CN219339733U - Photovoltaic power plant inspection device - Google Patents

Abstract

The utility model relates to the technical field of photovoltaic power station inspection, in particular to a photovoltaic power station inspection device which comprises an inspection unmanned plane and a charging station. Be equipped with solar cell panel on the unmanned aerial vehicle that patrols and examines, charge unmanned aerial vehicle through solar energy at the in-process of patrolling and examining, help prolonging the time of cruising, when unmanned aerial vehicle descends, through the impact force when buffering stabilizer blade buffering descends, do benefit to the protection to inside electronic component, extension unmanned aerial vehicle's life to concentrate in charging station after cruising, be convenient for patrol and examine unmanned aerial vehicle's management. According to the utility model, the impact force generated when the unmanned aerial vehicle falls can be buffered by the buffering support leg below the unmanned aerial vehicle wing, the service life of the unmanned aerial vehicle is effectively prolonged, the unmanned aerial vehicle is matched with the storage battery and the solar photovoltaic panel, the inspection time of the unmanned aerial vehicle can be prolonged, the equipment cost is reduced, meanwhile, the unmanned aerial vehicle is charged by the charging station, the charging is more conditioned and attractive, and the management of the unmanned aerial vehicle is facilitated.

Description

Photovoltaic power plant inspection device

Technical Field

The utility model relates to the technical field of photovoltaic power station inspection, in particular to a photovoltaic power station inspection device.

Background

The photovoltaic power station is a power generation system which is formed by utilizing solar energy and adopting special materials such as a crystalline silicon plate, an inverter and other electronic elements, is connected with a power grid and transmits power to the power grid.

Photovoltaic power stations tend to be remote in location, numerous in equipment and wide in distribution range. Due to the specificity of the photovoltaic power generation industry, once equipment failure occurs, direct property loss and potential safety hazards are caused. In order to maintain the stable and safe operation of the photovoltaic power station, regular inspection is required.

The traditional manual inspection method has the problems of low efficiency, high error rate, long inspection time and the like; with the development of technology, the use of civilian and commercial unmanned aerial vehicles has steadily grown. The unmanned aerial vehicle is applied to the photovoltaic power station inspection process, and has the advantages of being high in maneuverability, saving labor cost, improving inspection frequency and the like, but the corresponding photovoltaic power station inspection device is inconvenient in that on one hand, the photovoltaic power station is extremely large in occupied area, the unmanned aerial vehicle inspection device is limited by electric quantity, and cannot be inspected at one time, a plurality of unmanned aerial vehicles inspection devices are required to be equipped at the moment, so that equipment cost is increased, on the other hand, when the number of unmanned aerial vehicles is increased, charging of the unmanned aerial vehicles is disordered, daily management and maintenance are inconvenient, and inconvenience is brought to use, so that the unmanned aerial vehicle inspection device can efficiently cruise for a long time, and after cruise is ended, charge management can be carried out orderly, and the photovoltaic power station inspection device is a problem to be solved in the prior art.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art, and provides a photovoltaic power station inspection device, so as to solve the problems that the existing inspection unmanned aerial vehicle has short duration in the use process, the equipment cost is increased, and when the inspection unmanned aerial vehicle has more equipment, the charging is disordered, and the use is inconvenient.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the utility model provides a photovoltaic power plant inspection device, includes unmanned aerial vehicle and charging station, unmanned aerial vehicle be provided with the wing in the both sides of organism, be provided with the motor on the wing and be connected with the screw, the organism front end is provided with infrared detector, infrared detector is connected with processing chip A, processing chip A is connected with signal transceiver, signal transceiver is connected with ground basic station, processing chip A is connected with controller A, controller A is connected with the motor, unmanned aerial vehicle inside is provided with the battery, the battery is connected with the terminal slot that charges of organism, set up the base plate in the charging station, base plate one end is provided with the canopy that charges, be provided with charging plug in the canopy that charges, charging plug cooperatees with the slot that charges.

Further, the machine body is hinged with the wing through a hinge part.

Further, the wing below be provided with the stabilizer blade, the cover foot is established to the outside cover of stabilizer blade, is provided with damping spring between the bottom of stabilizer blade and the cover foot.

Further, a plurality of charging areas are divided in the charging shed, and each charging area is provided with a corresponding charging plug.

Further, the control box is arranged behind the charging shed and connected with the power line, the power line is connected with the charging plugs in the charging areas, the charging indicator lamps are correspondingly arranged above the charging areas, the full-charge detector is arranged in the charging circuit in the control box and connected with the processing chip B, the processing chip B is connected with the controller B, and the controller B is respectively connected with the charging indicator lamps.

The utility model has the beneficial effects that: the unmanned aerial vehicle wing below buffering stabilizer blade of patrolling and examining can cushion the impact force when unmanned aerial vehicle falls, and the effectual extension patrols and examines unmanned aerial vehicle's life, patrols and examines unmanned aerial vehicle cooperation battery and solar photovoltaic board, can prolong unmanned aerial vehicle's time of patrolling and examining, has reduced equipment cost, adopts the charging station to charge unmanned aerial vehicle simultaneously, and the conditioning that charges is more pleasing to the eye, is convenient for patrol and examine unmanned aerial vehicle's management.

Drawings

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

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

FIG. 3 is a schematic view (front view) of the overall structure of the charging station of the present utility model;

fig. 4 is a schematic view (side view) of the whole structure of the charging station of the present utility model.

Name corresponding to each label in the figure:

1. unmanned plane; 11. a body; 111. an infrared detector; 112. a signal transceiver; 113. processing the chip A; 114. a storage battery; 115. a controller A; 116. a solar cell panel; 117. a charging slot; 12. a wing; 121. a propeller; 122. a motor; 123. a support leg; 124. sleeving feet; 125. a damping spring; 13. a hinge part; 2. a charging station; 21. a substrate; 22. a charging shed; 221. a charging area; 222. a charging plug; 223. a charge indicator light; 23. a control box; 231. a full charge detector; 232. processing the chip B; 233. a controller B; 234. and a power supply line.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art based on the embodiments of the present utility model are within the scope of protection of the present utility model.

Embodiments of the utility model:

as shown in fig. 1-2, in the present embodiment, an unmanned aerial vehicle 1 is provided with an engine body 11, the engine body 11 is connected with a wing 12 through a hinge 13, a motor 122 is installed on the wing 12, the motor 122 is connected with a propeller 121, a supporting foot 123 is fixedly connected below the wing 12, a sleeve foot 124 is sleeved outside the supporting foot 123, a damping spring 125 is arranged between the supporting foot 123 and the sleeve foot 124, an infrared detector 111 is arranged at the front end of the engine body 11, the infrared detector 111 is connected with a processing chip a113, the processing chip a113 is connected with a signal transceiver 112, and a signal transceiver 112 is arranged in the engine body 11 and connected with the processing chip a113, the processing chip a113 is connected with a controller a115, the controller a115 is connected with the motor 122, a charging slot 117 is also arranged in the engine body 11 and connected with a storage battery 114, and a solar panel 116 is arranged on the upper surface of the engine body 11 and connected with the storage battery 114.

As shown in fig. 3 to 4, a base plate 21 is provided in a charging station 2, a charging booth 22 is provided at one side of the base plate 21, a plurality of charging areas 221 are provided in the charging booth 22, a charging plug 222 is provided in each charging area 221, and a charging indicator lamp 223 is correspondingly provided above the charging area 221, a control box 23 is provided at the rear of the charging booth 22, the control box 23 is connected with a power line 234, the power line 234 is connected with the charging plug 222 in the charging area 221, and a full charge detector 231 is mounted in the charging line, the full charge detector 231 is connected with a processing chip B232, the processing chip B232 is connected with a controller B233, and the controller B233 is respectively connected with each charging indicator lamp 223

The principle of the utility model is as follows:

according to the utility model, the unmanned aerial vehicle 1 needs to be charged in the charging station 2 before being used, and the wings 12 of the unmanned aerial vehicle 1 can be folded through the hinge parts 13 during charging, so that the volume of the charging area 221 can be reduced, more charging areas 221 can be arranged for a charging shed 22 with a fixed size, the resource utilization rate can be improved, the charging condition of the unmanned aerial vehicle 1 can be judged through the charging indicator lamp 223 in the charging process of the unmanned aerial vehicle 1, and the charging indicator lamp 223 changes from red to green after the full charging detector 231 in the circuit detects that the unmanned aerial vehicle 1 is charged, so that the unmanned aerial vehicle 1 can work.

The unmanned aerial vehicle 1 after charging can carry out the work of patrolling and examining, control unmanned aerial vehicle flies in photovoltaic power plant within range in the course of working, with regard to unmanned aerial vehicle's control, be present more mature technique, adopt the remote controller control can, just need not be repeated here, unmanned aerial vehicle 1 is the in-process of patrolling and examining, infrared detector 111 that carries on it can detect unusual heat source, namely "hot spot", in-process infrared detector 111 collects the signal and passes through signal transceiver 112 after handling chip A113 with the signal and transmits the bottom surface, can observe the detection condition at ground control station (thermal imaging principle), when hot spot appears, it has appeared unusual to indicate this department, the timely maintenance of staff can.

The unmanned aerial vehicle 1 can charge the battery 114 through the solar cell panel 116 in the process of patrolling and examining, and solar cell panel 16 texture is lighter, can not increase unmanned aerial vehicle's loading, can prolong unmanned aerial vehicle and patrol and examine the time simultaneously, helps reducing the quantity of patrolling and examining unmanned aerial vehicle to reduce the cost of equipment.

Can control unmanned aerial vehicle 1 to descend near charging station 2 after unmanned aerial vehicle 1 patrols and examines, descending in-process buffering stabilizer blade 123 can reduce unmanned aerial vehicle 1 and descend the impact force of in-process, helps promoting the protection to inside electronic component, promotes unmanned aerial vehicle 1's life.

The unmanned aerial vehicle 1 after the inspection is finished is placed in the charging station 2 again to be charged, and after the charging is finished, the next inspection task is started.

Claims (5)

1. The utility model provides a photovoltaic power plant inspection device which characterized in that: including unmanned aerial vehicle (1) and charging station (2), unmanned aerial vehicle (1) be provided with wing (12) in the both sides of organism (11), be provided with motor (122) on wing (12) and be connected with screw (121), organism (11) front end is provided with infrared detector (111), infrared detector (111) are connected with processing chip A (113), processing chip A (113) are connected with signal transceiver (112), signal transceiver (112) are connected with ground basic station, processing chip A (113) are connected with controller A (115), controller A (115) are connected with motor (122), unmanned aerial vehicle (1) inside is provided with battery (114), battery (114) are connected with terminal charging slot (117) of organism (11), set up base plate (21) in charging station (2), base plate (21) one end is provided with charging canopy (22), be provided with charging plug (222) in charging canopy (22), charging plug (222) cooperate with charging slot (117).

2. The photovoltaic power plant inspection device of claim 1, wherein: the machine body (11) is hinged with the wing (12) through a hinge part (13).

3. The photovoltaic power plant inspection device of claim 1, wherein: the wing (12) below be provided with stabilizer blade (123), foot (124) are established to the outside cover of stabilizer blade (123), are provided with damping spring (125) between the bottom of stabilizer blade (123) and foot (124).

4. The photovoltaic power plant inspection device of claim 1, wherein: the charging shed (22) is divided into a plurality of charging areas (221), and each charging area (221) is provided with a corresponding charging plug (222).

5. The photovoltaic power plant inspection device of claim 4, wherein: the charging shed (22) rear be provided with control box (23), control box (23) are connected with power cord (234), power cord (234) are connected with charging plug (222) in each charging zone (221), the top in each charging zone (221) is corresponding to be provided with charge indicator lamp (223), install full detector (231) in the charging line in control box (23), full detector (231) are connected with processing chip B (232), processing chip B (232) are connected with controller B (233), controller B (233) are connected with each charge indicator lamp (223) respectively.

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