CN220843026U - Unmanned aerial vehicle camera cloud platform shock absorber structure - Google Patents

Abstract

The utility model discloses an unmanned aerial vehicle camera tripod head shock-absorbing structure, which comprises a machine body, wherein a tripod head main body is fixedly arranged at the bottom of the machine body, a mounting seat is fixedly arranged at the bottom of the tripod head main body, a rotating ball is rotatably arranged at the inner side of the mounting seat, a connecting rod is fixedly arranged at the bottom of the rotating ball, a notch is formed in the mounting seat, the bottom end of the connecting rod extends out of the notch and is fixedly provided with a sleeve, a shock-absorbing air bag is fixedly arranged on the inner wall of the notch, the connecting rod penetrates through the shock-absorbing air bag, a spring is fixedly arranged at the top of the inner side of the sleeve, a support column is fixedly arranged at the bottom end of the spring, the bottom end of the support column extends out of the sleeve and is fixedly provided with a camera, a damping sheet is fixedly sleeved on the support column, and the damping sheet is contacted with the inner side wall of the sleeve. When the camera receives transverse vibration, the vibration is absorbed through the vibration damping air bags, so that the vibration damping is realized, when the camera receives longitudinal vibration, the plurality of damping fins are utilized to absorb the longitudinal vibration, the vibration damping is realized, the camera is prevented from shaking as much as possible, and therefore the shooting effect and quality are guaranteed.

Description

Unmanned aerial vehicle camera cloud platform shock absorber structure

Technical Field

The utility model belongs to the technical field of unmanned aerial vehicles, and particularly relates to an unmanned aerial vehicle camera cradle head shock-absorbing structure.

Background

The unmanned aerial vehicle is an unmanned aerial vehicle which is controlled by radio remote control equipment or an onboard computer program control system. The unmanned aerial vehicle aerial photography technology can be widely applied to the fields of national ecological environment protection, mineral resource exploration, marine environment monitoring, land utilization investigation, water resource development, crop growth monitoring and estimation, advertisement photography and the like, and has wide market demands. The unmanned aerial vehicle has the advantages of simple structure and low use cost, can complete tasks executed by the manned aircraft, is more suitable for tasks which are not executed by the manned aircraft, and has great effects in emergency and early warning of sudden matters.

At present unmanned aerial vehicle takes photo by plane in the flight, because the interference of external factors such as wind-force and inertia, the camera probably shakes to lead to the camera lens to take place to rock, finally lead to shooting effect poor and low quality, still probably can cause the influence to the camera life-span.

Disclosure of utility model

Aiming at the problems that the current aerial unmanned aerial vehicle is poor in shooting effect and low in quality and can influence the service life of a camera due to the interference of external factors such as wind power, inertia and the like, a camera possibly vibrates, so that a camera lens is rocked, and the service life of the camera is influenced.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides an unmanned aerial vehicle camera cloud platform shock absorber structure, includes the organism, the fixed cloud platform main part that is provided with in organism bottom, the fixed mount pad that is provided with in cloud platform main part bottom, the mount pad inboard rotates and is provided with the spin ball, the spin ball bottom is fixed to be provided with the connecting rod, the notch has been seted up on the mount pad, the notch is extended to the connecting rod bottom and is fixedly provided with the sleeve, the fixed bradyseism gasbag that is provided with of notch inner wall, the connecting rod runs through bradyseism gasbag, the fixed spring that is provided with in sleeve inboard top, spring bottom mounting is provided with the pillar, the sleeve is extended and is fixedly provided with the camera to the pillar bottom, fixed cover is equipped with the damping fin on the pillar, the damping fin contacts with the sleeve inside wall.

Preferably, a rotating groove is formed in the inner side of the mounting seat, and the rotating groove is matched with the rotating ball.

Preferably, the cushioning air bag is of an annular structure, and the cushioning air bag is sleeved outside the connecting rod.

Preferably, a plurality of damping fins are provided, and the plurality of damping fins are uniformly distributed.

Preferably, the camera front is provided with a camera, and the camera front is provided with LED lamps at two sides of the camera.

Preferably, two landing gears are fixedly arranged at the bottom of the machine body, and the two landing gears are symmetrically arranged.

Preferably, the top of the machine body is fixedly provided with a heat dissipation panel.

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

1. When the camera receives transverse vibration, the camera drives the support column and the sleeve to swing, the sleeve drives the connecting rod to move, and the connecting rod can drive the rotating ball to rotate, so that the connecting rod extrudes the cushioning air bag, absorbs vibration through the cushioning air bag, achieves cushioning, avoids the camera from shaking as much as possible, and accordingly shooting effect and quality are guaranteed, and the influence on the service life of the camera is avoided.

2. When the camera receives longitudinal vibration, the camera drives the support column to move upwards, the support column can upwards extrude the spring to buffer, simultaneously the support column drives a plurality of damping fins to carry out friction contact with the inner side wall of the sleeve, the longitudinal vibration is absorbed by the plurality of damping fins, the damping is realized, the camera is prevented from shaking as much as possible, the shooting effect and the quality are guaranteed, and the influence on the service life of the camera is avoided.

Drawings

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a schematic view of the structure of the present utility model from another view;

FIG. 3 is a schematic view of the present utility model in partial cross-section.

In the figure: 1. a body; 2. a holder main body; 3. a mounting base; 4. a rotating ball; 5. a connecting rod; 6. a notch; 7. a sleeve; 8. a shock absorbing air bag; 9. a spring; 10. a support post; 11. a camera; 12. a damping sheet; 13. a rotating groove; 14. a camera; 15. an LED lamp; 16. landing gear; 17. a heat dissipating panel.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments.

Referring to fig. 1-3, an unmanned aerial vehicle camera tripod head shock-absorbing structure comprises a machine body 1, wherein a tripod head main body 2 is fixedly arranged at the bottom of the machine body 1, a mounting seat 3 is fixedly arranged at the bottom of the tripod head main body 2, a rotating ball 4 is rotatably arranged on the inner side of the mounting seat 3, a rotating groove 13 is formed in the inner side of the mounting seat 3, and the rotating groove 13 is matched with the rotating ball 4. The fixed connecting rod 5 that is provided with in ball 4 bottom, set up notch 6 on the mount pad 3, notch 6 is extended to connecting rod 5 bottom and fixed being provided with sleeve 7, and notch 6 inner wall is fixed to be provided with the shock-absorbing gasbag 8, and connecting rod 5 runs through shock-absorbing gasbag 8, and shock-absorbing gasbag 8 is annular structure, and shock-absorbing gasbag 8 cover is established in the connecting rod 5 outside

During the use, through the normal running fit of ball 4 and rotary groove 13, make connecting rod 5 can carry out universal rotation, when receiving horizontal vibrations, connecting rod 5 can drive ball 4 and rotate, makes connecting rod 5 extrusion bradyseism gasbag 8, absorbs vibrations through bradyseism gasbag 8, realizes the bradyseism.

In addition, the top of the machine body 1 is fixedly provided with a heat dissipation panel 17, and heat dissipation of the machine body 1 is accelerated through the heat dissipation panel 17, so that the service life of the machine body 1 is prolonged.

Further, the top of the inner side of the sleeve 7 is fixedly provided with a spring 9, the bottom end of the spring 9 is fixedly provided with a support post 10, the bottom end of the support post 10 extends out of the sleeve 7 and is fixedly provided with a camera 11, a damping fin 12 is fixedly sleeved on the support post 10, and the damping fin 12 is in contact with the inner side wall of the sleeve 7. The damping fin 12 is provided with a plurality of, and a plurality of damping fins 12 are evenly distributed.

When in use, when receiving longitudinal vibration, the strut 10 can upwards extrude the spring 9 to buffer, and simultaneously the strut 10 drives a plurality of damping fins 12 to be in friction contact with the inner side wall of the sleeve 7, and the longitudinal vibration is absorbed by the damping fins 12, so that the damping effect is realized.

In addition, camera 11 openly is provided with camera 14, and camera 11 openly is located the both sides of camera 14 and is provided with LED lamp 15, carries out the view finding through camera 14 and shoots, provides light through LED lamp 15.

Finally, two landing gears 16 are fixedly arranged at the bottom of the machine body 1, the two landing gears 16 are symmetrically arranged, and the machine body 1 is convenient to support in the lifting process through the two landing gears 16.

The principle of operation of the present utility model will now be described as follows: the camera 11 is arranged at the bottom of the holder main body 2, is used for framing shooting through the camera 14, provides light through the LED lamp 15, and when the camera 11 is subjected to transverse vibration, the camera 11 drives the support column 10 and the sleeve 7 to swing, the sleeve 7 drives the connecting rod 5 to move, the connecting rod 5 drives the rotating ball 4 to rotate, the connecting rod 5 extrudes the cushioning air bag 8, the cushioning air bag 8 is used for absorbing vibration, cushioning is realized, the camera 11 is prevented from shaking as far as possible, so that shooting effect and quality are ensured, and the influence on the service life of the camera 11 is avoided;

When the camera 11 receives vertical vibrations, the camera 11 drives pillar 10 and upwards moves, and pillar 10 can upwards extrude spring 9, cushions, and pillar 10 drives a plurality of damping fin 12 and sleeve 7 inside wall simultaneously and carries out frictional contact, utilizes a plurality of damping fin 12 to absorb vertical vibrations, realizes the bradyseism, avoids camera 11 to take place to rock as far as possible to guarantee shooting effect and quality, also avoid causing the influence to the life-span of camera 11.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (7)

1. The utility model provides an unmanned aerial vehicle camera cloud platform shock absorber structure, includes organism (1), a serial communication port, organism (1) bottom is fixed to be provided with cloud platform main part (2), cloud platform main part (2) bottom is fixed to be provided with mount pad (3), mount pad (3) inboard rotates and is provided with swivel ball (4), swivel ball (4) bottom is fixed to be provided with connecting rod (5), notch (6) have been seted up on mount pad (3), notch (6) and fixed sleeve (7) that are provided with are extended to connecting rod (5) bottom, notch (6) inner wall is fixed to be provided with bradyseism gasbag (8), connecting rod (5) run through bradyseism gasbag (8), the fixed spring (9) that is provided with in sleeve (7) inboard top, spring (9) bottom fixed pillar (10) are provided with, sleeve (7) and fixed being provided with camera (11) are extended to pillar (10) bottom, fixed cover is equipped with damping piece (12) on pillar (10) and sleeve (7) inside wall contact.

2. The unmanned aerial vehicle camera tripod head shock absorbing structure according to claim 1, wherein a rotating groove (13) is formed in the inner side of the mounting seat (3), and the rotating groove (13) is matched with the rotating ball (4).

3. The unmanned aerial vehicle camera pan-tilt shock absorbing structure according to claim 1, wherein the shock absorbing air bag (8) is of an annular structure, and the shock absorbing air bag (8) is sleeved outside the connecting rod (5).

4. The unmanned aerial vehicle camera pan-tilt shock absorbing structure according to claim 1, wherein a plurality of damping fins (12) are provided, and a plurality of damping fins (12) are uniformly distributed.

5. The unmanned aerial vehicle camera pan-tilt shock absorbing structure according to claim 1, wherein the front face of the camera (11) is provided with a camera (14), and the front face of the camera (11) is provided with LED lamps (15) at two sides of the camera (14).

6. The unmanned aerial vehicle camera cradle head shock absorbing structure according to claim 1, wherein two landing gears (16) are fixedly arranged at the bottom of the machine body (1), and the two landing gears (16) are symmetrically arranged.

7. The unmanned aerial vehicle camera tripod head shock absorbing structure according to claim 1, wherein a heat radiating panel (17) is fixedly arranged at the top of the machine body (1).