performance, and the competitiveness of the sighting telescope mounting base can be improved.

The above description is only for the purpose of describing the preferred embodiments of the present invention, and is not intended to limit the scope of the present invention, and any variations and modifications made by those skilled in the art based on the above disclosure are within the scope of the appended claims.

Claims

1. The utility model provides a gun sight mount pad for install the gun sight in one of pick-up and forked tail, its characterized in that, the gun sight mount pad includes upper bracket, lower carriage and guide rod spring unit, the upper bracket be used for with gun sight fixed connection, the lower carriage be used for with the pick-up with one of them fixed connection of forked tail, the guide rod spring unit connect the upper bracket with the lower carriage, just the guide rod spring unit has elasticity.

2. The sight mount of claim 1, wherein the guide rod spring assembly comprises a guide rod and a spring, the upper bracket and the lower bracket are slidably coupled via the guide rod, and the spring is disposed over the guide rod and between the upper bracket and the lower bracket.

3. The sight mount of claim 2, wherein the upper bracket comprises an upper bracket body and an upper sleeve coupled to the upper bracket body, the lower bracket comprises a lower bracket body and a lower sleeve coupled to the lower bracket body, the upper sleeve, the lower sleeve and the spring are sleeved on the guide rod, the guide rod is axially fixed with respect to the lower sleeve, the upper sleeve is reciprocally movable with respect to the guide rod along an axial direction of the guide rod, and the spring is disposed between the upper sleeve and the lower sleeve.

4. The sight mount of claim 3, wherein the number of the lower sleeves on one of the guide rods is three, the number of the upper sleeves on one of the guide rods is two, the number of the springs on one of the guide rods is two, the two upper sleeves are respectively disposed in two gaps formed by the three lower sleeves, the two springs are sequentially disposed in the two gaps formed by the three lower sleeves, and one of the springs is disposed between one of the lower sleeves on both sides of the guide rod and one of the adjacent upper sleeves, and the other spring is disposed between the lower sleeve in the middle and the other of the upper sleeves.

5. The scope mount of claim 4, wherein the number of guide rods is two.

6. The sight mount of claim 4, further comprising two cushioning pads disposed on the guide rods, wherein four gaps are formed between the upper sleeve and the lower sleeve, and wherein the springs and the cushioning pads are disposed in the four gaps in a staggered manner.

7. The scope mount of claim 4, further comprising bushings disposed between the guide bar and the upper sleeve, and between the guide bar and the lower sleeve.

8. The sighting telescope mount of claim 3, wherein the lower bracket body comprises a bracket main body, a fixing block, a pressing block and an adjusting assembly, the lower sleeve is fixedly connected with the bracket main body, one side of the bracket main body is fixedly connected with the fixing block, the other side of the bracket main body is detachably connected with the pressing block through the adjusting assembly, the fixing block, the bracket main body and the pressing block form a clamping groove, the clamping groove is used for clamping the pickup or the dovetail, and the adjusting assembly is used for adjusting the size of the clamping groove.

9. The sight mount of claim 8, wherein the adjustment assembly comprises a threaded rod and a lock nut, the threaded rod is fixedly disposed on the mount body, the pressing block and the nut are sleeved on the threaded rod, the pressing block is disposed between the mount body and the nut, and the threaded rod and the lock nut cooperate to adjust a distance between the pressing block and the mount body.

10. The sighting telescope mount of claim 8, wherein the lower bracket body further comprises a reset assembly, the reset assembly comprises a reset spring and a push rod, the bracket body is provided with a reset hole, one end of the reset spring and one end of the push rod are arranged in the reset hole, the reset spring is sleeved on the push rod, the push rod is used for compressing the reset spring, and the other end of the push rod is abutted against the pressing block under the action of the reset spring.