CN114704746B - Multi-axis motion fixing mechanism and method for camera - Google Patents

Abstract

The invention relates to the technical field of bearing rotation and discloses a camera multi-axis motion fixing mechanism and a camera multi-axis motion fixing method. At the rotatory process of slip cap, reducible and the excessive friction of the lateral wall of hose, avoid appearing card axle rotation motionless situation at the in-process of adjustment, when shortening the hose, lubricating oil increases gradually, avoid blocking and be difficult to rotate, when the lateral wall of slip cap moves gradually right, when drawing the pine hose, lubricating oil reduces gradually, can avoid lubricating oil too much and lead to the mirror axle unstable, the lateral wall of elastic sleeve and the lateral wall department of panel can support the lateral wall of slip cap, avoid the fuselage to appear vibrating and lead to camera lens fuzzy.

Description

Multi-axis motion fixing mechanism and method for camera

Technical Field

The invention relates to the technical field of bearing rotation, in particular to a camera multi-axis motion fixing mechanism and a camera multi-axis motion fixing method.

Background

When the camera rotates in multiple axes, the focal length of the camera can be effectively adjusted, when the bearings of the camera rotate with each other, the inner shaft and the outer shaft are repeatedly rubbed, when the butt joint clamping shaft at the rotating shaft shell wall is offset, the hand of an operator needs to be applied with a little force when the camera rotates again, when the butt joint clamping shaft at the shaft shell wall is converted from the offset position to the normal rail position, shake is caused at the position of the camera lens, the camera body vibrates violently, and the picture of the camera lens is blurred.

Disclosure of Invention

In order to solve the problem that the camera is worn due to multiple friction when in multi-axis rotation, the aim that lubricating oil can be gradually increased or decreased in the tightening and loosening process is fulfilled, and the camera is convenient to use, the invention is realized by the following technical scheme: the utility model provides a camera multiaxis motion fixed establishment, includes the mirror axle, the outside through-connection of mirror axle has the elastic sleeve, the one end through-connection that the mirror axle was kept away from to the lateral wall of elastic sleeve has the sliding sleeve, the inboard through-connection of sliding sleeve has the hose, the one end through-connection that the sliding sleeve was kept away from to the hose has the retainer plate, the one end through-connection that the sliding sleeve was kept away from to the retainer plate has the carriage, the side end through-connection that the carriage is close to the movable ring has the gleitbretter, the inside wall top through-connection of hose has the lamination board, the inner end through-connection that the hose was kept away from to the lamination board has the slider, the inside top through-connection of hose has branch, the lateral wall department sliding connection of movable ring has the fixture block, one side through-connection that the movable ring was kept away from to the fixture block has the board, the lateral wall department through-connection of movable plate has the retainer plate, the lateral wall department through-connection of elastic sleeve has the inserted bar, the one end through-connection that the elastic sleeve was kept away from the elastic sleeve has the panel.

Further, one end of the sliding sheet far away from the supporting frame is connected to the outer side wall of the hose in a penetrating mode, the side wall of the sliding sheet can slide outwards along the outer side wall of the hose, and the lubricant stored around the side wall of the supporting frame can be extruded.

Further, the side end of the sliding plate is connected to the side wall of the supporting rod in a penetrating mode, the left end of the supporting rod is pushed to the right end, and in the repeated adjustment process, the sliding plate can be advanced layer by layer through the side end of the sliding plate.

Further, the side walls of the sliding blocks are connected between the side walls of the supporting rods in a penetrating mode, and the side walls of the laminated plates penetrate between the side walls of the supporting rods along the side walls of the sliding blocks.

Further, the side wall of the sliding sheet is connected to the inner side wall of the supporting frame in a penetrating manner, the side wall of the sliding sheet is inserted into the side wall of the sliding sheet, and the side wall of the sliding sheet is pushed to approach the side wall of the supporting frame.

Further, the side wall of the panel is connected between the side walls of the elastic sleeve in a penetrating manner, the side wall of the sliding sleeve can be contracted to push the side wall of the panel, and the right end of the sliding sleeve and the left end of the elastic sleeve can mutually collide.

Further, one end of the supporting rod, which is close to the sliding sheet, is connected to the inside of the supporting frame in a penetrating manner, the outer end of the supporting rod can push the side wall of the clamping block to push the moving plate, and the side wall of the moving plate is inserted into the side wall of the sliding sheet.

A camera multi-axis motion fixation method, comprising the steps of:

s1, rotating the sliding sleeve at the position of the supporting frame by an operator, sliding the sliding sleeve rightward along the outer side wall of the hose, clamping the hose on the inner side of the sliding sleeve, pressing the laminated board inwards by the hose, and pushing the sliding plate upwards by the hose;

s2, rotating the side wall of the hose, reducing the distance from the inner side wall of the hose to the axis part, enabling the laminated board to be inserted between the side walls of the support rods along the side wall of the sliding block, enabling the side wall of the laminated board to be spirally rotated after being inserted into the side wall of the support rods, and scraping the inner end of the sliding plate;

s3, after the transverse length of the hose is shortened by rotating, the side wall of the supporting rod is pushed into the supporting frame in a spiral mode, the side wall of the supporting rod is pushed outwards through the inner side wall of the movable ring, and the outer end of the supporting rod pushes the side wall of the clamping block to push the moving plate;

s4, the sliding plate is inserted into the side wall of the sliding plate, the sliding plate is pushed to approach the side wall of the supporting frame, the sliding plate slides outwards along the side wall of the hose, and the lubricant stored around the side wall of the supporting frame is pushed through the left end of the supporting rod;

s5, in the repeated adjustment process, the lubricating oil can be gradually advanced layer by layer through the side end of the sliding plate, and accordingly lubricating oil at the left end of the inner side of the supporting rod can be smoothly pushed to the right end;

s6, gradually moving the side wall of the sliding sleeve leftwards, gradually increasing lubricating oil when shortening the hose, and gradually loosening the hose and gradually reducing the lubricating oil when gradually moving the side wall of the sliding sleeve rightwards;

s7, when the sliding sleeve slides to the outer side wall of the hose, the sliding sleeve is contracted to push the side wall of the panel, the right end of the sliding sleeve and the left end of the elastic sleeve are mutually impacted and combined, and the side wall of the elastic sleeve can be supported by the side wall of the panel.

The invention provides a camera multi-axis motion fixing mechanism and a camera multi-axis motion fixing method. The beneficial effects are as follows:

1. according to the camera multi-axis motion fixing mechanism and the camera multi-axis motion fixing method, the side wall of the support rod is also in a spiral shape, the side wall of the laminated board is spirally rotated after being inserted into the side wall of the support rod, the side wall of the laminated board can be scraped at the inner end of the sliding plate, when the side wall of the hose is twisted, the side wall of the laminated board is twisted with the side wall of the support rod in a crossed and overlapped mode, the distance between the sliding sleeve and the movable ring is favorably shortened, the excessive friction with the side wall of the hose in the twisting and rotating process of the side wall of the sliding sleeve can be reduced, and the situation that the clamping shaft is not rotated in the adjusting process can be avoided.

2. According to the camera multi-axis motion fixing mechanism and the camera multi-axis motion fixing method, in the process of repeatedly adjusting the sliding sheets, the sliding sheets can be gradually advanced layer by layer through the side ends of the sliding sheets, and accordingly lubricating oil at the left end of the inner side of the supporting rod can be smoothly pushed to the right end, so that when the side wall of the sliding sleeve gradually moves leftwards, the lubricating oil is gradually increased when the hose is shortened, the phenomenon that the hose is difficult to rotate due to clamping is avoided, when the side wall of the sliding sleeve gradually moves rightwards, the lubricating oil is gradually reduced when the hose is pulled loose, and the phenomenon that the lens axis is unstable due to excessive lubricating oil can be avoided.

3. According to the multi-axis motion fixing mechanism and the multi-axis motion fixing method for the camera, when the side wall of the sliding sleeve slides to the outer side wall of the hose, the side wall of the sliding sleeve can be contracted to push the side wall of the panel, the right end of the sliding sleeve and the left end of the elastic sleeve are mutually impacted, the side wall of the sliding sleeve and the side wall of the elastic sleeve are combined, the side wall of the elastic sleeve can be matched with the side wall of the panel, the side wall of the sliding sleeve can be supported, and the camera lens blurring caused by vibration of a camera body is avoided.

Drawings

FIG. 1 is a schematic diagram of the overall structure connection of the present invention;

FIG. 2 is a schematic view of the structural connection between the interior of the hose and the slider and sled of the present invention;

FIG. 3 is a schematic view of the structural connection between the moving coil and the sliding sheet according to the present invention;

fig. 4 is a schematic view of the connection of the elastic sleeve and the sliding sleeve according to the present invention, and the structural connection between the inner side of the elastic sleeve and the panel.

In the figure: 1. a mirror shaft; 2. an elastic sleeve; 3. a sliding sleeve; 4. a hose; 5. a movable ring; 6. a support frame; 7. laminating; 8. a slide block; 9. a slide plate; 10. a support rod; 11. a sliding sheet; 12. moving the plate; 13. a clamping block; 14. a limit ring; 15. a panel; 16. and a plunger.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Embodiments of the camera multi-axis motion fixing mechanism and method are as follows:

referring to fig. 1-4, a multi-axis motion fixing mechanism for a camera comprises a mirror shaft 1, an elastic sleeve 2 is connected with an outer side of the mirror shaft 1 in a penetrating manner, a sliding sleeve 3 is connected with an outer side wall of the elastic sleeve 2 in a penetrating manner at one end far away from the mirror shaft 1, a flexible pipe 4 is connected with an inner side of the sliding sleeve 3 in a penetrating manner, a movable ring 5 is connected with one end of the flexible pipe 4 far away from the sliding sleeve 3 in a penetrating manner, a supporting frame 6 is connected with a sliding sheet 11 in a penetrating manner at one end of the movable ring 5 far away from the sliding sleeve 3, a laminated plate 7 is connected with an inner side end of the flexible pipe 4 in a penetrating manner, a sliding block 8 is connected with an inner side wall top of the flexible pipe 4 in a penetrating manner, a supporting rod 10 is connected with a clamping block 13 in a penetrating manner at an inner axis of the flexible pipe 4, a moving plate 12 is connected with a side wall of the moving plate 12 in a penetrating manner at one side of the moving plate, a sliding plate 11 is connected with a side wall of the flexible pipe 2 in a penetrating manner, a limiting rod 16 is connected with a penetrating manner at one end of the inner side wall of the flexible pipe 4 far away from the sliding sleeve 2, and a limiting rod 16 is connected with a penetrating member 16 at one end of the elastic rod 16.

One end of the sliding sheet 11 far away from the supporting frame 6 is connected to the outer side wall of the hose 4 in a penetrating way, the side wall of the sliding sheet 11 can slide outwards along the outer side wall of the hose 4, and the lubricant stored around the side wall of the supporting frame 6 can be extruded.

The side end of the sliding plate 9 is connected with the side wall of the supporting rod 10 in a penetrating way, the left end of the supporting rod 10 is pushed to the right end, and in the repeated adjustment process, the sliding plate 9 can be advanced layer by layer through the side end of the sliding plate 9.

The side walls of the slide 8 are connected between the side walls of the struts 10 in a penetrating manner, and the side walls of the stack 7 are inserted between the side walls of the struts 10 along the side walls of the slide 8.

The side wall of the sliding vane 11 is connected with the inner side wall of the supporting frame 6 in a penetrating way, the side wall of the moving plate 12 is inserted into the side wall of the sliding vane 11, and the side wall of the sliding vane 11 is pushed to approach the side wall of the supporting frame 6.

The side wall of the panel 15 is connected between the side walls of the elastic sleeve 2 in a penetrating way, the side wall of the sliding sleeve 3 can be contracted to push the side wall of the panel 15, and the right end of the sliding sleeve 3 and the left end of the elastic sleeve 2 can mutually collide.

One end of the supporting rod 10, which is close to the sliding sheet 11, is connected to the inside of the supporting frame 6 in a penetrating way, and the outer end of the supporting rod 10 can push the side wall of the clamping block 13 to push the moving plate 12, and the side wall of the moving plate 12 is inserted into the side wall of the sliding sheet 11.

Working principle: when in use, as shown in fig. 1 and 2, an operator holds the support frame 6 by hand, when the sliding sleeve 3 is rotated, the inner side wall of the sliding sleeve 3 slides rightward and outward along the outer side wall of the flexible pipe 4, the outer side wall of the flexible pipe 4 is clamped at the inner side of the sliding sleeve 3, the side wall of the flexible pipe 4 inwards presses the laminated board 7, the flexible pipe 4 at the bottom side wall also pushes the sliding plate 9 upwards, in the rotating process, the side wall of the sliding sleeve 3 rotates to drive the outer side wall of the flexible pipe 4, the side wall of the flexible pipe 4 rotates in a twisting manner, at the moment, the distance from the inner side wall of the flexible pipe 4 to the axis part is reduced, the side wall of the laminated board 7 is inserted between the side walls of the supporting rod 10 along the side wall of the sliding block 8, and the side wall of the laminated board 7 rotates in a spiral manner after being inserted into the side wall of the supporting rod 10, the inner end of the sliding plate 9 can be scraped, when the side wall of the flexible pipe 4 twists, the side wall of the laminated board 7 is crossed with the side wall of the twisting and the side wall of the supporting rod 10, the distance between the sliding sleeve 3 and the movable ring 5 can be reduced, and the excessive friction of the side wall of the flexible pipe can be reduced;

as shown in fig. 1 and 3, when the lateral length of the hose 4 is shortened due to rotation, the side wall of the strut 10 can be pushed into the support frame 6 in a spiral manner, and can be pushed outwards through the inner side wall of the movable ring 5, the outer end of the strut 10 can push the side wall of the clamping block 13 to push the moving plate 12, the side wall of the moving plate 12 is inserted into the side wall of the sliding plate 11, the side wall of the sliding plate 11 is pushed towards the side wall of the support frame 6, at this time, the side wall of the sliding plate 11 can slide outwards along the outer side wall of the hose 4, the lubricant stored around the side wall of the support frame 6 can be pushed towards the right end through the left end of the strut 10 in fig. 2, and in the process of repeated adjustment, the lubricant at the inner side left end of the strut 10 can be pushed towards the right end in a layer by layer along with the side end of the strut 9, so that when the side wall of the sliding sleeve 3 gradually moves leftwards, the lubricant gradually increases when the hose 4 is shortened, and when the side wall of the sliding sleeve 3 gradually moves rightwards, the lubricant gradually decreases when the hose 4 is loosened;

as shown in fig. 1 and 4, when the side wall of the sliding sleeve 3 slides to the outer side wall of the hose 4, the side wall of the sliding sleeve 3 can be contracted to push the side wall of the panel 15, the right end of the sliding sleeve 3 and the left end of the elastic sleeve 2 collide with each other, the sliding sleeve 3 and the side wall of the elastic sleeve 2 are combined, the side wall of the elastic sleeve 2 can be matched with the side wall of the panel 15, and the side wall of the sliding sleeve 3 can be supported to avoid vibration of the machine body.

Although embodiments of the present invention 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 invention, the scope of which is defined in the appended claims and their equivalents.

Claims (2)

1. A camera multiaxial motion fixation mechanism comprising a mirror axis (1), characterized in that: the utility model discloses a mirror axle, including mirror axle (1), elastic sleeve (2) are connected with in a penetrating way in the outside of mirror axle (1), the one end through-connection that mirror axle (1) was kept away from to the lateral wall of elastic sleeve (2) has sliding sleeve (3), the inboard through-connection of sliding sleeve (3) has hose (4), the one end through-connection that sliding sleeve (3) was kept away from to hose (4) has retainer plate (5), the one end through-connection that sliding sleeve (3) was kept away from to retainer plate (5) has braced frame (6), the lateral end through-connection that braced frame (6) is close to movable ring (5) has gleitbretter (11), the inside wall top through-connection of hose (4) has lamination board (7), the inner through-connection that lamination board (7) kept away from hose (4) has slider (8), the inside axle center department through-connection of hose (4) has branch (10), the lateral wall department sliding connection of movable ring (5) has fixture block (13), one side through-connection that retainer plate (13) kept away from movable ring (5) has lateral wall (12) and moves slip sheet (12), lateral wall (14) is connected in the lateral wall through-connection of elastic sleeve (2), the inner side wall of the elastic sleeve (2) is connected with an inserting rod (16) in a penetrating way, and one end, far away from the elastic sleeve (2), of the inserting rod (16) is connected with a panel (15) in a penetrating way;

one end of the sliding sheet (11) far away from the supporting frame (6) is connected to the outer side wall of the hose (4) in a penetrating way;

the side end of the sliding plate (9) is connected with the side wall of the supporting rod (10) in a penetrating way;

the side walls of the sliding blocks (8) are connected between the side walls of the supporting rods (10) in a penetrating manner;

the side wall of the sliding sheet (11) is connected with the inner side wall of the supporting frame (6) in a penetrating way;

the side walls of the panel (15) are connected between the side walls of the elastic sleeve (2) in a penetrating way;

one end of the supporting rod (10) close to the sliding sheet (11) is connected to the inside of the supporting frame (6) in a penetrating mode.

2. A camera multi-axis motion fixing method applied to the camera multi-axis motion fixing mechanism of claim 1, comprising the following steps:

s1, rotating the sliding sleeve (3) at the position of the supporting frame (6) by an operator, sliding and pulling out the sliding sleeve (3) rightward along the outer side wall of the hose (4), clamping the hose (4) on the inner side of the sliding sleeve (3), pressing the lamination plate (7) inwards by the hose (4), and pushing the sliding plate (9) upwards by the hose (4);

s2, the side wall of the hose (4) rotates, the distance from the inner side wall of the hose (4) to the axis part is reduced, the laminated plate (7) is inserted between the side walls of the support rods (10) along the side wall of the sliding block (8), the side wall of the laminated plate (7) is spirally rotated after being inserted into the side wall of the support rods (10), and the inner end of the sliding plate (9) is scraped;

s3, after the transverse length of the hose (4) is shortened by rotating, the side wall of the supporting rod (10) is pushed into the supporting frame (6) in a spiral mode, the side wall of the supporting rod is pushed outwards through the inner side wall of the movable ring (5), and the outer end of the supporting rod (10) pushes the side wall of the clamping block (13) to push the moving plate (12);

s4, inserting a moving plate (12) into the side wall of the sliding plate (11), pushing the sliding plate (11) to approach the side wall of the supporting frame (6), enabling the sliding plate (11) to slide outwards along the side wall of the hose (4), and pushing the lubricant stored around the side wall of the supporting frame (6) through the left end of the supporting rod (10);

s5, in the repeated adjustment process, the lubricating oil can be gradually advanced through the side end of the sliding plate (9) layer by layer, and then lubricating oil at the left end of the inner side of the supporting rod (10) can be smoothly pushed to the right end;

s6, gradually moving the side wall of the sliding sleeve (3) leftwards, gradually increasing lubricating oil when shortening the hose (4), and gradually loosening the hose (4) and gradually reducing the lubricating oil when gradually moving the side wall of the sliding sleeve (3) rightwards;

s7, when the sliding sleeve (3) slides to the outer side wall of the hose (4), the sliding sleeve (3) contracts to push the side wall of the panel (15), the right end of the sliding sleeve (3) and the left end of the elastic sleeve (2) are mutually impacted and combined, and the side wall of the elastic sleeve (2) can be supported by the side wall of the panel (15).