KR20110008706A - Apparatus for measuring strength of sunlight module using universal testing machine - Google Patents

Abstract

PURPOSE: An apparatus for measuring the strength of a sunlight module using an universal testing machine is provided to enable a sunlight module of a variety of thickness to be measured using only one device since an improved universal testing machine, in which a separate jig is installed, is supplied. CONSTITUTION: An apparatus for measuring the strength of a sunlight module using an universal testing machine comprises an upper jig(5), a lower jig(6), a displacement measuring device(7) and a load cell. The upper jig is installed on the lower part of an upper ram(3), which is fixed to a support(2), which is installed perpendicularly to the upper part of an universal testing body(1). The upper jig is formed so that the position of an upper support(51), which supports the sunlight module, is varied. The lower jig is installed on the upper part of a lower ram, which is installed to move up and down a support, which is installed perpendicularly to the upper part of the universal testing body. The lower jig is formed so that the position of a lower support(61), which supports the sunlight module, is varied.

Description

Apparatus for measuring strength of sunlight module using universal testing machine

The present invention relates to a photovoltaic module strength measuring device using a universal testing machine, and more specifically, to a photovoltaic module of various thicknesses and other thin plate brittle materials using a universal universal testing machine instead of a dedicated photovoltaic module strength measuring tester. The present invention relates to a measuring device capable of measuring various strengths and loads.

Since solar modules are very thin brittle materials, tensile or compression tests using universal testing machines are not possible when evaluating strength. For this reason, the strength evaluation of solar modules is carried out through a four-point bending test.

That is, the solar module is damaged at relatively low load during the four-point bending test, so it is necessary to purchase a special equipment because it requires precise measuring equipment.

The four-point bending test using the dedicated equipment supports four points of the solar modules with the upper and lower supports above or below, as shown in FIG. 13, and then lowers the upper jig installed with the upper support to apply the compressive force to the solar module to support the upper support. B is a test to evaluate the strength by bending the solar module and measuring the bending and load and deformation amount until the solar module is broken.

Figure 14 shows a conventional dedicated equipment for testing the strength of the solar module, as shown in the lower portion to fix the lower support can be seen that a plurality of holes are formed at a predetermined distance, the hole It can be seen that the two lower supports are supported at the bottom to support the solar module, and the upper solar module has two upper supports installed in the direction intersecting with the lower support. In addition, the upper support is installed in the upper jig formed with a plurality of fixing holes, it can be seen that the upper jig is installed in the lower part of the motor installed in the connection member installed in conjunction with the cylinder to be transported up and down is a structure that the cylinder is transported up and down.

However, the conventional dedicated equipment for strength test of a conventional solar module, such as shown in Figure 14 is very expensive because the price is very expensive, and the measurement load is small, because the measurement load is small, very thin solar light There is a problem that only the module can be tested and there are many difficulties in the test because the distance between the supports for the four-point support is not free.

Therefore, it is possible to measure various thicknesses and loads, freely adjust the distance between supports for four-point support, and there is a need for a relatively inexpensive measuring device using existing equipment. The device is not provided.

An object of the present invention for solving the above problems is to provide a device that can measure all the solar modules having a variety of thickness and load by using a single universal testing machine.

Another object of the present invention is to provide a measuring device that is free to adjust the distance between the support for the four-point support when measuring the solar module.

Another object of the present invention is to provide a multi-purpose measuring device capable of testing not only solar modules but also brittle materials of other thin plates.

The present invention to achieve the object as described above and to perform the problem for eliminating the conventional drawbacks

 An upper jig installed at a lower portion of an upper ram fixed to a support vertically installed on an upper portion of the universal testing base, and configured to vary a position of an upper support for supporting a solar module;

A lower jig installed on an upper portion of a lower ram installed to move a support vertically installed on an upper portion of the universal testing base, and having a variable position of a lower support for supporting a solar module;

A displacement measuring device fixedly installed at one side thereof to interlock when the lower ram is moved up and down;

It is achieved by providing a photovoltaic module strength measurement apparatus using a universal testing machine, characterized in that it comprises a; load cell replaceably installed in the base plate located in the lower portion of the lower jig.

The upper jig is characterized in that the hole is formed in the center to be coupled to the upper ram by a bolt coupling, the long hole machined in a continuous groove so that the position of the upper support.

The lower jig is a linear bush which is fixed to the upper part of the hole so that the lower support position is variable, the long hole machined in a continuous groove, the hole formed to penetrate the guide installed in the base plate, and the guide of the base plate is inserted and lowered stably Characterized in that formed.

The displacement measuring device is coupled to a fixture formed on one side of the lower ram of the universal testing machine, characterized in that the lower ram is configured to measure the displacement while changing the probe length of the upper surface of the universal testing base body as a reference point during the vertical transfer.

The load cell is inserted into the hole of the load cell mount base, characterized in that installed in the base plate.

The base plate is characterized in that it is configured to penetrate the hole formed in the lower jig by inserting two guides in the processed hole.

The present invention provides a universal testing machine that is improved by installing a separate jig in a low-cost or general-purpose device, that is, a universal testing machine that performs tensile and compression tests of general materials, using only one device using a solar module having various thicknesses. With the advantage of being able to measure,

In addition, it is possible to change the load cell for load measurement arbitrarily, and it is possible to measure for various load conditions.

It is possible to test not only photovoltaic modules but also other thin brittle materials.

It is a useful invention having the advantage of being able to freely adjust the distance adjustment between the supports for four-point support when measuring the intensity of the solar module is an invention that is expected to use greatly in the industry.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a perspective view showing the device configuration of the present invention, Figure 2 is an exemplary view showing the position of the main configuration of the present invention is equipped with a universal testing machine, Figure 3 is a top and bottom jig constituting the present invention It is a perspective view shown.

First of all, the universal testing machine used in the photovoltaic module strength measuring apparatus of the present invention is a machine capable of performing various tests on materials such as tensile test, compression test, and bending test. Two vertically installed supports 2 are installed at the top. In the support, the upper ram 3 and the lower ram 4 are respectively installed in the support through holes formed at both sides thereof. The upper ram 4 is fixedly installed on the support, and the lower ram 3 is a universal testing base ( Ascending and descending is carried out by the elevating means (not shown) provided in 1). At this time, the support guides the stable lifting of the lower ram. This universal testing machine is a measuring device commonly used in all industrial sites, and detailed description of the universal testing machine itself is omitted.

The photovoltaic module strength measuring apparatus of the present invention is constructed by using a universal testing machine capable of performing the tensile and compression tests of the above-described general materials, and the upper jig 5 and the lower jig 6 performing the present invention on the universal testing machine. ) Is installed on the upper ram (3) and lower ram (4), respectively. In addition, an upper support 51 is provided on the upper jig, and a lower support 61 is installed on the lower jig to provide a compressive force while supporting the solar modules to be measured from above and below, respectively.

In addition, the lower jig (6) was installed so that the load cell for the load measurement can be arbitrarily changed according to the required load required for measurement, it was configured to enable measurement for various load conditions. In addition, one side of the lower ram was installed to measure the position displacement of the lower ram 4 to move up and down by installing a displacement measuring device (7).

The measuring method is to fix the upper ram (ram. 3) at the top to the support (2), and to move the lower ram (ram) 4 at the bottom along the support (2). At this time, the displacement measuring instrument 7 attached to the lower ram 4 accurately measures the transport distance of the lower ram. When the lower ram rises, the lower support 61 of the lower jig installed on the lower ram compresses and measures the photovoltaic module 9, which is a brittle flake, in which the upper support 51 of the upper jig installed on the upper ram is supported by four points. The bending force data is measured until the breakdown point reaches the yield point after the solar module material, the target specimen, is elastically deformed.

At this time, the lower jig is installed under the load cell for precise load measurement to measure the load at the time of compression.

Figure 4 is an exploded perspective view showing the structure of the lower jig constituting the present invention, Figure 5 is a cross-sectional view showing the mounting structure of the lower jig constituting the present invention, Figure 6 is a groove formed in the lower jig constituting the present invention It is a perspective view showing the coupling structure between the lower supports installed.

As shown, the lower jig 6 installed a load cell 8 on a base plate 81 installed in the lower ram of the universal testing machine for very precise measurement. In order to stabilize the load cell during installation, the load cell is mounted in the hole 821 using a load cell mount base 82 having a hole 821 corresponding to the load cell, and is installed by bolting to the base plate 81.

In addition, two guides 83 are formed by processing the holes 811 in the base plate 81 so that the load of the lower jig 6, that is, the load generated when the solar module is compressed, is vertically transmitted to the load cell 8. Install it. Similarly, holes 62 were also machined in the lower jig 6 so that the guide 83 was penetrated.

In addition, when the guide 83 is raised and lowered, the stable rising and lowering was performed, and the linear bush 63 was fixed by bolt coupling in the upper axial direction of the hole 62 formed in the lower jig 6 to measure the precise load. Accordingly, the guide can be precisely conveyed, and thus the measurement value of the load cell can be precise, thereby enabling reliable measurement.

In addition, the lower jig 6 of the present invention provided a lower support 61 with various radii to form a long hole 64 processed into a continuous groove to support the solar module. Accordingly, after the lower support 61 is installed at various radii, the lower support is fixed to the lower support at the lower part of the long hole 64 so that the lower support is freely installed at various positions. Such various position adjustments enable the testing of photovoltaic modules of various sizes.

In addition, the load cell used in the present invention can be arbitrarily replaced according to various loads, in the drawings shows a load cell for 100N as an example. Since the load cell can be replaced as described above, the measuring device of the present invention enables measurement for various load ranges.

Figure 7 is a perspective view showing a coupling structure between the upper support provided in the groove formed in the upper jig constituting the present invention.

As shown, the upper jig 5 of the present invention installed the upper support 51 at various radii to form a long hole 52 processed into a continuous groove to support the solar module. Accordingly, after the upper support 51 is installed at various radii, the upper support may be freely installed at various positions by fixing the upper support with a nut at the upper part of the long hole 52. Such various position adjustments enable the testing of photovoltaic modules of various sizes.

In addition, a hole 53 is formed at the center of the upper jig so that the bolt penetrating the upper jig is coupled to the upper ram 3 of the universal testing machine.

8 is a photograph showing a position where the displacement measuring instrument constituting the present invention is installed in the universal testing machine, and FIG.

As shown in the figure, the displacement measuring unit 7 bolted the coupling 10 to one side of the lower ram of the universal testing machine for precise displacement measurement, and then fixed the displacement measuring instrument to the fixing stand. The reference point of the displacement measuring instrument was fixed on the upper surface of the universal testing base (1). In this way, the lower ram is measured during displacement while the length of the probe 71 of the displacement measuring instrument is changed during the vertical movement.

10 is an exemplary view showing a measurement processing system by the intensity measurement test of the solar module using the present invention, Figure 11 is an illustration showing the bending state of the solar module according to the strength measurement test of the solar module according to the present invention. 12 is a comparative view showing measurement data of the present invention and the conventional dedicated equipment.

As shown in FIG. 1, the load and displacement data from the load cell and the displacement gauge were measured using a data acquisition system called UCAM60. It can be seen that the solar module is bent as shown in FIG. 11 as the lower ram rises, and when this condition is further progressed, the solar module is broken due to brittleness of the solar module. If you look at the load graph, you can see that the graph has fallen perpendicularly past the top yield point in the upper right corner. In the two graphs of FIG. 12, the horizontal axis represents a change in displacement until breakage of the solar module measured by the displacement measuring unit 7, and the vertical axis represents a change in load until breakage of the solar module measured through the load cell 8. to be. When the flexural strength of the photovoltaic module is large, breakage occurs under a large load state, whereas when the strength is small, the breakage occurs under a small load state, and thus the flexural strength of the photovoltaic module is compared with the displacement-load graph. Can be evaluated. In addition, it is possible to evaluate the brittleness of the solar module by comparing the displacement amount. That is, the photovoltaic module which breaks at a large displacement amount has a small brittleness, and the solar module which has a breakage at a small displacement amount has a large brittleness.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is a perspective photograph showing a device configuration of the present invention,

2 is an exemplary view showing a position of the main configuration of the present invention is equipped with a universal testing machine,

3 is a perspective view showing the upper and lower jig constituting the present invention,

Figure 4 is an exploded perspective view showing the structure of the lower jig constituting the present invention,

5 is a cross-sectional view showing a mounting structure of the lower jig constituting the present invention,

Figure 6 is a perspective view showing a coupling structure between the lower support provided in the groove formed in the lower jig constituting the present invention,

Figure 7 is a perspective view showing a coupling structure between the upper support provided in the groove formed in the upper jig constituting the present invention,

8 is a photograph showing the position where the displacement measuring instrument constituting the present invention is installed in the universal testing machine,

9 is an exemplary view showing a state in which the displacement measuring instrument constituting the present invention is transferred to the universal testing machine up and down,

10 is an exemplary view showing a measurement processing system by the strength measurement test of the solar module using the present invention,

11 is an exemplary view showing a bending state of the solar module according to the strength measurement test of the solar module according to the present invention,

12 is a comparison view showing the measurement data of the present invention and the conventional dedicated equipment,

13 is an exemplary view showing a four-point bending test for measuring the intensity of the solar module,

14 is a dedicated equipment for testing the strength of a conventional solar module.

<Description of the symbols for the main parts of the drawings>

(1): universal testing base body (2): support

(3): upper ram (4): lower ram

(5): Upper jig (6): Lower jig

(7): displacement measuring instrument (8): load cell

(9): solar module (10): holder

(51): upper support (52, 64): long hole

(53, 62, 811, 821): Hole 61: Lower support

(63): Linear Bushing (71): Probe

(81): Base Plate (82): Load Cell Mount Base

83: Guide

Claims (6)

 The upper jig (5) is installed in the lower portion of the upper ram (3) fixed to the support (2) vertically installed on the upper part of the universal testing base (1), the position of the upper support (51) for supporting the solar module is variable )Wow; The lower portion is installed on the upper portion of the lower ram (4) installed so as to move the support (2) vertically installed on the upper portion of the universal testing base (1), the lower portion formed so that the position of the lower support 61 for supporting the solar module is variable Jig 6; A displacement measuring device (7) fixedly installed at one side thereof so as to interlock when the lower ram is moved up and down; Device for measuring the strength of the solar module using a universal testing machine, characterized in that it comprises a; load cell (8) replaceably installed in the base plate (81) located in the lower portion of the lower jig (6). The method according to claim 1, The upper jig 5 has a long hole 52 is formed into a continuous groove so that the position of the upper support 51 is variable, and the hole 53 is formed in the center to be coupled to the upper ram 3 by bolting Photovoltaic module strength measurement device using a universal testing machine, characterized in that. The method according to claim 1, The lower jig 6 includes a long hole 64 formed by continuous grooves so that the position of the lower support 61 varies, a hole 62 formed to pass through the guide 83 installed in the base plate 81, and a base. Solar module strength measuring apparatus using a universal testing machine, characterized in that the guide (83) of the plate (81) is inserted is formed in a linear bush (63) fixed to the upper portion of the hole (62) so as to move up and down stably. The method according to claim 1, The displacement measuring unit 7 is coupled to the fixed base 10 formed on one side of the lower ram of the universal testing machine, the length of the probe 71 as a reference point to the upper surface of the universal testing base 1 when the lower ram is transported up and down Solar module strength measuring device using a universal testing machine, characterized in that configured to measure the displacement while changing. The method according to claim 1, The load cell (8) is inserted into the hole (821) of the load cell mount base 82, the solar module intensity measuring apparatus using a universal testing machine, characterized in that installed in the base plate (81). The method according to claim 1, The base plate 81 is installed by inserting two guides 83 into the machined hole 811 to penetrate the hole 62 formed in the lower jig 6, the solar module using a universal testing machine Strength measuring device.

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