CN220263148U - Unmanned aerial vehicle cabinet body structure that charges - Google Patents

Abstract

The utility model relates to an unmanned aerial vehicle charging cabinet structure, which comprises a cabinet body, wherein the cabinet body is divided into a battery charging bin and a battery storage bin which are arranged up and down; the battery charging bin is internally provided with a bracket, the upper surface of the bracket is of a step structure, the upper surface of a step in the step structure is provided with a charging slot, and the charging slot is internally used for being clamped with a plurality of battery chargers arranged along the length direction of the battery charger; the bracket is of a step structure, a row of chargers are arranged on each step, and the height difference exists between the steps, so that the battery can be taken out from the bracket conveniently. Meanwhile, a plurality of rows of battery chargers distributed in a stepped mode are beneficial to monitoring the batteries/battery chargers from multiple angles by the camera, and the situation that only one surface can be observed by the battery chargers in a planar arrangement is avoided.

Description

Unmanned aerial vehicle cabinet body structure that charges

Technical Field

The utility model relates to an unmanned aerial vehicle charging cabinet structure, and belongs to the technical field of charging cabinets.

Background

The electric line inspection unmanned aerial vehicle is used for checking power grid lines, and the line inspection unmanned aerial vehicle is powered by a rechargeable battery; the existing charger can only charge a single line inspection unmanned aerial vehicle battery, and is low in efficiency. The electric power inspection unmanned aerial vehicle has multiple models, and the electric power inspection unmanned aerial vehicle battery of various models is also different.

Therefore, a charging cabinet for an unmanned aerial vehicle, such as the chinese patent with publication number CN216488290U, is presented, however, a plurality of batteries are distributed on the same plane, which is not only unfavorable for taking out, but also unfavorable for real-time camera monitoring.

Disclosure of Invention

The utility model aims to provide an unmanned aerial vehicle charging cabinet structure so as to solve the problems in the background technology.

The technical scheme of the utility model is as follows:

an unmanned aerial vehicle cabinet body structure that charges includes:

the cabinet body is divided into a battery charging bin and a battery storage bin which are arranged up and down;

the battery charging bin is internally provided with a bracket, the bracket is of a stepped structure, the upper surface of a step in the stepped structure is provided with a charging slot, and the charging slot is internally used for being connected with a plurality of battery chargers arranged along the length direction of the battery charger in a clamping manner.

Preferably, a camera, a smoke alarm and a temperature sensor are arranged on the inner top wall of the battery charging bin.

Preferably, the battery storage bin adopts a drawer type structure.

Preferably, an inner sinking push-pull groove is formed in the outer bin plate of the battery storage bin.

Preferably, the bottom of the cabinet body is provided with a movable wheel.

Preferably, the bracket is installed in the battery charging bin by adopting a drawer type structure, and the bracket is driven to enter and exit the side wall opening of the battery charging bin through the transverse moving assembly.

Preferably, a cabinet door made of transparent materials is arranged at the opening of the side wall of the battery charging bin, and a warning lamp is arranged on the cabinet door.

Preferably, the battery charger bin is further provided with a sunk replacement slot, and the replacement slot is used for clamping the battery charger.

The utility model has the following beneficial effects:

the bracket is of a step structure, a row of chargers are arranged on each step, and the height difference exists between the steps, so that the battery can be taken out from the bracket conveniently. Meanwhile, a plurality of rows of battery chargers distributed in a stepped mode are beneficial to monitoring the batteries/battery chargers from multiple angles by the camera, avoiding shielding of the batteries/battery chargers in the rear row and avoiding that the battery chargers in the plane arrangement can only observe one surface.

Drawings

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

FIG. 2 is a schematic view of the structure of the utility model with the cabinet door removed and the battery storage compartment pulled out;

FIG. 3 is another schematic view of FIG. 2;

FIG. 4 is a schematic view of the structure of the bracket and its mating parts according to the present utility model;

FIG. 5 is another schematic view of FIG. 4;

fig. 6 is a schematic view of the battery storage compartment structure of the present utility model.

The reference numerals in the drawings are as follows:

1. a cabinet body; 11. a heat radiation hole; 2. a battery storage bin; 21. a push-pull groove; 3. a battery charging bin; 31. a cabinet door; 32. a warning light; 4. a touch screen; 6. a moving wheel; 7. a camera; 8. replacing the groove position; 81. a rear cover; 9. a bracket; 91. charging slot; 92. and traversing the assembly.

Detailed Description

The utility model will now be described in detail with reference to the drawings and to specific embodiments.

Examples: as shown in fig. 1-6:

unmanned aerial vehicle has multiple model, and the unmanned aerial vehicle battery of various models is different.

The upper portion of the cabinet body 1 is fixedly provided with a battery charging bin 3, the front wall of the battery charging bin 3 is opened or closed through a hinged cabinet door 31, the cabinet door 31 is made of transparent materials, the inside condition of the battery charging bin 3 can be observed, a warning lamp 32 (such as a tri-color lamp) is arranged on the cabinet door 31, a bracket 9 of a drawer type structure is arranged on the inner bottom wall of the battery charging bin 3, and the bracket 9 drives a linear movement to enter and exit the front wall of the battery charging bin 3 through a transverse moving assembly 92 (screw transmission module).

The upper surface of the bracket 9 is formed into a stepped structure by three rows of steps, a charging slot 91 is formed in the upper surface of each step along the length direction of the step, a plurality of battery chargers arranged in a straight shape can be clamped on one charging slot 91, charging pins are arranged in the bracket 9, and the battery chargers are electrically connected with the corresponding charging pins when inserted into the bracket 9. Thereby realizing the installation of three rows of battery chargers distributed in a stepwise manner on the bracket 9.

The camera 7, smoke alarm and temperature-sensing ware are installed to roof in the battery charging storehouse 3, and camera 7 is towards bracket 9 upper surface, monitors the battery in charging through camera 7, and three rows of battery charger of ladder distribution are favorable to the control of camera 7, avoid two rows of battery charger at the back to be sheltered from by the battery charger of first row. The smoke alarm and the temperature sensor are used for monitoring the smoke and the temperature state in the battery charging bin 3.

The touch screen 4 is installed on cabinet body 1 upper portion, and touch screen 4 is connected with each battery charger electricity, and the battery sweeps a yard and charges, and information such as real-time voltage, electric current, temperature, electric quantity, the number of times of charging of every battery are shown to touch screen 4.

As shown in fig. 3, a battery charger bin is disposed on the rear side wall of the cabinet body 1, an opening of the battery charger bin is closed by a rear cover 81, a plurality of replacement slots 8 distributed in array are formed in the battery charger bin, an elastic layer is disposed on the inner side wall of each of the replacement slots 8, battery chargers are inserted into the replacement slots 8 through the elastic layer, and battery chargers of other types which are temporarily unused are inserted into the replacement slots 8. The charging contacts of the battery chargers of different models are uniformly designed and are used for being matched with the charging pins in the bracket 9.

The lower part of the cabinet body 1 is provided with a battery storage bin 2, the battery storage bin 2 is movably arranged at the lower part of the cabinet body 1 by adopting a drawer type structure, a push-pull groove 21 is formed in the outer side of the battery storage bin 2, fingers are inserted into the push-pull groove 21 to conveniently push and pull the battery storage bin 2, and the battery storage bin 2 is used for storing a battery which is charged/to be charged.

The bottom of the cabinet body 1 is provided with a moving wheel 6 which is convenient for the movement of the cabinet body 1. The left and right side walls of the cabinet body 1 are provided with heat dissipation holes 11 and are matched with fans to facilitate air cooling of batteries in the battery storage bin 2 and the battery charging bin 3.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. Unmanned aerial vehicle cabinet body structure that charges, its characterized in that: comprising the following steps:

the battery storage cabinet comprises a cabinet body (1), wherein the cabinet body (1) is divided into a battery charging bin (3) and a battery storage bin (2) which are arranged up and down;

a bracket (9) is arranged in the battery charging bin (3), the bracket (9) is of a step structure, a charging slot (91) is formed in the upper surface of a step in the step structure, and a plurality of battery chargers arranged along the length direction of the battery charger are connected in the charging slot (91) in a clamping mode;

the bracket (9) is installed in the battery charging bin (3) by adopting a drawer type structure, and the bracket (9) drives the side wall opening of the battery charging bin (3) to enter and exit through the transverse moving assembly (92).

2. The unmanned aerial vehicle charging cabinet structure of claim 1, wherein: the inner top wall of the battery charging bin (3) is provided with a camera (7), a smoke alarm and a temperature sensor.

3. The unmanned aerial vehicle charging cabinet structure of claim 1, wherein: the battery storage bin (2) adopts a drawer type structure.

4. A drone charging cabinet structure as claimed in claim 3, wherein: an inner sinking push-pull groove (21) is formed in the outer side bin plate of the battery storage bin (2).

5. The unmanned aerial vehicle charging cabinet structure of claim 1, wherein: the bottom of the cabinet body (1) is provided with a movable wheel (6).

6. The unmanned aerial vehicle charging cabinet structure of claim 1, wherein: the battery charging bin is characterized in that a cabinet door (31) made of transparent materials is arranged at the opening of the side wall of the battery charging bin (3), and a warning lamp (32) is arranged on the cabinet door (31).

7. The unmanned aerial vehicle charging cabinet structure of claim 1, wherein: the battery charger bin is internally provided with an inner sinking replacement slot (8), and the replacement slot (8) is internally used for clamping the battery charger.