JPH11274522A - Torsion tester and testing method for solar battery module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure mechanical durability, in which inner disconnection or damage to a solar battery module is caused by mechanical stress like torsion of the solar battery module during delivery, mounting or construction work. SOLUTION: A torsion tester includes a holding plate 2 made up of upper and lower L-shaped plates 21 and 22 with opposite flat faces in parallel, a tightening member 3 for tightening the solar battery module 7 between the upper and lower plates 21 and 22, and a stress applying unit 4 for applying stress to the solar battery module 7 between the upper and lower plates 21 and 22.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell module torsion tester used for examining mechanical durability of a solar cell module, and a mechanical durability test using the solar cell module torsion tester. To a torsion test method for a solar cell module.

[0002]

2. Description of the Related Art JIS-C-8917 describes the environmental test method and durability test method of a solar cell module such as a crystal type, and includes a temperature cycle test, a temperature / humidity cycle test, a terminal strength test, a salt water spray test, and a light spray test. An irradiation test, a hot spot test, a wind resistance test, a hail test, a waterproof test, a torsion test, and the like are specified.

In the torsion test, two adjacent sides of a substantially rectangular solar cell module are fixed to a rigid frame, and the angle between the narrow angle of the two sides and the angle opposite to the narrow side is displaced by a predetermined amount. It is specified that the electrical continuity and the insulation resistance between one of the output terminals and the module frame be continuously measured. Here, the predetermined displacement amount is h = 0.021.
(L ² + W ² ) ^1/2 . Here, h: displacement amount (m) for a displacement angle of 1.2 ° L: module length (m) W: module width (m). As described in the JIS, there has been no torsion tester used in this torsion test method.

[0004]

However, when the solar cell module is transported, mounted, or constructed, mechanical stress such as torsion is often applied to the solar cell module. Since there is a risk of defective products such as internal disconnection of the solar cell module or breakage of the solar cell module, it is necessary to know the limit of this twist and make improvements to prevent the occurrence of defective products due to twist. There is. For that purpose, it is necessary to have a torsion tester for solar cell modules that can measure the relationship between torsion and internal disconnection or breakage, and a test method for testing mechanical durability using this torsion tester. The request was great.

Accordingly, an object of the present invention is to provide a solar cell for testing mechanical durability such as internal disconnection or breakage of the solar cell module caused by mechanical stress such as torsion during transportation, installation and construction of the solar cell module. An object of the present invention is to provide a module torsion tester and a test method for measuring mechanical durability using the solar cell module torsion tester.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to achieve the above object, and the invention according to claim 1 is a solar cell module torsion for examining mechanical durability of the solar cell module. A testing machine, wherein a facing plate is substantially parallel, and a holding plate composed of an L-shaped upper plate and a lower plate which are smooth surfaces, and a solar cell module is sandwiched between the upper plate and the lower plate. A fastener that can be fixed with
A stress applying device for applying stress to the solar cell module fixed between the upper plate and the lower plate.

According to a second aspect of the present invention, the fastener according to the first aspect of the present invention is capable of fixing a solar cell module sandwiched between an upper plate and a lower plate by screws. A plurality of tools are provided on the holding plate.

According to a third aspect of the present invention, there is provided a solar cell module torsion tester according to the first or second aspect, wherein two adjacent sides of the substantially square solar cell module are sandwiched between an upper plate and a lower plate, Tighten the upper and lower plates with fasteners to fix the solar cell module, apply stress to the solar cell module with a stress applying device, and measure the electrical resistance between the output terminals of the solar cell module, the output terminals and the module frame. The insulation resistance between them is continuously measured.

The invention according to claim 1 includes a holding plate, a fastener, and a stress applying device. When a stress is applied to the solar cell module by the stress applying device, the deformation of the solar cell module is reduced. It is preferable to provide a moving distance measuring device for checking the degree, since the relationship between the mechanical durability and the deformation and the relationship between the stress and the deformation of the solar cell module can be determined.

In the present invention, the upper plate and the lower plate have an L-shape. The included angle of the L-shape corresponds to the shape of the solar cell module which is measured so as to easily sandwich the solar cell module. It is preferable to combine them. For example, if the solar cell module is a parallelogram, as shown in FIG. 4A, the included angle 24 between the upper plate 21 and the lower plate 22 is made an acute angle, and the solar cell module is formed by the upper plate 21 and the lower plate 22. May be sandwiched. However, since many solar cell modules are square or rectangular, the center angle of this L-shape is generally a right angle. The center angle may be slightly rounded, as in the case of the included angle 24 in FIG. The materials of the upper plate and the lower plate are not particularly limited. The upper and lower plates opposing surfaces are smooth, but the opposite surface is not particularly limited.
For example, it may be a flat surface, or a rib may be provided to increase the mechanical strength. Also, as shown in FIG.
The opposite surface 23 may be a flat surface, and the opposite surface 26 may be an uneven surface.

Further, in the present invention, a stress applying device is provided. The stress applying device applies a stress to the solar cell module fixed between the upper plate and the lower plate to deform the solar cell module. Therefore, it is preferable to provide a stress applying device at a position where stress is applied to the solar cell module to easily deform it. For example, when fixing the adjacent sides of a square or rectangular solar cell module with the upper plate and the lower plate, the solar cell module is positioned near the diagonal of the corner of the solar cell module sandwiched between the upper plate and the lower plate. A stress applying device may be provided so as to be located. Further, it is preferable that the stress applying device is movable so as to correspond to solar cell modules of various sizes.
The direction in which the stress is applied to the solar cell module by the stress applying device is set so as to be applied at right angles to the solar cell module. The direction may be from above or from below. There are various types of the stress applying device, and a hydraulic jack is preferable.

According to the second aspect of the present invention, the fastener can fasten and fix the solar cell module sandwiched between the upper plate and the lower plate by screws. There are various types of devices that can be fixed by tightening what is sandwiched between them. For example, one of the upper plate and the lower plate has a screw rod fixed so as not to rotate around the axis of the screw and a through hole provided in the other, and the screw rod has a through hole. And a nut may be screwed in from the tip of the threaded rod and tightened. Alternatively, a through hole may be provided in the upper plate and the lower plate, and a bolt inserted from one side to the other and a screw may be screwed into the bolt. It may be tightened with the inserted nut. Further, a through hole may be provided on one side and a screw hole may be provided on the other side, and the bolt may be screwed into the screw hole from the through hole to fasten the bolt.

According to the second aspect of the present invention, a plurality of the fasteners are provided on the holder. This position includes at least a bent portion located substantially at the center of the L-shaped holder,
It is preferable to provide it at three places at both ends because it is easy to fix. If the length of one side of the L-shape is longer than the length of the side of the solar cell module, and the positions of the fasteners at both ends are outside the solar cell module, the solar cell module can be easily tightened firmly. It is preferred.

According to the third aspect of the present invention, the electric resistance between the output terminals of the solar cell module and the insulation resistance between the output terminals and the module frame are continuously measured by applying a stress to the solar cell module. In addition, breaks should be examined. This breaking is performed visually. Note that the term “break” refers to breakage of a component inside the module other than the internal disconnection, for example, a crack in a solar cell or the like. It is preferable to measure the moving distance of the stress-applied portion of the solar cell module in order to determine the degree of torsion that causes breakage.

(Function) According to the first aspect of the present invention, the holding plate composed of an L-shaped upper plate and a lower plate whose opposing surfaces are substantially parallel and which are smooth surfaces is provided. Since it is provided with a fastener capable of sandwiching and fixing the solar cell module therebetween, and a stress applying device for applying stress to the solar cell module fixed between the upper plate and the lower plate, The solar cell module is held by a holding plate consisting of an upper plate and a lower plate, the solar cell module is fixed by tightening the upper plate and the lower plate with a fastener, and stress is applied to the solar cell module by a stress applying device. Then, the electric resistance between the output terminals of the solar cell module and the insulation resistance between the output terminals and the module frame are measured.

Then, the relationship between the amount of stress applied and the internal disconnection of the solar cell module or the breakage of the solar cell module can be understood. Thus, the limit to which stress can be applied to the solar cell module during transportation, installation, construction, and the like of the solar cell module is known, and the solar cell module can be used for improvement of the solar cell module. In addition, since the opposing surfaces of the upper plate and the lower plate are substantially parallel and smooth, when fixing the solar cell module with the holding plate, the solar cell module surfaces can be almost uniformly fastened.

According to the second aspect of the present invention, since the fastening tool can fasten and fix a member sandwiched between the upper plate and the lower plate with a screw, the solar cell module is inserted between the upper plate and the lower plate. It is sandwiched and fixed by the action of screws. According to the second aspect of the present invention, since a plurality of the fasteners are provided on the holding plate, the holding plate including the upper plate and the lower plate is fixed at a plurality of locations by the fasteners. The solar cell module can be firmly fixed by the holding plate.

According to a third aspect of the present invention, there is provided a solar cell module torsion tester which sandwiches two adjacent sides of a substantially square solar cell module between an upper plate and a lower plate, and clamps the upper plate and the lower plate. To fix the solar cell module, apply stress to the solar cell module with a stress applying device, and continuously measure the electrical resistance between the output terminals of the solar cell module and the insulation resistance between the output terminals and the module frame Therefore, the relationship between the amount of stress applied and the internal disconnection of the solar cell module or the breakage of the solar cell module can be understood. As a result, the limit to which stress can be applied to the solar cell at the time of transportation, installation, construction, etc. of the solar cell module is understood,
Further, it can be used for improvement of a solar cell module and the like.

[0019]

Next, embodiments of the present invention will be described. (Embodiment 1) FIGS. 1 and 2 show one embodiment of the present invention. FIG. 1 (a) is an explanatory view showing a plane in use of a solar cell module torsion tester, and FIG. A)
FIG. 2A is a cross-sectional view taken along line A, FIG. 2A is a plan view showing a state in which a fastener is attached to a holding plate, and FIG. 2B is a side view of FIG.

In FIGS. 1 and 2, reference numeral 7 denotes a substantially square solar cell module. The solar cell module 7 includes a plurality of solar cells arranged side by side, and ones connected by lead wires sandwiched between both sides by an adhesive. Further, a translucent glass is placed on the upper side, a back cover is placed on the lower side, and the whole is integrated with the adhesive by heating / pressing, and a module frame 71 is attached to the periphery. The solar cells are connected by a lead wire, and this end is connected to an output terminal.

Reference numeral 1 denotes a solar cell module torsion tester. The solar cell module torsion tester 1 includes a holding plate 2.
, A fastener 3, a stress applying device 4, and a table 5. As shown in FIG. 2, the holding plate 2 includes an L-shaped upper plate 21 and a lower plate 22 whose side length is slightly longer than the side of the solar cell module 7 to be measured. Opposing surface 23
Has a smooth surface so that it can be mounted almost in parallel. The upper plate 21 is provided with a through hole 25 at the center angle portion and both end portions, and the lower plate 22 is provided with a screw hole 26 at a position facing the through hole 25 of the upper plate. I have. 1 between the upper plate 21 and the lower plate 22.
As shown in (b), when the solar cell module 7 is sandwiched, the through holes 25 and the screw holes 26 on both sides are located outside the solar cell module 7.

The fastener 3 is, as shown in FIG.
Is a bolt which can be screwed into the screw hole 26 of the lower plate 22 from the through hole 25 of the lower plate 22. The fastener 3 has three through holes 25 and screw holes 26.
There are three so that each can be screwed into. The table 5 includes a table body 51 and a rising portion 52 as shown in FIG.
The base body 51 is a flat plate having a larger surface than the solar cell module 7. The rising portion 52 stands substantially vertically in an L shape from the base body 51, and the lower plate 22 is fixed to an upper end of the rising portion 52. Also, the lower plate 22
The screw hole 26 extends to the rising portion 52.

The stress applying device 4 is a hydraulic jack. The stress applying device 4 is almost at the same height as the rising portion 52 of the base 5, and the vertically moving end 41 is attached to the holding plate 2 by the solar cell module 7. Is mounted near the diagonal 75 of the corner of the solar cell module 7 sandwiched in the vicinity of the included angle 24 of the holding plate 2 so that the tip 41 pushes up the solar cell module from below. Has become. Note that the stress applying device 4 is movable so as to be compatible with solar cell modules 7 of various sizes.

Next, a test method for testing the mechanical durability of the solar cell module by using the solar cell module torsion tester will be described. The two adjacent sides of the substantially square solar cell module 7 are sandwiched between the upper plate 21 and the lower plate 22 of the solar cell module torsion tester 1, and the upper plate 21 and the lower plate 22 are tightened by the fasteners 3. The battery module 7 is fixed. Thus, the fastener 3 is a bolt and the upper plate 21
Since the through hole 25 is provided with the screw hole 26 in the lower plate, the solar cell module 7 can be fastened by screwing the bolt through the through hole 25 into the screw hole 26. Moreover,
Since there are three fastening portions, the solar cell module can be firmly fixed.

Next, near the diagonal 75 of the corner of the solar cell module 7 sandwiched in the vicinity of the included angle 24 of the holding plate 2 of the solar cell module 7, stress is applied by the tip 41 of the stress applying device 4. The electrical resistance between the output terminals of the solar cell module 7 and the insulation resistance between the output terminals and the module frame are continuously measured. Then, the relationship between the amount of applied stress and the internal disconnection of the solar cell module 7 or the breakage of the solar cell module can be understood.

Thus, the limit of applying stress to the solar cell at the time of transportation, installation, construction and the like of the solar cell module 7 can be understood, and the solar cell module 7 can be used for improvement and the like. In addition, since the opposing surfaces of the upper plate 21 and the lower plate 22 are substantially parallel and smooth, when fixing the solar cell module 7 with the holding plate 2, the surface of the solar cell module 7 is almost uniformly fastened. it can.

(Embodiment 2) FIG. 3 shows another embodiment of the present invention, and is an explanatory view showing a main part of a usage state of a solar cell module torsion tester.

When the second embodiment shown in FIG. 3 is compared with the first embodiment shown in FIGS. 1 and 2, the stress applying device 4a of the solar cell module torsion tester 1a uses the solar cell module 7a.
The difference is that a displacement meter 6a for measuring the amount of displacement of the solar cell module 7a when a stress is applied to the solar cell module 7a is attached. Others are almost the same as those in the first embodiment, and the description is omitted.

This solar cell module torsion tester 1a
In the same manner as in Example 1, the electric resistance between the output terminals of the solar cell module 7 and the insulation resistance between the output terminals and the module frame are continuously measured, and simultaneously when the stress is applied by the stress applying device 4a. The displacement A can also be measured. By this, it is possible to know how much torsion or the like of the module internal component breaks, and to understand the relationship between the mechanical durability and the deformation of the solar cell module 7a and the relationship between the stress and the deformation. Further, similarly to the first embodiment, the solar cell module 7a
It can be seen that there is a limit to which stress is applied to the solar cell module 7a at the time of transportation, installation, construction, etc. Further, it can be used for improving the solar cell module 7a and the like.

[0030]

According to the first aspect of the present invention, the holding plate composed of an L-shaped upper plate and a lower plate, whose opposing surfaces are substantially parallel and which are smooth surfaces, is provided. Since it is provided with a fastener that can fix the solar cell module in between, and a stress applying device that applies stress to the solar cell module fixed between the upper plate and the lower plate, the solar cell The module is held by a holding plate, the solar cell module is fixed with a fastener, and a stress is applied to the solar cell module by a stress applying device, so that the electric resistance between the output terminals of the solar cell module, the output terminal and the module. By measuring the insulation resistance between the frames, the relationship between the amount of stress applied and the internal disconnection of the solar cell module or the breakage of the solar cell module can be determined.

Thus, the limit of applying stress to the solar cell at the time of transportation, installation, construction, and the like of the solar cell module can be understood, and the solar cell module can be used for improving the solar cell module. In addition, since the opposing surfaces of the upper plate and the lower plate are substantially parallel and smooth, when fixing the solar cell module with the holding plate, the solar cell module surfaces can be almost uniformly fastened.

According to the second aspect of the present invention, since the fastening tool can fasten and fix the solar cell module sandwiched between the upper plate and the lower plate by screws, the solar cell module can be fixed between the upper plate and the lower plate. It can be fixed by the action of screws across the module. Further, in the invention according to claim 2, since a plurality of the fasteners are provided on the holding plate, a plurality of the holding plates including the upper plate and the lower plate are fixed at a plurality of locations with the fasteners, so that the solar cell module is provided. Can be firmly fixed.

According to a third aspect of the present invention, there is provided a solar cell module torsion tester which sandwiches two adjacent sides of a substantially square solar cell module between an upper plate and a lower plate, and clamps the upper plate and the lower plate. To fix the solar cell module, apply stress to the solar cell module with a stress applying device, and continuously measure the electrical resistance between the output terminals of the solar cell module and the insulation resistance between the output terminals and the module frame Therefore, it is known that the degree of torsion at which the break occurs is examined, and the limit of applying stress to the solar cell at the time of transportation, installation, construction and the like of the solar cell module can be understood.
Further, it can be used for improvement of a solar cell module and the like.

[Brief description of the drawings]

FIG. 1 shows an embodiment of the present invention, wherein (a) is an explanatory view showing a plane in use of a solar cell module torsion tester, and (b) is a cross-sectional view taken along line AA of (a). It is.

2A is a plan view showing a state in which a fastener is attached to a holding plate, and FIG. 2B is a side view of FIG.

FIG. 3, showing another embodiment of the present invention, is an explanatory view showing a main part of a use state of a solar cell module torsion tester.

FIG. 4 is an explanatory view showing a modified example of an upper plate and a lower plate sandwiching a solar cell module.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1, 1a Solar cell module torsion tester 2 Holding plate 21 Upper plate 22 Lower plate 3 Holder 4, 4a Stress applying device 5 6a Displacement meter 7, 7a Solar cell module

Claims (3)

[Claims] A solar cell module torsion tester for examining mechanical durability of a solar cell module, comprising:
Opposing surfaces are substantially parallel, and an L-shaped holding plate consisting of an upper plate and a lower plate, which are smooth surfaces, can be fixed by sandwiching the solar cell module between the upper plate and the lower plate. A solar cell module torsion tester comprising: a fastener; and a stress applying device for applying stress to a solar cell module fixed between an upper plate and a lower plate. 2. The fastening device according to claim 1, wherein the fastening device can fasten and fix a solar cell module sandwiched between an upper plate and a lower plate with a screw, and a plurality of the fastening devices are provided on a holding plate. The solar cell module tester according to claim 1, wherein: 3. An almost square solar cell module adjacent two sides is sandwiched between an upper plate and a lower plate of the solar cell module torsion tester according to claim 1 or 2, and the upper plate is fastened with a fastener. And the lower plate are fastened to fix the solar cell module, stress is applied to the solar cell module by a stress applying device, and the electrical resistance between the output terminals of the solar cell module and the insulation resistance between the output terminal and the module frame are continuous. A torsion test method for a solar cell module, wherein the torsion test is performed.