CN216280322U - Perovskite solar cell data acquisition device - Google Patents

Abstract

The utility model discloses a perovskite solar cell data acquisition device, which comprises a perovskite solar cell panel, a bracket and an acquisition box, wherein the perovskite solar cell panel is obliquely arranged, the bracket is fixedly arranged at the lower side of the perovskite solar cell panel, the acquisition box is fixedly connected at the end part of the bracket, and an opening is formed in one side of the acquisition box, which faces to the perovskite solar cell panel, the perovskite solar cell data acquisition device provided by the utility model can acquire data of the perovskite solar cell panel in an elevation angle mode through the arrangement of the bracket and a thermal imaging camera, the normal lighting of the perovskite solar cell is not influenced, the thermal imaging camera can be controlled to synchronously turn left and right to shoot through the arrangement of a lifting component and a swinging component when the elevation angle is adjusted, the surface of the perovskite solar cell can be sequentially scanned, complete perovskite solar cell surface information can be obtained.

Description

Perovskite solar cell data acquisition device

Technical Field

The utility model relates to the technical field of solar cell data acquisition, in particular to a perovskite solar cell data acquisition device.

Background

The perovskite type solar cell is a solar cell which uses perovskite type organic metal halide semiconductor as a light absorption material, belongs to a third generation solar cell and is also called a new concept solar cell;

the solar energy conversion rate of the perovskite solar cell is greatly influenced by dust on the surface of the cell, and the solar cell can also be in failure due to overheating, but the solar cell data acquisition device is difficult to monitor the surface condition of the solar cell comprehensively in the open air state, so that the perovskite solar cell is difficult to process when dust is accumulated or the failure occurs, the photoelectric conversion rate of the perovskite solar cell is reduced, and potential hazards are brought to application safety.

SUMMERY OF THE UTILITY MODEL

The utility model provides a perovskite solar cell data acquisition device, which solves the technical problems that the conventional solar cell data acquisition device is difficult to comprehensively monitor the surface of a solar cell in an open air state, so that the perovskite solar cell is difficult to process when dust is accumulated or faults exist, the photoelectric conversion rate of the perovskite solar cell is reduced, and hidden dangers are brought to application safety.

In order to solve the technical problems, the perovskite solar cell data acquisition device provided by the utility model comprises a perovskite solar cell panel, a support and an acquisition box, wherein the perovskite solar cell panel is obliquely arranged, the support is fixedly arranged on the lower side of the perovskite solar cell panel, the end part of the support is fixedly connected with the acquisition box, an opening is formed in one side, facing the perovskite solar cell panel, of the acquisition box, a lifting component, a swinging component and a thermal imaging camera are installed in the acquisition box, the lifting component is in transmission connection with the swinging component, and the lifting component and the swinging component jointly act on the thermal imaging camera to scan the perovskite solar cell panel.

Preferably, the lifting unit includes the limiting plate, limiting plate fixed connection is between the relative inner wall of collection box, the middle part of limiting plate is provided with the rectangular channel, and sliding fit is equipped with the lift cover in the rectangular channel, the tip of lift cover runs through and is provided with the lifter, the downside threaded connection of lift cover has the lead screw, the bottom of lead screw and driving motor's output fixed connection, driving motor fixed connection is at the collection box diapire.

Preferably, the top of lift cover is provided with the diaphragm, the equal fixedly connected with sliding frame of both ends downside of diaphragm, the sliding frame is all worn out at the both ends of lifter, the upside middle part fixedly connected with round bar of diaphragm, the top of round bar is rotated and is connected the downside at thermal imaging camera.

Preferably, the swing subassembly is including swinging the frame, equal fixedly connected with engagement tooth board on the relative lateral wall of swing frame, be provided with sector gear in the swing frame, the fixed outer wall at the lead screw of establishing of sector gear cover, just sector gear takes turns and is connected with the engagement tooth board meshing.

Preferably, the upper side of the swing frame is rotatably connected with a vertical rod, the top end of the vertical rod is hinged with a supporting plate, and the top end of the supporting plate is fixedly connected with the thermal imaging camera.

Preferably, the opposite side walls of the collection box are fixedly connected with sliding rails, and a swinging frame is embedded between the two sliding rails in a sliding manner.

Compared with the related art, the perovskite solar cell data acquisition device provided by the utility model has the following beneficial effects: the utility model provides a perovskite solar cell data acquisition device, through the arrangement of a bracket and a thermal imaging camera, the perovskite solar cell panel can be subjected to data acquisition in an elevation angle mode, the normal lighting of the perovskite solar cell is not influenced, through the arrangement of a lifting component and a swinging component, the thermal imaging camera can be controlled to synchronously turn left and right to shoot when the elevation angle is adjusted, the surface of the perovskite solar cell can be sequentially scanned, the complete surface information of the perovskite solar cell can be obtained, a technician judges whether the solar cell is locally overheated or dirty through the temperature difference of the surface of the solar cell, and data support can be provided for the maintenance and repair of the perovskite solar cell.

Drawings

FIG. 1 is an external view of a perovskite solar cell data acquisition device of the present invention;

FIG. 2 is a side cross-sectional view of a collection box in the perovskite solar cell data collection device of the present invention;

FIG. 3 is a front view of a collection box in the perovskite solar cell data collection device of the present invention;

FIG. 4 is a top sectional view of a collection box in the perovskite solar cell data collection device of the utility model.

Reference numbers in the figures: 1. a perovskite solar panel; 2. a support; 3. a collection box; 301. opening the mouth; 302. a slide rail; 4. a lifting assembly; 401. a limiting plate; 402. a lifting sleeve; 403. a lifting rod; 404. a screw rod; 405. a drive motor; 406. a transverse plate; 407. a sliding frame; 408. a round bar; 5. a swing assembly; 501. a swing frame; 502. a toothed plate; 503. a sector gear; 504. a vertical rod; 505. a support plate; 6. thermal imaging camera.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the embodiment, as shown in fig. 1-4, the perovskite solar cell data acquisition device of the utility model comprises a perovskite solar cell panel 1, a bracket 2 and an acquisition box 3, wherein the perovskite solar cell panel 1 is arranged obliquely, the bracket 2 is fixedly arranged on the lower side of the perovskite solar cell panel 1, the end of the bracket 2 is fixedly connected with the acquisition box 3, an opening 301 is formed in one side of the acquisition box 3 facing the perovskite solar cell panel 1, a lifting component 4, a swinging component 5 and a thermal imaging camera 6 are arranged in the acquisition box 3, the lifting component 4 is in transmission connection with the swinging component 5, the lifting component 4 and the swinging component 5 jointly act on the thermal imaging camera 6 to scan the perovskite solar cell panel 1, and the lifting component 4 and the swinging component 5 are arranged to control the thermal imaging camera 6 to adjust the elevation angle, and synchronously, shooting in a left-right turning mode, and sequentially scanning the surface of the perovskite solar panel 1 in sequence to obtain complete surface information of the perovskite solar panel 1.

Wherein, lifting unit 4 includes limiting plate 401, limiting plate 401 fixed connection is between the relative inner wall of collection box 3, limiting plate 401's middle part is provided with the rectangular channel, and sliding fit is equipped with lift cover 402 in the rectangular channel, the tip of lift cover 402 runs through and is provided with lifter 403, the downside threaded connection of lift cover 402 has lead screw 404, the bottom of lead screw 404 and driving motor 405's output fixed connection, driving motor 405 fixed connection is at collection box 3 diapire, and driving motor 405 moves, drives lead screw 404 and rotates, and lead screw 404 screw drive lift cover 402 rises, and lifter 403 will hold up smooth frame 407, and when holding up, lifter 403 slides along smooth frame 407, can not block and die.

Wherein, the top of lift cover 402 is provided with diaphragm 406, the equal fixedly connected with sliding frame 407 of both ends downside of diaphragm 406, sliding frame 407 is all worn out at the both ends of lifter 403, the upside middle part fixedly connected with round bar 408 of diaphragm 406, the top of round bar 408 is rotated and is connected in thermal imaging camera 6's downside, and thermal imaging camera 6 can adjust the angle of elevation with diaphragm 406 synchronization, and thermal imaging camera 6 can rotate with round bar 408 and be connected for thermal imaging camera 6 can control the angle when the angle of elevation changes, can adjust in step.

Wherein, swing subassembly 5 includes swing frame 501, equal fixedly connected with tooth flank 502 on the relative lateral wall of swing frame 501, be provided with sector gear 503 in the swing frame 501, the fixed cover of sector gear 503 is established at the outer wall of lead screw 404, just sector gear 503 is connected with tooth flank 502 meshing in turn, and lead screw 404 drives sector gear 503 and rotates, and sector gear 503 meshes one of them tooth flank 502 for swing frame 501 is along slide rail 302 unidirectional movement, and later, the tooth flank position of sector gear 503 rotates to the opposite side, and another tooth flank 502 of meshing can make swing frame 501 along slide rail 302 reverse movement, with this makes swing frame 501 reciprocating motion.

The upper side of the swing frame 501 is rotatably connected with a vertical rod 504, the top end of the vertical rod 504 is hinged with a supporting plate 505, the top end of the supporting plate 505 is fixedly connected with the thermal imaging camera 6, the lifting rod 403 is used for supporting the sliding frame 407, the horizontal plate 406 is inclined, the thermal imaging camera 6 rotates around a hinged point of the vertical rod 504 and the supporting plate 505, and therefore the shooting elevation angle of the thermal imaging camera 6 can be gradually reduced.

The opposite side walls of the collection box 3 are fixedly connected with slide rails 302, a swing frame 501 is embedded between the two slide rails 302 in a sliding manner, and the swing frame 501 can only swing left and right under the limiting action of the two slide rails 302.

The working principle is as follows: the driving motor 405 runs to drive the screw rod 404 to rotate, the screw rod 404 drives the lifting sleeve 402 to ascend in a threaded manner, the lifting rod 403 supports the sliding frame 407, the horizontal plate 406 inclines, the thermal imaging camera 6 rotates around a hinge point between the vertical rod 504 and the supporting plate 505, so that the shooting elevation angle of the thermal imaging camera 6 is gradually reduced, synchronously, the screw rod 404 drives the sector gear 503 to rotate, the sector gear 503 is meshed with one toothed plate 502, the swinging frame 501 moves along the sliding rail 302 in a single direction, then, the meshed part of the sector gear 503 rotates to the other side and is meshed with the other toothed plate 502, the swinging frame 501 can move in the reverse direction along the sliding rail 302, so that the swinging frame 501 moves in a reciprocating manner, when the swinging frame 501 moves, the vertical rod 504 pulls the thermal imaging camera 6 to change the direction in a reciprocating manner, the vertical rod 504 is rotatably connected with the swinging frame 501, the round rod 408 is rotatably connected with the thermal imaging camera 6, and the thermal imaging camera 6 cannot be blocked, and can not conflict with the elevation angle adjustment of the thermal imaging camera 6 each other to this makes the thermal imaging camera 6 be the broken line type and shoots on perovskite solar cell panel 1, can shoot the general appearance of perovskite solar cell panel 1, and the technical staff can judge whether local overheat or dirty phenomenon appears in the solar cell through the difference in temperature on analogy solar cell surface.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The perovskite solar cell data acquisition device comprises a perovskite solar cell panel (1), a bracket (2) and an acquisition box (3), characterized in that the perovskite solar cell panel (1) is obliquely arranged, a bracket (2) is fixedly arranged at the lower side of the perovskite solar cell panel (1), the end part of the bracket (2) is fixedly connected with a collection box (3), one side of the collection box (3) facing the perovskite solar panel (1) is provided with an opening (301), a lifting component (4), a swinging component (5) and a thermal imaging camera (6) are arranged in the collection box (3), the lifting component (4) is in transmission connection with the swinging component (5), and the lifting component (4) and the swinging component (5) jointly act on the thermal imaging camera (6) to scan the perovskite solar panel (1).

2. The perovskite solar cell data acquisition device of claim 1, wherein the lifting assembly (4) comprises a limiting plate (401), the limiting plate (401) is fixedly connected between the opposite inner walls of the acquisition box (3), a rectangular groove is formed in the middle of the limiting plate (401), a lifting sleeve (402) is embedded in the rectangular groove in a sliding mode, a lifting rod (403) penetrates through the end of the lifting sleeve (402), a lead screw (404) is connected to the lower side of the lifting sleeve (402) in a threaded mode, the bottom end of the lead screw (404) is fixedly connected with the output end of a driving motor (405), and the driving motor (405) is fixedly connected to the bottom wall of the acquisition box (3).

3. The perovskite solar cell data acquisition device as claimed in claim 2, wherein a transverse plate (406) is arranged above the lifting sleeve (402), sliding frames (407) are fixedly connected to the lower sides of the two ends of the transverse plate (406), the two ends of the lifting rod (403) penetrate through the sliding frames (407), a round rod (408) is fixedly connected to the middle of the upper side of the transverse plate (406), and the top end of the round rod (408) is rotatably connected to the lower side of the thermal imaging camera (6).

4. The perovskite solar cell data acquisition device of claim 1, wherein the swing assembly (5) comprises a swing frame (501), opposite side walls of the swing frame (501) are fixedly connected with a toothed plate (502), a sector gear (503) is arranged in the swing frame (501), the sector gear (503) is fixedly sleeved on the outer wall of the lead screw (404), and the sector gear (503) is in meshing connection with the toothed plate (502) in turn.

5. The perovskite solar cell data acquisition device as claimed in claim 4, wherein the upper side of the swing frame (501) is rotatably connected with a vertical rod (504), the top end of the vertical rod (504) is hinged with a supporting plate (505), and the top end of the supporting plate (505) is fixedly connected with the thermal imaging camera (6).

6. The perovskite solar cell data acquisition device as claimed in claim 1, wherein the acquisition box (3) is fixedly connected with sliding rails (302) on opposite side walls, and a swinging frame (501) is slidably embedded between the two sliding rails (302).

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