CN219584487U - Unmanned aerial vehicle cloud platform mounting structure that makes a video recording - Google Patents

Abstract

The utility model belongs to the technical field of unmanned aerial vehicles, and particularly relates to an unmanned aerial vehicle camera shooting holder mounting structure, which comprises an unmanned aerial vehicle body and a camera shooting holder, wherein the camera shooting holder is arranged at the bottom of the unmanned aerial vehicle body, the bottom end of the unmanned aerial vehicle body is fixedly connected with a mounting seat, the top end of the camera shooting holder is fixedly connected with a docking mechanism for mounting the camera shooting holder on the mounting seat, the docking mechanism is connected with the mounting seat in a clamping way, the bottom end of the unmanned aerial vehicle body is fixedly connected with a limiting mechanism for limiting the position of the mounting seat, and the limiting mechanism is arranged on the periphery of the unmanned aerial vehicle body. According to the utility model, the camera shooting holder is detachably arranged on the mounting seat through the docking mechanism, the docking mechanism can be automatically limited and fixed by the time limiting mechanism during installation, the docking mechanism is prevented from being separated from the mounting seat, the camera shooting holder is convenient to disassemble and assemble, the camera shooting holders with different configurations can be replaced according to requirements when the unmanned aerial vehicle executes tasks, and the practicability of the unmanned aerial vehicle is improved.

Description

Unmanned aerial vehicle cloud platform mounting structure that makes a video recording

Technical Field

The utility model belongs to the technical field of unmanned aerial vehicles, and particularly relates to an unmanned aerial vehicle camera tripod head mounting structure.

Background

The unmanned aerial vehicle is applied in the fields of aerial photography, agriculture, plant protection, express delivery transportation, disaster relief, observation of wild animals, mapping, news report, electric power inspection, disaster relief, film and television shooting, and the like, the application of the unmanned aerial vehicle is greatly expanded, and the camera cradle head is a key component of the unmanned aerial vehicle for installing and fixing a camera structure.

The unmanned aerial vehicle is according to its manufacturing cost configuration corresponding cloud platform and camera of making a video recording when producing, its cloud platform of making a video recording is generally fixed mounting on unmanned aerial vehicle, is difficult to disassemble, and that is to say an unmanned aerial vehicle leaves the factory after, and its configuration of making a video recording can't change promptly, and unmanned aerial vehicle is when carrying out the task, often needs to adopt the camera device of different configurations and even needs relative professional camera device according to the difference of task and task environment, and the cloud platform of making a video recording that unmanned aerial vehicle self was equipped just so can't satisfy the demand.

Disclosure of Invention

The utility model aims to provide an unmanned aerial vehicle camera shooting holder mounting structure which is convenient for dismounting camera shooting holders, and when a task is executed, camera shooting holders with different configurations can be replaced according to requirements so as to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an unmanned aerial vehicle cloud platform mounting structure that makes a video recording, includes unmanned aerial vehicle body and camera cloud platform, camera cloud platform sets up the bottom at unmanned aerial vehicle body, unmanned aerial vehicle body's bottom fixedly connected with mount pad, camera cloud platform's top fixedly connected with is used for installing the docking mechanism on the mount pad with camera cloud platform, docking mechanism is connected with the mount pad block, unmanned aerial vehicle body's bottom fixedly connected with is used for restricting the stop gear of mount pad position, stop gear sets up the periphery at unmanned aerial vehicle body.

Further, the butt joint mechanism comprises a plug column fixedly connected to the top end of the camera cradle head, the side wall of the plug column is fixedly connected with connecting strips which are distributed around the axis of the plug column at equal intervals, and one side of each connecting strip is fixedly connected with a fan-shaped bearing plate.

Further, the top of the inserted column is provided with arranging grooves which are distributed around the axis of the inserted column at equal intervals, and the inside of each arranging groove is fixedly connected with an elastic metal sheet.

Further, the mount pad includes the erection shield of fixed connection in unmanned aerial vehicle body bottom, the spliced pole is pegged graft in the inside of erection shield, the bottom fixedly connected with of erection shield is around the arc arch of erection shield axle center equidistance distribution, the bellied lateral wall fixedly connected with of arc is used for supporting the fan-shaped layer board of corresponding fan-shaped bearing plate, adjacent two for the passageway that supplies corresponding fan-shaped bearing plate to pass between the fan-shaped layer board.

Further, electric connection column heads which are distributed around the axis of the installation cover at equal intervals are embedded in the top end of the installation cover, the electric connection column heads are in contact connection with corresponding elastic metal sheets, the elastic metal sheets are electrically connected with the camera cradle head, and the electric connection column heads are electrically connected with the unmanned aerial vehicle.

Further, stop gear includes fixed connection at the annular disc of unmanned aerial vehicle body bottom, annular disc cover is established in the outside of installing the cover, the inside swing joint of annular disc has the ring, the bottom fixedly connected with of ring is around the spacer pin of ring axis equidistance distribution, the logical groove around annular disc axis equidistance distribution is seted up to the bottom of annular disc, a plurality of the spacer pin runs through respectively a plurality of logical groove, logical groove block connects in one side of corresponding connecting strip.

Further, the top of ring has seted up the recess that distributes around the equal distance of ring axis, the inside fixedly connected with spring of recess, the top of spring and the bottom fixed connection of unmanned aerial vehicle body.

Compared with the prior art, the utility model has the beneficial effects that: the camera cradle head is detachably mounted on the mounting seat through the docking mechanism, the docking mechanism can be automatically limited and fixed by the time limit mechanism in mounting, the docking mechanism is prevented from being separated from the mounting seat, the camera cradle head is convenient to disassemble and assemble, the camera cradle head of different configurations can be replaced according to requirements when the unmanned aerial vehicle is used for executing tasks, and the practicability of the unmanned aerial vehicle is improved.

Drawings

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

FIG. 2 is a schematic view of the mating structure of the docking mechanism and mount of the present utility model;

FIG. 3 is an exploded view of the docking mechanism, mount and spacing mechanism of the present utility model;

FIG. 4 is an enlarged schematic view of the portion A of FIG. 3 according to the present utility model;

fig. 5 is a schematic perspective view of a limiting mechanism according to the present utility model.

In the drawings, the list of components represented by the various numbers is as follows:

1. an unmanned body; 2. a camera cradle head; 3. a docking mechanism; 31. inserting a column; 32. a connecting strip; 33. a fan-shaped bearing plate; 34. a placement groove; 35. an elastic metal sheet; 4. a mounting base; 41. a mounting cover; 42. arc-shaped bulges; 43. a fan-shaped supporting plate; 44. an electrical connection stud; 5. a limiting mechanism; 51. an annular disc; 52. a circular ring; 53. a limiting pin; 54. a spring; 55. a groove; 56. and (5) through grooves.

Detailed Description

The present utility model will be specifically described with reference to examples below in order to make the objects and advantages of the present utility model more apparent. It should be understood that the following text is intended to describe only one or more specific embodiments of the utility model and does not limit the scope of the utility model strictly as claimed.

As shown in fig. 1 and 3, an unmanned aerial vehicle camera shooting cloud platform mounting structure, including unmanned aerial vehicle body 1 and camera shooting cloud platform 2, camera shooting cloud platform 2 sets up in the bottom of unmanned aerial vehicle body 1, the bottom fixedly connected with mount pad 4 of unmanned aerial vehicle body 1, the top fixedly connected with of camera shooting cloud platform 2 is used for installing the docking mechanism 3 on mount pad 4 with camera shooting cloud platform 2, docking mechanism 3 is connected with mount pad 4 block, the bottom fixedly connected with of unmanned aerial vehicle body 1 is used for restricting the stop gear 5 in mount pad 4 positions, stop gear 5 sets up the periphery at unmanned aerial vehicle body 1.

According to the structure, when the camera cradle head 2 is installed, the docking mechanism 3 at the top end of the camera cradle head 2 is connected to the mounting seat 4 in a clamping manner, and then the docking mechanism 3 can be automatically limited and fixed by the limiting mechanism 5, so that the camera cradle head 2 is prevented from falling off due to the separation of the docking mechanism 3 and the mounting seat 4.

As shown in fig. 2, 3 and 4, the docking mechanism 3 includes a post 31 fixedly connected to the top of the camera tripod head 2, a connecting strip 32 fixedly connected to the side wall of the post 31 and distributed equidistantly around the axis of the post 31, a fan-shaped bearing plate 33 fixedly connected to one side of the connecting strip 32, a placement groove 34 equidistantly distributed around the axis of the post 31 and formed in the top of the post 31, an elastic metal sheet 35 fixedly connected to the inside of the placement groove 34, a mounting seat 4 including a mounting cover 41 fixedly connected to the bottom of the unmanned aerial vehicle body 1, the post 31 inserted into the mounting cover 41, an arc-shaped protrusion 42 fixedly connected to the bottom of the mounting cover 41 and distributed equidistantly around the axis of the mounting cover 41, and a fan-shaped supporting plate 43 fixedly connected to the side wall of the arc-shaped protrusion 42 and used for supporting the corresponding fan-shaped bearing plate 33, and a channel between two adjacent fan-shaped supporting plates 43 for the corresponding fan-shaped bearing plates 33 to pass through.

According to the above configuration, when the camera head 2 is mounted, the post 31 is inserted into the mounting cover 41, the fan-shaped bearing plate 33 is passed through the corresponding two fan-shaped supporting plates 43, and then the post 31 is rotated by a certain angle, the fan-shaped bearing plate 33 is rotated to the upper side of the corresponding fan-shaped supporting plate 43, and the fan-shaped supporting plate 43 is used for supporting the fan-shaped bearing plate 33, so that the camera head 2 is hoisted under the unmanned aerial vehicle body 1.

As shown in fig. 3 and 4, the top end of the mounting cover 41 is embedded with electric connection studs 44 distributed equidistantly around the axis of the mounting cover 41, the electric connection studs 44 are in contact connection with the corresponding elastic metal sheets 35, the elastic metal sheets 35 are electrically connected with the camera head 2, and the electric connection studs 44 are electrically connected with the unmanned aerial vehicle body 1.

According to the above structure, after the insert column 31 rotates in place, the top ends of the plurality of elastic metal sheets 35 are respectively contacted with the bottom ends of the plurality of electric connection column heads 44, so that the electric connection between the camera cradle head 2 and the unmanned aerial vehicle body 1 is realized, and since the elastic metal sheets 35 have elasticity, the elastic metal sheets 35 are extruded after the insert column 31 is inserted in place, the connection between the elastic metal sheets 35 and the electric connection column heads 44 is tighter, and poor contact is avoided.

As shown in fig. 3 and 5, the limiting mechanism 5 includes an annular disc 51 fixedly connected to the bottom end of the unmanned aerial vehicle body 1, the annular disc 51 is sleeved outside the mounting cover 41, an annular ring 52 is movably connected to the inside of the annular disc 51, limiting pins 53 distributed around the axis of the annular ring 52 are fixedly connected to the bottom end of the annular disc 52, through grooves 56 distributed around the axis of the annular disc 51 are formed in the bottom end of the annular disc 51, a plurality of limiting pins 53 penetrate through the through grooves 56 respectively, the through grooves 56 are clamped and connected to one side of the corresponding connecting strip 32, grooves 55 distributed around the axis of the annular ring 52 are formed in the top end of the annular disc 52, springs 54 are fixedly connected to the inside of the grooves 55, and the top ends of the springs 54 are fixedly connected with the bottom end of the unmanned aerial vehicle body 1.

According to the structure, the inserting column 31 is upwards extruded with the limiting pin 53 in the inserting process, the limiting pin 53 is retracted, after the fan-shaped bearing plate 33 rotates in place, the limiting pin 53 is ejected to prop against one side of the corresponding connecting strip 32 under the action of the spring 54, so that the inserting column 31 can be prevented from reversely rotating, and further the falling off of the shooting cloud deck 2 is avoided, when the shooting cloud deck 2 is dismounted, the limiting pin 53 is pushed back inwards, the reversely rotating inserting column 31 enables the fan-shaped bearing plate 33 to correspond to a channel between the corresponding two fan-shaped supporting plates 43, then the shooting cloud deck 2 can be dismounted by pulling down the shooting cloud deck 2, and the shooting cloud deck 2 is convenient to dismount.

The working principle of the utility model is as follows: when the camera holder 2 is installed, the inserting columns 31 are inserted into the installation cover 41, the fan-shaped bearing plates 33 penetrate through the corresponding two fan-shaped supporting plates 43, then the inserting columns 31 are rotated by a certain angle, the fan-shaped bearing plates 33 are rotated to the upper parts of the corresponding fan-shaped supporting plates 43, the fan-shaped supporting plates 43 are used for supporting the fan-shaped bearing plates 33, so that the camera holder 2 is hoisted below the unmanned aerial vehicle body 1, the inserting columns 31 upwards squeeze the limiting pins 53 in the inserting process, the limiting pins 53 retract, the top ends of the plurality of elastic metal sheets 35 are respectively contacted with the bottom ends of the plurality of electric connection column heads 44 after the inserting columns 31 are rotated in place, so that the camera holder 2 is electrically connected with the unmanned aerial vehicle body 1, the elastic metal sheets 35 are extruded after the inserting columns 31 are inserted in place, the elastic metal sheets 35 are connected with the electric connection column heads 44 more tightly, poor contact is avoided, the limiting pins 53 are ejected and abutted against one side of the corresponding connecting strips 32 under the action of the springs 54 after the fan-shaped bearing plates 33 are rotated in place, the opposite rotation of the fan-shaped bearing plates 33, the camera holder 2 can be prevented from falling down, and the opposite rotation of the corresponding fan-shaped bearing plates 2 can be dismounted, and the camera holder 2 can be dismounted, and the opposite to the corresponding supporting plates 2 can be dismounted, and the camera holder 2 can be conveniently, and the opposite to the camera holder 2 can be dismounted.

The foregoing is merely a preferred embodiment of the present utility model and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present utility model, which are intended to be comprehended within the scope of the present utility model. Structures, devices and methods of operation not specifically described and illustrated herein, unless otherwise indicated and limited, are implemented according to conventional means in the art.

Claims (7)

1. The utility model provides an unmanned aerial vehicle cloud platform mounting structure of making a video recording, includes unmanned aerial vehicle body (1) and makes a video recording cloud platform (2), make a video recording cloud platform (2) setting in the bottom of unmanned aerial vehicle body (1), its characterized in that: the camera shooting device comprises an unmanned aerial vehicle body (1), and is characterized in that an installing seat (4) is fixedly connected to the bottom end of the unmanned aerial vehicle body (1), a docking mechanism (3) used for installing the camera shooting cloud deck (2) on the installing seat (4) is fixedly connected to the top end of the camera shooting cloud deck (2), the docking mechanism (3) is connected with the installing seat (4) in a clamping mode, a limiting mechanism (5) used for limiting the position of the installing seat (4) is fixedly connected to the bottom end of the unmanned aerial vehicle body (1), and the limiting mechanism (5) is arranged on the periphery of the unmanned aerial vehicle body (1).

2. The unmanned aerial vehicle camera cradle head mounting structure according to claim 1, wherein: the butt joint mechanism (3) comprises a plug post (31) fixedly connected to the top end of the camera cradle head (2), connecting strips (32) which are distributed around the axis of the plug post (31) at equal intervals are fixedly connected to the side wall of the plug post (31), and a fan-shaped bearing plate (33) is fixedly connected to one side of each connecting strip (32).

3. The unmanned aerial vehicle camera cradle head mounting structure according to claim 2, wherein: the top of inserted post (31) has seted up around the setting groove (34) of inserted post (31) axis equidistance distribution, the inside fixedly connected with elasticity sheetmetal (35) of setting groove (34).

4. The unmanned aerial vehicle camera cradle head mounting structure according to claim 3, wherein: the installation seat (4) comprises an installation cover (41) fixedly connected to the bottom end of the unmanned aerial vehicle body (1), the inserting columns (31) are inserted into the installation cover (41), arc-shaped protrusions (42) which are distributed around the axis of the installation cover (41) at equal intervals are fixedly connected to the bottom end of the installation cover (41), fan-shaped supporting plates (43) used for supporting corresponding fan-shaped supporting plates (33) are fixedly connected to the side walls of the arc-shaped protrusions (42), and channels for the corresponding fan-shaped supporting plates (33) to pass through are formed between every two adjacent fan-shaped supporting plates (43).

5. The unmanned aerial vehicle camera cradle head mounting structure according to claim 4, wherein: the top of the mounting cover (41) is embedded with electric connection column heads (44) which are distributed around the axis of the mounting cover (41) at equal intervals, the electric connection column heads (44) are in contact connection with corresponding elastic metal sheets (35), the elastic metal sheets (35) are electrically connected with the camera cradle head (2), and the electric connection column heads (44) are electrically connected with the unmanned aerial vehicle body (1).

6. The unmanned aerial vehicle camera cradle head mounting structure according to claim 5, wherein: stop gear (5) are including fixed connection in annular disc (51) of unmanned aerial vehicle body (1) bottom, the outside at installing cover (41) is established to annular disc (51) cover, the inside swing joint of annular disc (51) has ring (52), the bottom fixedly connected with of ring (52) is around spacer pin (53) of ring (52) axis equidistance distribution, logical groove (56) around annular disc (51) axis equidistance distribution are seted up to the bottom of annular disc (51), a plurality of spacer pin (53) run through a plurality of respectively logical groove (56), one side at corresponding connecting strip (32) is connected in logical groove (56) block.

7. The unmanned aerial vehicle camera cradle head mounting structure according to claim 6, wherein: the novel unmanned aerial vehicle is characterized in that grooves (55) which are distributed around the axis of the circular ring (52) at equal intervals are formed in the top end of the circular ring (52), springs (54) are fixedly connected inside the grooves (55), and the top ends of the springs (54) are fixedly connected with the bottom end of the unmanned aerial vehicle body (1).