CN219372387U - Photovoltaic flexible assembly test support and photovoltaic assembly test equipment - Google Patents

Abstract

The utility model discloses a photovoltaic flexible component testing bracket which comprises two long-side outer frames, an upper short-side outer frame and a lower short-side outer frame, wherein the upper end of the long-side outer frame is detachably connected with the end part of the upper short-side outer frame, the lower end of the long-side outer frame is detachably connected with the end part of the lower short-side outer frame, a plurality of fixing blocks are movably arranged on the front surface of the long-side outer frame and the front surface of the upper short-side outer frame, the fixing blocks and the long-side outer frame which are arranged on the long-side outer frame are used for clamping the long-side edge of a photovoltaic flexible component, and the fixing blocks and the upper short-side outer frame which are arranged on the upper short-side outer frame are used for clamping the upper short-side edge of the photovoltaic flexible component. The condition that the sample is softened under the high temperature condition to cause the bottom structure of the sample to be damaged in the test process can not occur, so that the test is invalid. The sample can be directly placed vertically or on the sample rack, so that the test result can be more reactive to the performance of the sample, and the result is more representative. The utility model also discloses photovoltaic module testing equipment comprising the photovoltaic flexible module testing bracket.

Description

Photovoltaic flexible assembly test support and photovoltaic assembly test equipment

Technical Field

The utility model relates to the field of photovoltaic equipment, in particular to a photovoltaic flexible assembly test support. In addition, the utility model also relates to photovoltaic module testing equipment comprising the photovoltaic flexible module testing bracket.

Background

The photovoltaic power generation is used as a novel energy form, is widely applied to various technical fields, and in order to ensure reliable and stable equipment operation, when a photovoltaic product is tested, a part of tests need to be tested after the sample is vertically placed, such as tests of environmental damp-heat tests, potential induced attenuation tests, thermal cycle tests, wet freezing tests and the like, and all the samples need to be vertically placed in an environmental box. The conventional assembly is provided with a frame, so that a sample can be directly placed vertically and then tested or placed vertically on a sample frame and then tested, but the light photovoltaic flexible assembly is free of the frame in structure and soft in characteristics, and cannot be placed vertically, when the light photovoltaic flexible assembly is placed vertically on the sample frame, the sample can be bent greatly, the bottom of the sample can bear the weight of the sample, the sample is easy to lose efficacy due to softening of the material under the high-temperature condition, the test result is disturbed, and the real test result cannot be obtained.

Therefore, how to provide a photovoltaic flexible assembly test stand for stably supporting a flexible assembly is a technical problem that a person skilled in the art needs to solve.

Disclosure of Invention

The utility model aims to provide a photovoltaic flexible assembly test support, which forms a rectangular frame through a long-side outer frame, an upper short-side outer frame and a lower short-side outer frame, and clamps the peripheral edges of a photovoltaic flexible assembly together with a fixed block, so that the assembly is prevented from being damaged, and the test effect is ensured. Another object of the present utility model is to provide a photovoltaic module testing apparatus comprising the above-described photovoltaic flexible module testing stand.

In order to solve the technical problems, the utility model provides a photovoltaic flexible assembly testing bracket, which comprises two long-side outer frames which are parallel to each other, an upper short-side outer frame and a lower short-side outer frame which are parallel to each other, wherein the long-side outer frames are perpendicular to the upper short-side outer frame, the upper ends of the long-side outer frames are detachably connected with the end parts of the upper short-side outer frames, the lower ends of the long-side outer frames are detachably connected with the end parts of the lower short-side outer frames to form a rectangular frame in a splicing way, a plurality of fixing blocks are movably mounted on the front surface of the long-side outer frames and the front surface of the upper short-side outer frames, the fixing blocks mounted on the long-side outer frames and the long-side outer frames are used for clamping long-side edges of a photovoltaic flexible assembly, and the fixing blocks mounted on the upper short-side outer frames are used for clamping upper short-side edges of the photovoltaic flexible assembly.

Preferably, the photovoltaic module further comprises two corner brackets symmetrically arranged, the upper end of the long side outer frame is connected with the lower end of the corner bracket, the upper end of the corner bracket is connected with the end part of the upper short side outer frame, the front of the corner bracket is attached to the long side outer frame and the back of the upper short side outer frame, the front of the long side outer frame is flush with the front of the upper short side outer frame, the back of the lower short side outer frame is attached to the front of the long side outer frame, and the upper side of the lower short side outer frame is used for supporting the lower short side edge of the photovoltaic module.

Preferably, the upper side surface of the long-side outer frame is attached to the lower side surface of the upper short-side outer frame.

Preferably, the long-side frame, the upper short-side frame and the lower short-side frame are provided with a plurality of positioning holes arranged along the extending direction, the corner connector is correspondingly provided with a mounting hole, the fixing block is correspondingly provided with a fixing hole, the upper end of the long-side frame and the upper short-side frame are connected with the corner connector through adjusting bolts, the lower end of the long-side frame is connected with the lower short-side frame through adjusting bolts, and the long-side frame and the upper short-side frame are connected with the fixing block through fixing bolts.

Preferably, the mounting hole above the corner brace is aligned with each positioning hole of the upper short-side frame to adjust the distance between the two long-side frames, and the positioning hole of the lower short-side frame is aligned with each positioning hole of the lower end of the long-side frame to adjust the distance between the upper short-side frame and the lower short-side frame.

Preferably, a plurality of the positioning holes are arranged near the ends of the long-side outer frame, the upper short-side outer frame, and the lower short-side outer frame.

Preferably, four fixing blocks are mounted on the long-side outer frame, four fixing blocks are mounted on the upper short-side outer frame, one fixing hole is formed in each fixing block mounted on the long-side outer frame, one fixing hole is formed in each fixing block mounted on two ends of the upper short-side outer frame, and two fixing holes are formed in each fixing block mounted in the middle of the upper short-side outer frame.

Preferably, the adjusting bolt is a flat head bolt, and the fixing bolt is an outer hexagon bolt.

Preferably, a flange is arranged at the outer edge of the back of the fixed block, and a crack is arranged between the back of the fixed block and the front of the long-side outer frame and between the back of the fixed block and the front of the upper short-side outer frame.

The utility model provides photovoltaic module testing equipment, which comprises the photovoltaic flexible module testing bracket.

The utility model provides a photovoltaic flexible component testing support which comprises two long-side outer frames which are parallel to each other, an upper short-side outer frame and a lower short-side outer frame which are parallel to each other, wherein the long-side outer frames are perpendicular to the upper short-side outer frames, the upper ends of the long-side outer frames are detachably connected with the end parts of the upper short-side outer frames, the lower ends of the long-side outer frames are detachably connected with the end parts of the lower short-side outer frames to form a rectangular frame in a splicing mode, a plurality of fixing blocks are movably mounted on the front face of the long-side outer frames and the front face of the upper short-side outer frames, the fixing blocks mounted on the long-side outer frames and the long-side outer frames are used for clamping long-side edges of a photovoltaic flexible component, and the fixing blocks mounted on the upper short-side outer frames and the upper short-side edges of the photovoltaic flexible component are used for clamping.

Through long limit frame, go up minor face frame and lower minor face frame formation rectangular frame, press from both sides tight photovoltaic flexible module's edge all around with the fixed block jointly, rectangular frame four sides all have fixed support effect to light photovoltaic flexible module sample, and the weight of sample itself is not born by sample bottom, but born jointly by each supporting point and bottom, and sample softening causes sample bottom structure to be destroyed under the high temperature condition can not appear in the test process to lead to the condition of test inefficacy. The four sides of the rectangular frame have a certain protection function except for the fixing function on the light photovoltaic flexible assembly sample, and can prevent the battery hidden crack caused by bending deformation of the sample in the carrying process. The fixed sample can be directly vertically placed on the sample rack, the existing sample rack is compatible to be used, the working area can be adjusted, and the size of the working area can be flexibly adjusted according to the size of the measured sample. In the project requiring erection test, the sample can be directly vertically placed or placed on the sample rack, so that the test result can more reflect the performance of the sample, and the result is more representative.

The utility model also provides a photovoltaic module testing device comprising the photovoltaic flexible module testing support, and the photovoltaic module testing device has the same technical effects as the photovoltaic flexible module testing support.

Drawings

FIG. 1 is a schematic front view of a specific embodiment of a photovoltaic flexible module test stand provided by the present utility model;

FIG. 2 is a schematic back view of an embodiment of a photovoltaic flexible module test stand provided by the present utility model;

FIG. 3 is a schematic view of an embodiment of a photovoltaic flexible module test stand according to the present utility model;

fig. 4 is a schematic structural diagram of an angle code in a specific embodiment of the photovoltaic flexible component test stand provided by the utility model;

FIG. 5 is a front partial enlarged view of one embodiment of a photovoltaic flexible module test stand provided by the present utility model;

FIG. 6 is a rear partial enlarged view of one embodiment of a photovoltaic flexible module test stand provided by the present utility model;

fig. 7 is a schematic structural diagram of a fixing bolt in a specific embodiment of the photovoltaic flexible module testing stand provided by the utility model;

FIG. 8 is a schematic structural view of an adjusting bolt in an embodiment of the photovoltaic flexible module test stand provided by the present utility model;

FIG. 9 is a schematic view of a two-view structure of a hole fixture block in an embodiment of a photovoltaic flexible module test stand according to the present utility model;

fig. 10 is a schematic diagram of a two-view structure of two hole fixing blocks in an embodiment of a photovoltaic flexible module testing stand provided by the present utility model.

Detailed Description

The utility model provides a photovoltaic flexible assembly testing support, which forms a rectangular frame through a long-side outer frame, an upper short-side outer frame and a lower short-side outer frame, and clamps the peripheral edges of a photovoltaic flexible assembly together with a fixed block, so that the assembly is prevented from being damaged, and the testing effect is ensured. The utility model further provides photovoltaic module testing equipment comprising the photovoltaic flexible module testing support.

In order to better understand the aspects of the present utility model, the present utility model will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1 to 3, fig. 1 is a schematic front view of a specific embodiment of a photovoltaic flexible module testing stand provided by the present utility model; FIG. 2 is a schematic back view of an embodiment of a photovoltaic flexible module test stand provided by the present utility model; fig. 3 is a schematic diagram of an operating state of an embodiment of the photovoltaic flexible module testing stand provided by the utility model.

The utility model provides a photovoltaic flexible component testing support, which comprises two long-side outer frames 1, an upper short-side outer frame 2, a lower short-side outer frame 3 and a plurality of fixing blocks 4, wherein the upper and lower relations are defined according to the directions of the vertical arrangement of the support during operation, the two long-side outer frames 1 are mutually parallel, the upper short-side outer frame 2 and the lower short-side outer frame 3 are mutually parallel, the long-side outer frame 1 is perpendicular to the upper short-side outer frame 2, the upper ends of the two long-side outer frames 1 are respectively and detachably connected with the two ends of the upper short-side outer frame 2, the lower ends of the two long-side outer frames 1 are respectively and detachably connected with the two ends of the lower short-side outer frame 3, the four outer frames are spliced to form a rectangular frame in the mode, the fixing blocks 4 are movably mounted on the front face of the long-side outer frame 1 and are used for clamping the long-side edge of a photovoltaic flexible component 6, and the fixing blocks 4 are movably mounted on the front face of the upper short-side outer frame 2 and the upper short-side 2 are used for clamping the short-side edge of the photovoltaic flexible component 6.

The rectangular frame is formed by the long-side outer frame 1, the upper short-side outer frame 2 and the lower short-side outer frame 3, the four sides of the rectangular frame clamp the peripheral edges of the photovoltaic flexible assembly 6 together with the fixed blocks 4, the four sides of the rectangular frame have a fixed supporting effect on the sample of the light photovoltaic flexible assembly 6, the weight of the sample is not born by the bottom of the sample, but born by the supporting points and the bottom together, and the sample is not softened under the high-temperature condition in the testing process, so that the bottom structure of the sample is damaged, and the test failure is caused. The four sides of the rectangular frame have a certain protection function except for the fixing function on the sample of the light photovoltaic flexible assembly 6, and can prevent the battery hidden crack caused by bending deformation of the sample in the carrying process. The fixed sample can be directly vertically placed on the sample rack, the existing sample rack is compatible to be used, the working area can be adjusted, and the size of the working area can be flexibly adjusted according to the size of the measured sample. In the project requiring erection test, the sample can be directly vertically placed or placed on the sample rack, so that the test result can more reflect the performance of the sample, and the result is more representative.

Referring to fig. 4 to 6, fig. 4 is a schematic structural diagram of a corner connector in an embodiment of the testing stand for a photovoltaic flexible component according to the present utility model; FIG. 5 is a front partial enlarged view of one embodiment of a photovoltaic flexible module test stand provided by the present utility model; fig. 6 is a rear partial enlarged view of one embodiment of a photovoltaic flexible module test stand provided by the present utility model.

In order to guarantee stable connection of support, can also set up two angle yards 5 of symmetry, angle yard 5's lower extreme is connected to long limit frame 1's upper end, the tip of short side frame 2 is connected to angle yard 5's upper end, angle yard 5's positive laminating long limit frame 1 and the back of going up short side frame 2, make the front of long limit frame 1 and the front parallel and level of going up short side frame 2, make things convenient for the stable of photovoltaic flexible component 6 to place, the front of long limit frame 1 is laminated to the back of short side frame 3 down simultaneously, make short side frame 3 protrusion in long limit frame 1's front, place photovoltaic flexible component 6 when frame is positive, the last side of short side frame 3 is used for supporting photovoltaic flexible component 6's short side edge down. Meanwhile, due to the shape characteristics of the corner brace 5, the upper side surface of the long-side outer frame 1 is attached to the lower side surface of the short-side outer frame 2.

Preferably, the long-side outer frame 1, the upper short-side outer frame 2 and the lower short-side outer frame 3 are respectively provided with a plurality of positioning holes 11, the plurality of positioning holes 11 are respectively arranged along the extending direction of the corresponding outer frame, meanwhile, the corner bracket 5 is correspondingly provided with a mounting hole 51, and the fixing block 4 is correspondingly provided with a fixing hole 41. During installation, the front sides of the corner brackets 5 are attached to the back sides of the long-side outer frames 1 and the upper short-side outer frames 2, the positioning holes 11 at the upper ends of the long-side outer frames 1 are aligned with the mounting holes 51 at the lower ends of the corner brackets 5, the positioning holes 11 at the end parts of the upper short-side outer frames 2 are aligned with the mounting holes 51 at the upper ends of the corner brackets 5, then the corner brackets 5 penetrate through the corresponding positioning holes 11 and the mounting holes 51 through the adjusting bolts 52, and the long-side outer frames 1 and the upper short-side outer frames 2 of the corner brackets 5 are connected through the adjusting bolts 52. Then the back laminating long limit frame 1's of short side frame 3 front down, the locating hole 11 of long limit frame 1 lower extreme aligns the locating hole 11 of short side frame 3 down, then pass corresponding locating hole 11 through adjusting bolt 52, connect long limit frame 1 and short side frame 3 down through adjusting bolt 52, place photovoltaic flexible component 6 in rectangular frame front, then make the fixed orifices 41 of fixed block 4 aim at different locating holes 11, fixing bolt 42 passes corresponding fixed orifices 41 and locating hole 11, fix fixed orifices 4 position, and compress tightly the edge of photovoltaic flexible component 6.

In order to adjust the size of the working area, after the corner brace 5 is connected with the long-side outer frames 1, the two long-side outer frames 1 are horizontally moved, so that the corner brace 5 is aligned with each positioning hole 11 at different horizontal positions on the upper short-side outer frame 2 and then fixed, and the distance between the two long-side outer frames 1 can be adjusted. The lower short side outer frame 3 can be vertically moved, the positioning holes 11 of the lower short side outer frame 3 are fixed after being aligned with the positioning holes 11 of different vertical positions of the lower end of the long side outer frame 1, and the distance between the upper short side outer frame 2 and the lower short side outer frame 3 can be adjusted, so that the size of the rectangular frame area is realized.

For ease of processing, a plurality of positioning holes 11 are arranged near the ends of the long-side frame 1, the upper short-side frame 2, and the lower short-side frame 3. The lower end of the long-side outer frame 1, the end part of the upper short-side outer frame 2 and the end part of the lower short-side outer frame 3 are provided with more dense positioning holes 11, so that the area of the rectangular frame is adjusted more finely, and meanwhile, the middle part of the long-side outer frame 1 is provided with sparse upper positioning holes 11, so that the fixing block 4 can be installed. The number and arrangement of the positioning holes 11 can be adjusted according to the situation, and the utility model is also within the scope of protection.

Referring to fig. 7 and 8, fig. 7 is a schematic structural diagram of a fixing bolt in an embodiment of a testing stand for a photovoltaic flexible component according to the present utility model; fig. 8 is a schematic structural diagram of an adjusting bolt in an embodiment of the photovoltaic flexible module testing stand provided by the utility model.

Specifically, the adjusting bolt 52 is a flat head bolt, and the fixing bolt 42 is an outer hexagonal bolt. Of course, other types of bolts, or other types of connection, such as a bayonet connection or snap connection, may be used.

Referring to fig. 9 and 10, fig. 9 is a schematic view illustrating a two-view structure of a hole fixing block in an embodiment of a testing stand for a photovoltaic flexible component according to the present utility model; fig. 10 is a schematic diagram of a two-view structure of two hole fixing blocks in an embodiment of a photovoltaic flexible module testing stand provided by the present utility model.

Preferably, four fixing blocks 4 are installed on the long-side outer frame 1, four fixing blocks 4 are installed on the upper short-side outer frame 2, one fixing hole 41 is formed in the fixing block 4 installed on the long-side outer frame 1, one fixing hole 41 is formed in the fixing block 4 installed on two ends of the upper short-side outer frame 2, and two fixing holes 41 are formed in the fixing block 4 installed in the middle of the upper short-side outer frame 2. The fixed blocks 4 on each outer frame are distributed uniformly, so that the stress of the photovoltaic flexible assembly 6 is more uniform.

On the basis of the photovoltaic flexible component test support provided by the specific embodiments, the flange 43 is arranged at the outer edge of the back surface of the fixed block 4, the flange 43 is in front contact with the outer frame, a crack is formed between the back surface of the fixed block 4 and the front surface of the long-side outer frame 1 and the front surface of the upper short-side outer frame 2, the edge of the photovoltaic flexible component 6 is positioned in the crack to be clamped, the clamping action of the fixed block 4 is limited, the damage to the photovoltaic flexible component 6 is avoided, and the adhesive tape can be added on the fixed block 4.

In addition to the above-mentioned photovoltaic flexible component testing stand, the specific embodiment of the present utility model further provides a photovoltaic component testing apparatus including the above-mentioned photovoltaic flexible component testing stand, and the structure of other parts of the photovoltaic component testing apparatus is referred to the prior art, and will not be described herein.

The photovoltaic flexible component test support and the photovoltaic component test equipment provided by the utility model are described in detail. The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the utility model can be made without departing from the principles of the utility model and these modifications and adaptations are intended to be within the scope of the utility model as defined in the following claims.

Claims (10)

1. The utility model provides a photovoltaic flexible assembly test stand, its characterized in that includes two long limit frame (1) and the last minor face frame (2) and the minor face frame (3) that are parallel to each other of each other, long limit frame (1) perpendicular to go up minor face frame (2), the upper end of long limit frame (1) can be dismantled and connect the tip of going up minor face frame (2), the lower extreme of long limit frame (1) can be dismantled and connect the tip of minor face frame (3) down to splice and form rectangular frame, a plurality of fixed blocks (4) movable mounting in the front of long limit frame (1) and the front of going up minor face frame (2), install in long limit frame (1) fixed block (4) with long limit frame (1) are used for pressing from both sides the long limit edge of tight Fu Rouxing subassembly (6), install in go up the fixed block (4) of minor face frame (2) are used for pressing from both sides tight light Fu Rouxing subassembly (6).

2. The photovoltaic flexible component testing bracket according to claim 1, further comprising two corner brackets (5) symmetrically arranged, wherein the upper end of the long-side outer frame (1) is connected with the lower end of the corner bracket (5), the upper end of the corner bracket (5) is connected with the end of the upper short-side outer frame (2), the front surface of the corner bracket (5) is attached to the long-side outer frame (1) and the back surface of the upper short-side outer frame (2), the front surface of the long-side outer frame (1) is aligned with the front surface of the upper short-side outer frame (2), the back surface of the lower short-side outer frame (3) is attached to the front surface of the long-side outer frame (1), and the upper side surface of the lower short-side outer frame (3) is used for supporting the lower short-side edge of the light Fu Rouxing component (6).

3. The photovoltaic flexible module testing stand according to claim 2, characterized in that the upper side of the long side frame (1) is attached to the lower side of the upper short side frame (2).

4. The photovoltaic flexible component test support according to claim 3, wherein the long-side outer frame (1), the upper short-side outer frame (2) and the lower short-side outer frame (3) are respectively provided with a plurality of positioning holes (11) arranged along the extending direction, the corner connector (5) is correspondingly provided with a mounting hole (51), the fixing block (4) is correspondingly provided with a fixing hole (41), the upper end of the long-side outer frame (1) and the upper short-side outer frame (2) are connected with the corner connector (5) through adjusting bolts (52), the lower end of the long-side outer frame (1) is connected with the lower short-side outer frame (3) through adjusting bolts (52), and the long-side outer frame (1) and the upper short-side outer frame (2) are connected with the fixing block (4) through fixing bolts (42).

5. The photovoltaic flexible module testing stand according to claim 4, wherein the mounting hole (51) above the corner bracket (5) is aligned with each of the positioning holes (11) of the upper short-side frame (2) to adjust the distance between the two long-side frames (1), and the positioning hole (11) of the lower short-side frame (3) is aligned with each of the positioning holes (11) of the lower end of the long-side frame (1) to adjust the distance between the upper short-side frame (2) and the lower short-side frame (3).

6. The photovoltaic flexible module testing stand according to claim 5, characterized in that a plurality of the positioning holes (11) are arranged near the ends of the long-side frame (1), the upper short-side frame (2) and the lower short-side frame (3).

7. The photovoltaic flexible component testing bracket according to claim 6, wherein four fixing blocks (4) are installed on the long-side outer frame (1), four fixing blocks (4) are installed on the upper short-side outer frame (2), one fixing hole (41) is formed in the fixing block (4) installed on the long-side outer frame (1), one fixing hole (41) is formed in the fixing block (4) installed on two ends of the upper short-side outer frame (2), and two fixing holes (41) are formed in the fixing block (4) installed in the middle of the upper short-side outer frame (2).

8. The photovoltaic flexible module test stand according to claim 7, characterized in that the adjusting bolt (52) is in particular a flat head bolt and the fixing bolt (42) is in particular an outer hexagonal bolt.

9. The photovoltaic flexible module test stand according to any one of claims 1 to 8, characterized in that a flange (43) is provided at the outer edge of the back surface of the fixing block (4), and a gap is provided between the back surface of the fixing block (4) and the front surface of the long-side outer frame (1) and the front surface of the upper short-side outer frame (2).

10. A photovoltaic module testing apparatus comprising a photovoltaic flexible module testing stand according to any one of claims 1 to 9.