CN221154677U - Automatic roll-over mirror roll-over adjustment structure - Google Patents

Abstract

The utility model discloses an automatic turning mirror distance adjusting structure which comprises a device body, wherein a turning mirror frame is movably arranged at the bottom of the device body, a mounting block is fixedly arranged on the bottom surface of the device body, a groove is formed in the mounting block, a shaft rod A is movably arranged in the groove, a rotating handle B is fixedly arranged at one end of the shaft rod A, a concave block is fixedly arranged at the other end of the shaft rod A, a bearing B is movably arranged at the outer side of the shaft rod A, a movable block A is movably arranged at the outer side of the bearing B, a limiting block A is fixedly arranged at one side of the movable block A, and a shaft rod B is movably arranged in the groove. Through axostylus axostyle A and axostylus axostyle B that set up, rotate axostylus axostyle A can make slider B drive movable lens A and carry out lateral shifting, and the axostylus axostyle B that rotates can make slider A drive movable lens B and carry out lateral shifting again, can carry out single regulation with the interpupillary distance of adaptation wearer to movable lens A and movable lens B, has improved the viewing effect of wearer.

Description

Automatic roll-over mirror roll-over adjustment structure

Technical Field

The utility model belongs to the technical field of automatic turning mirrors, and particularly relates to an automatic turning mirror distance adjusting structure.

Background

The intelligent turnover mirror is a professional visual training instrument capable of increasing the adjusting force and improving the adjusting function, the adjusting sensitivity and the adjusting hysteresis, and the training of eyes is more digital and visual through intelligent control. By relaxing the eyes through the presbyopic lens, the myopic lens contracts the eyes, allowing them to tighten and loosen as if we were exercising the muscle strength. The focusing capability of eyes for far and near is improved and improved, the good camera zooms fast just like the focusing of a camera lens, and clear pictures can be captured quickly and easily, otherwise, the phenomena of visual fatigue, reading disorder, slow response and the like are easy to occur.

The utility model provides an automatic tilting mirror, including the fixed mirror, the fixed mirror of automatic tilting mirror is divided into upset lens and fixed lens two kinds, fixes at user's head with the bandage when wearing automatic tilting mirror, lets the lens be located the eye the place ahead, and every user's interpupillary distance all is different, and the interval between the unable regulation lens of current fixed mirror of an automatic tilting mirror, the interpupillary distance between different wearer's eyes is different, leads to watching the effect not good, based on this we propose an automatic tilting mirror roll-over structure.

Disclosure of utility model

Aiming at the defects in the prior art, the utility model aims to provide an automatic turning mirror distance adjusting structure, which solves the problem that the prior automatic turning mirror fixing mirror cannot adjust the distance between lenses, so that the watching effect is poor.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an automatic roll-over mirror roll-over structure, includes the device body, the bottom movable mounting of device body has the upset picture frame, the bottom surface fixed mounting of device body has the installation piece, the inside of installation piece is seted up flutedly, the inside movable mounting of recess has axostylus axostyle A, the one end fixed mounting of axostylus axostyle A has changeing handle B, the other end fixed mounting of axostylus axostyle A has the concave block, the outside movable mounting of axostylus axostyle A has bearing B, the outside movable mounting of bearing B has movable block A, one side fixed mounting of movable block A has stopper A, the inside movable mounting of recess has axostylus axostyle B, the one side fixed mounting of axostylus axostyle B has bearing A, the outside movable mounting of bearing A has movable block B, one side movable mounting of stopper B has the bolt, the spacing groove has been seted up to the front side of installation piece, the bottom surface of installation piece is opened movable groove, the inside movable mounting of recess has axostylus axostyle B, the one end fixed mounting of axostylus axostyle B has the bearing A, the inside movable mounting of axostylus axostyle B has the movable groove, the inside fixed mounting of sliding block A has the sliding block A, the inside sliding block A has the sliding block A.

Preferably, one end of the shaft rod B movably penetrates through one end of the mounting block and extends to one end of the rotating handle a, and the other end of the shaft rod B is threaded through one side of the sliding block a and extends to one end of the protruding block.

Through above-mentioned technical scheme, advantage lies in that rotation handle A drives axostylus axostyle B and rotates and make slider A carry out lateral shifting, is convenient for adjust.

Preferably, one end of the shaft rod A movably penetrates through one end of the mounting block and extends to one end of the rotating handle B, and the other end of the shaft rod A penetrates through one side of the sliding block B in a threaded manner and extends to one end of the concave block.

Through above-mentioned technical scheme, advantage lies in that the rotation is rotated B and is driven axostylus axostyle A and rotate and make slider B carry out lateral shifting, is convenient for adjust.

Preferably, one end of the limiting block B movably penetrates through the inside of the limiting groove and extends to the outer side of the mounting block, and one end of the limiting block A movably penetrates through the inside of the limiting groove and extends to the outer side of the mounting block.

Through above-mentioned technical scheme, advantage lies in driving inside concave piece and lug through stopper B and stopper A and blocking it together, makes axostylus axostyle A and axostylus axostyle B can rotate simultaneously and adjusts.

Preferably, the bottom of the movable lens A is slidably mounted in the chute, and the bottom of the movable lens B is slidably mounted in the chute.

Through above-mentioned technical scheme, the advantage lies in increasing the stability when movable lens A and movable lens B remove through the spout.

Preferably, the bottom end of the sliding block a movably penetrates through the inside of the movable groove and extends to the top surface of the movable lens B, and the bottom end of the sliding block B movably penetrates through the inside of the movable groove and extends to the top surface of the movable lens a.

Through above-mentioned technical scheme, advantage lies in can drive movable lens A and movable lens B through slider A and slider B and carry out the transverse adjustment position, facilitate the use.

Preferably, one end thread of the bolt penetrates through one side of the limiting block B and extends to one side of the limiting block A.

Through above-mentioned technical scheme, the advantage lies in can fix stopper B and stopper A's position through the bolt, makes concave block and lug hug closely together always, has increased the stability of device.

Compared with the prior art, the utility model has the beneficial effects that:

1. Through the device body that sets up, when using, the wearer wears the device body at the head, the adjusting device makes fixed frame and eye parallel then, then rotate B and drive axostylus axostyle A and rotate and make slider B carry out lateral shifting, movable block A reduces the frictional force when axostylus axostyle A rotates simultaneously, slider B can drive movable lens A and remove the regulation, at this moment, rotation A drives axostylus axostyle B and rotates and make slider A carry out lateral shifting, simultaneously movable block B reduces the frictional force when axostylus axostyle B rotates, slider A can drive movable lens B and remove the regulation, the pupil distance of individual personnel of convenient adaptation, and screw the bolt can fix stopper B and stopper A's position, make concave block and lug hug closely together all the time, at this moment rotate one of axostylus axostyle A or change B and axostylus axostyle B just can rotate simultaneously, make movable lens A and movable lens B remove the regulation and make it and the pupil distance looks adaptation between wearer's eyes, and practicality is good.

2. Through axostylus axostyle A and axostylus axostyle B that set up, rotate axostylus axostyle A can make slider B drive movable lens A and carry out lateral shifting, and the axostylus axostyle B that rotates can make slider A drive movable lens B and carry out lateral shifting again, can carry out single regulation with the interpupillary distance of adaptation wearer to movable lens A and movable lens B, has improved the viewing effect of wearer.

Drawings

FIG. 1 is a schematic view of a three-dimensional appearance structure of the present utility model;

FIG. 2 is a schematic view of a rear sectional structure of the present utility model;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A according to the present utility model;

FIG. 4 is a schematic side sectional view of the present utility model;

FIG. 5 is an enlarged schematic view of the structure of FIG. 4B according to the present utility model;

fig. 6 is a schematic view of a front cross-sectional structure of the present utility model.

In the figure: 1. a device body; 2. a movable lens A; 3. turning over the glasses frame; 4. a movable lens B; 5. a chute; 6. a rotating handle A; 7. a rotating handle B; 8. a limiting block B; 9. a limiting block A; 10. a fixed frame; 11. a shaft lever A; 12. a shaft lever B; 13. a sliding block A; 14. a sliding block B; 15. a groove; 16. a limit groove; 17. a bearing A; 18. a bearing B; 19. a concave block; 20. a bump; 21. a mounting block; 22. a movable block A; 23. a movable block B; 24. a bolt; 25. a movable groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by one of ordinary skill in the art without undue burden on the person of ordinary skill in the art based on the embodiments of the present utility model, are within the scope of the present utility model.

As shown in fig. 1-6, an automatic turning mirror distance adjusting structure comprises a device body 1, a turning mirror frame 3 is movably mounted at the bottom of the device body 1, a mounting block 21 is fixedly mounted at the bottom surface of the device body 1, a groove 15 is formed in the inner side of the mounting block 21, a shaft rod a11 is movably mounted at the inner side of the groove 15, a rotating handle B7 is fixedly mounted at one end of the shaft rod a11, a concave block 19 is fixedly mounted at the other end of the shaft rod a11, a bearing B18 is movably mounted at the outer side of the shaft rod a11, a movable block a22 is movably mounted at the outer side of the bearing B18, a limit block A9 is fixedly mounted at one side of the movable block a22, a lug a 20 is fixedly mounted at the other end of the groove 15, a bearing a17 is fixedly mounted at one end of the shaft rod B12, a movable block B23 is fixedly mounted at the outer side of the bearing a 23, a bolt 24 is movably mounted at one side of the limit block B8, a limit groove 16 is formed at the front side of the mounting block 21, a limit block 21 is fixedly mounted at the bottom surface of the inner side of the groove 25, a sliding block 15 is fixedly mounted at the bottom surface of the groove 10B 13 is fixedly mounted at the bottom surface of the inner side of the groove 15, a sliding block 10 is fixedly mounted at the bottom surface of the sliding block 10, and the sliding block 10 is fixedly mounted at the bottom surface of the sliding block 10.

The working principle of the technical scheme is as follows:

When the device is used, a wearer wears the device body 1 on the head, then the adjusting device enables the fixed frame 10 to be parallel to eyes, then the rotating handle B7 drives the shaft rod A11 to rotate so as to enable the sliding block B14 to transversely move, meanwhile, the moving block A22 reduces friction force generated when the shaft rod A11 rotates, the sliding block B14 can drive the movable lens A2 to move and adjust, at the moment, the rotating handle A6 drives the shaft rod B12 to rotate so as to enable the sliding block A13 to transversely move, meanwhile, the moving block B23 reduces friction force generated when the shaft rod B12 rotates, the sliding block A13 can drive the movable lens B4 to move and adjust, the pupil distance of individual wearing personnel is convenient to adapt, the position of the limiting block B8 and the limiting block A9 can be fixed by screwing the bolt 24, the concave block 19 and the convex block 20 are always clung together, at the moment, one of the shaft rod A11 of the rotating handle A6 or the shaft rod B7 can simultaneously rotate so that the movable lens A2 and the movable lens B4 can move and adjust so as to adapt to the pupil distance between eyes of the wearer, and the practicality is good.

In another embodiment, as shown in fig. 1-6, one end of the shaft B12 movably penetrates one end of the mounting block 21 and extends to one end of the knob A6, and the other end of the shaft B12 is threaded through one side of the slider a13 and extends to one end of the bump 20.

The rotating handle A6 drives the shaft lever B12 to rotate so that the sliding block A13 transversely moves, and adjustment is facilitated.

In another embodiment, as shown in fig. 1-6, one end of the shaft a11 movably penetrates one end of the mounting block 21 and extends to one end of the knob B7, and the other end of the shaft a11 is threaded through one side of the slider B14 and extends to one end of the recess block 19.

The rotating handle B7 drives the shaft rod A11 to rotate so that the sliding block B14 transversely moves, and adjustment is facilitated.

In another embodiment, as shown in fig. 1-6, one end of the stopper B8 is movably inserted into the stopper groove 16 and extends to the outside of the mounting block 21, and one end of the stopper A9 is movably inserted into the stopper groove 16 and extends to the outside of the mounting block 21.

The limiting block B8 and the limiting block A9 drive the inner concave block 19 and the convex block 20 to clamp the inner concave block and the convex block together, so that the shaft rod A11 and the shaft rod B12 can rotate simultaneously for adjustment.

In another embodiment, as shown in fig. 1-6, the bottom of the movable lens A2 is slidably mounted inside the chute 5, and the bottom of the movable lens B4 is slidably mounted inside the chute 5.

The stability of the movable lens A2 and the movable lens B4 during movement is increased through the chute 5.

In another embodiment, as shown in fig. 1-6, the bottom end of the slider a13 is movable through the interior of the movable groove 25 and extends to the top surface of the movable lens B4, and the bottom end of the slider B14 is movable through the interior of the movable groove 25 and extends to the top surface of the movable lens A2.

The movable lens A2 and the movable lens B4 can be driven to transversely adjust the positions through the sliding blocks A13 and the sliding blocks B14, so that the device is convenient to use.

In another embodiment, as shown in FIGS. 1-6, one end of the bolt 24 is threaded through one side of the stop block B8 and extends to one side of the stop block A9.

The positions of the limiting block B8 and the limiting block A9 can be fixed through the bolts 24, so that the concave block 19 and the convex block 20 are always clung together, and the stability of the device is improved.

The working principle and the using flow of the utility model are as follows: when the device is used, a wearer wears the device body 1 on the head, then the adjusting device enables the fixed frame 10 to be parallel to eyes, then the rotating handle B7 drives the shaft rod A11 to rotate so that the sliding block B14 transversely moves, meanwhile, the moving block A22 reduces friction force generated when the shaft rod A11 rotates, the sliding block B14 can drive the movable lens A2 to move and adjust, at the moment, the rotating handle A6 drives the shaft rod B12 to rotate so that the sliding block A13 transversely moves, meanwhile, the moving block B23 reduces friction force generated when the shaft rod B12 rotates, the sliding block A13 can drive the movable lens B4 to move and adjust, the pupil distance of individual wearing personnel is convenient, the screwing bolts 24 can fix the positions of the limiting blocks B8 and the limiting blocks A9, the concave blocks 19 and the convex blocks 20 are always clung together, at the moment, one of the shaft rod A11 of the rotating handle A6 or the rotating handle B7 and the shaft rod B12 can simultaneously rotate so that the movable lens A2 and the movable lens B4 move and adjust, the pupil distance between the two eyes of the wearer is matched, the practicality is good, the sliding block A4 can be moved and the sliding block B4 can be adjusted transversely through the set up, the sliding block A11 and the shaft rod A11 can move the sliding block B2, and the sliding block B4 can be adjusted transversely, and the pupil distance of the movable lens B2 can be adjusted, and the pupil distance of the movement of the moving lens B can be adjusted.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an automatic roll-over mirror roll-over structure, includes device body (1), its characterized in that: the bottom movable mounting of device body (1) has upset picture frame (3), the bottom surface fixed mounting of device body (1) has installation piece (21), recess (15) have been seted up to the inside of installation piece (21), the inside movable mounting of recess (15) has axostylus axostyle A (11), the one end fixed mounting of axostylus axostyle A (11) has changeing handle B (7), the other end fixed mounting of axostylus axostyle A (11) has concave block (19), the outside movable mounting of axostylus axostyle A (11) has bearing B (18), the outside movable mounting of bearing B (18) has movable block A (22), one side fixed mounting of movable block A (22) has stopper A (9), the inside movable mounting of recess (15) has axostylus axostyle B (12), the one end fixed mounting of axostylus axostyle B (12) has changeing handle A (6), the other end fixed mounting of axostylus axostyle B (12) has lug (20), the outside fixed mounting of axostylus axostyle A (17), the outside movable mounting of axostylus axostyle A (17) has movable block A (23), the outside movable mounting of axostyle A (17) has movable block B (23), one side of movable block B (8) is installed on one side of movable block B (24), limiting groove (16) have been seted up to the front side of installation piece (21), movable groove (25) have been seted up to the bottom surface of installation piece (21), the inside slidable mounting of recess (15) has slider B (14), the bottom surface fixed mounting of slider B (14) has movable lens A (2), the inside slidable mounting of recess (15) has slider A (13), the bottom surface fixed mounting of slider A (13) has movable lens B (4), the bottom surface fixed mounting of installation piece (21) has fixed frame (10), spout (5) have been seted up to the inboard of fixed frame (10).

2. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: one end of the shaft rod B (12) movably penetrates through one end of the mounting block (21) and extends to one end of the rotating handle A (6), and the other end of the shaft rod B (12) penetrates through one side of the sliding block A (13) in a threaded manner and extends to one end of the protruding block (20).

3. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: one end of the shaft rod A (11) movably penetrates through one end of the mounting block (21) and extends to one end of the rotating handle B (7), and the other end of the shaft rod A (11) penetrates through one side of the sliding block B (14) in a threaded mode and extends to one end of the concave block (19).

4. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: one end of the limiting block B (8) movably penetrates through the inside of the limiting groove (16) and extends to the outer side of the mounting block (21), and one end of the limiting block A (9) movably penetrates through the inside of the limiting groove (16) and extends to the outer side of the mounting block (21).

5. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: the bottom of the movable lens A (2) is slidably arranged in the chute (5), and the bottom of the movable lens B (4) is slidably arranged in the chute (5).

6. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: the bottom end of the sliding block A (13) movably penetrates through the inside of the movable groove (25) and extends to the top surface of the movable lens B (4), and the bottom end of the sliding block B (14) movably penetrates through the inside of the movable groove (25) and extends to the top surface of the movable lens A (2).

7. The automatic roll-over mirror distance adjustment structure according to claim 1, wherein: one end thread of the bolt (24) penetrates through one side of the limiting block B (8) and extends to one side of the limiting block A (9).