KR200455080Y1 - Probe unit for solar cell inspection - Google Patents

Abstract

The present invention relates to a probe unit provided in a solar cell inspection apparatus, wherein the first conductor block, the insulating block, and the second conductor block are sequentially stacked and coupled to each other, and the first conductor block and the second conductor block are arranged in sequence. The insulating coupling portion and the conductive coupling portion are alternately formed so as to be opposite to each other, and the first conductive block and the first conductive block are connected to the insulating coupling portion and the conductive coupling portion so that the probe connected to the bus bar (metal electrode) of the solar cell is penetrated. The second conductor block itself acts as a conductor for measuring the current value or voltage, which eliminates the need for a separate conductor connection for connecting probes, and improves durability and safety as well as easy installation and disassembly of solar cells. It relates to a probe unit for.

Description

Probe unit for testing Solar cell

The present invention relates to a probe unit provided in a solar cell inspection apparatus, comprising a first conductor block and a second conductor block into which a plurality of probes are inserted and coupled to measure a current value and a voltage of a solar cell, wherein the first conductor block is provided. The conductor block and the second conductor block serve as respective conductors for measuring the current value and voltage of the solar cell, thereby eliminating the need for a separate conductor connecting operation for connecting the probes, as well as providing excellent durability and safety. It relates to a probe unit for inspection.

In general, a solar cell is a semiconductor device that converts light energy directly into electrical energy, and processes a silicon wafer to process electrons and holes of different polarities, respectively. It is a photovoltaic cell that produces electrical energy through the movement of electrons by light energy using the principle of photovoltaic power generation by PN bonding by bonding a (negative) type semiconductor and a P (positive) type semiconductor and forming electrodes.

Such a solar cell is a basic element of the smallest unit of a solar cell array (array) composed of a plurality of modules (module) and a solar panel (panel) for power generation.

Conventional silicon-based solar cells are manufactured by manufacturing a substrate (wafer) cut into a thin thickness in the form of a thin plate, and then processing the substrate through various processing processes.

In general, a silicon-based solar cell manufacturing process is a texturing process (surface organization process) for increasing light absorption of the substrate manufactured as described above, and a diffusion process (dope process) for forming a PN junction by laminating an emitter layer of N layers. ), Oxide film removal process to remove impurities from wafer surface, anti-reflective coating process to reduce light reflection loss, front and back electrode printing process, and PN junction separation process to remove part of N layer at outside using laser or etching solution Is done.

Here, the front and rear electrode printing process is to form a metal electrode on the surface of the solar cell for collecting photogenerated charges, and is installed in consideration of light absorption loss and sheet resistance.

Therefore, as illustrated in FIG. 1, a plurality of front electrode grids 2 are stacked on the front surface of the solar cell 1, and a plurality of bus bars collecting charges from the front electrode grids 2 and transmitting them to the outside. (busbar) (5) is installed.

At this time, the ends of the plurality of probes 70 installed in the probe unit are in contact with the busbar 5 to collect current values and voltage characteristics of the solar cell 1 through the probe 70 and then through separate inspection equipment. As a performance evaluation of the solar cell, the photoelectric conversion characteristics are examined.

Conventional probe unit by coupling a plurality of probes spaced at regular intervals to a support block of a predetermined length, by soldering a plurality of leads connected to the probe for connecting the probe for measuring the current value and the probe for measuring the voltage, respectively The current value and the voltage of the solar cell were measured.

However, the conventional probe unit as described above has the following problems.

First, since the wire connection work for electrically connecting a plurality of probes is required, manufacturing is not easy and cumbersome, and there is a problem that the assembly cost is reduced and the manufacturing cost is also increased. By being connected to, it is vulnerable to external shock or vibration, etc., durability and safety has been significantly reduced, and third, there is a problem that the maintenance of the ubiquitous is not easy because the whole must be replaced in case of partial damage or damage.

The present invention has been made to solve the above problems, first, the first and second conductor block itself to act as a respective conductor, by eliminating the separate conductor connection work to improve assembly as well as reduce manufacturing costs Second, by removing the soldering work for connecting the conductors, it is possible to improve the durability and safety against external shock or vibration, and third, the first conductor block, the insulating block and the second conductor block in sequence By combining the laminate, it is possible to provide a solar cell inspection probe unit that can be partially replaced and damaged in case of damage or breakage, and can also reduce the cost.

In order to achieve the above object, the present invention provides a plurality of insulating coupling parts and a conductive coupling part spaced apart from each other along a longitudinal direction, the first conductor block being alternately formed repeatedly, and coupled to a lower end of the first conductor block and the insulating coupling part. An insulating block having a plurality of through holes formed to correspond to the conductive coupling part, and formed in the same structure as the first conductive block and coupled to the lower end of the insulating block, but having an insulating coupling part in a reverse order of the arrangement of the insulating coupling part and the conductive coupling part; And a second conductor block alternately arranged with the conductive coupling part, and a probe penetrated through the insulating coupling part and the conductive coupling part, respectively.

In this case, the insulating coupling portion and the conductive coupling portion of the first and second conductor blocks may be formed through the insertion hole in the central portion so that the probe can be press-coupled.

In addition, the insulating coupling portion may be insulated by inserting a hollow insulator.

Meanwhile, the first conductor block and the second conductor block are preferably made of a gold plated brass material having excellent conductivity.

In addition, the insulating block may be an acrylic material.

As described above, the present invention not only improves the assemblability but also can reduce the manufacturing cost, thereby improving the productivity, and the maintenance is easy and the cost can be reduced. In addition, the durability and safety is improved, there is an effect that can improve the reliability and marketability of the solar cell inspection apparatus.

1 is a perspective view of a solar cell and a probe unit for inspecting a solar cell of the present invention,
FIG. 2 is an exploded perspective view of the probe unit for inspecting a solar cell of FIG. 1;
3 is a partial cross-sectional view of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a perspective view of the solar cell and the subject innovation, Figure 2 shows an exploded perspective view of the subject innovation, Figure 3 shows a partial cross-sectional view of the insulating coupling portion and the energizing coupling portion of the subject innovation.

As shown in FIG. 1, the solar cell 1 is generally provided in a rectangular shape, and the front electrode grid 2 is arranged and deposited at a predetermined interval on the front surface, and the front electrode grid on the front electrode grid 2. A plurality of bus bars 5 serving as passages for collecting and transferring charges from outside are provided.

The front electrode grid 2 and the bus bar 5 are formed by depositing at an appropriate interval and an appropriate number in consideration of light absorption and surface resistance of the solar cell 1.

Therefore, in the solar cell 1, charges generated through light absorption are collected by the bus bar 5 through the front electrode grid 2, and then transferred to the outside to generate electricity.

Meanwhile, the solar cell 1 to be inspected is inspected by being loaded into a separate inspection table (not shown), and as the light source, sunlight is preferable, but a xenon lamp for irradiating similar light may be used.

Here, the performance evaluation of the solar cell 1 according to the present invention is performed as a photoelectric conversion characteristic for measuring the current and voltage characteristics, and after obtaining the output characteristic curve by measuring the current value and voltage of the solar cell 1, This is done by comparing with a baseline.

Meanwhile, the present invention consists of a first conductor block 10, an insulating block 30, a second conductor block 50, and a probe 70.

The first conductor block 10 supports a plurality of probes 70 and includes a support 11 forming a body and a fastening part 12 provided at both ends of the support 11.

The support 11 is provided in a bar shape having a predetermined length (bar) having a predetermined thickness and width, and is provided to ensure a sufficient length so that an appropriate number of probes 70 can be spaced at appropriate intervals.

On the other hand, the support 11 is formed by alternately repeating the insulating coupling portion 15 and the energizing coupling portion 17 to which each probe 70 is coupled alternately.

The support 11 is preferably formed to have a sufficiently thin thickness and width within a limit capable of firmly supporting the plurality of probes 70, and thus the insulating coupling portion 15 and the energizing coupling portion 17 Is preferably provided with a cylindrical shape whose outer diameter is larger than the thickness of the support (11).

In addition, the support 11 is not limited to the rectangular bar shape as shown, and may be provided in various shapes according to the size and shape of the probe 70 to be described below, and also the insulating coupling portion 15 and In addition to the cylindrical coupling portion 17 may be provided in various shapes such as square or pentagon.

Meanwhile, insertion holes 16 and 18 are vertically formed in the centers of the insulating coupling part 15 and the conductive coupling part 17, respectively, and the insertion holes 16 of the insulating coupling part 15 are conductive coupling parts ( The diameter is relatively larger than the insertion hole 18 of 17) and the insulator 20 is inserted therein.

The insulator 20 is to prevent the probe 70 and the support 11 from being electrically connected. The insulator 20 is formed in the form of a hollow round pipe, and a plastic material having excellent insulation may be used.

At this time, the inner diameter of the insertion hole 18 and the insulator 20 of the energizing coupling portion 17 is formed to correspond to the outer diameter of the probe 70 so that the probe 70 can be press-fitted.

Therefore, the probe 70 coupled to the energization coupling unit 17 is electrically connected to the first conductor block 10, and the insulation coupling unit 15 serves as an insulator 20 to insulate the probe. 70 and the first conductor block 10 are not electrically connected.

Meanwhile, the fastening portions 12 at both ends of the support 11 are used to couple the probe unit to a separate jig (not shown) capable of moving the probe unit in the front, rear, up, and down directions. 13) can be screwed into the jig.

In addition, the fastening part 12 may be electrically connected to the test equipment and the conductive wire 80 or the connector such that the charges collected through the probe 70 and the support 11 may be transmitted to the solar cell test equipment installed separately.

On the other hand, the insulating block 30 is coupled to the lower end of the first conductor block 10 serves to electrically insulate the first conductor block 10 and the second conductor block 50 to be described below, the first conductor It is preferable to have the same shape as the block 10 but have a sufficiently thin thickness, and the through holes 35 are formed at positions corresponding to the insertion holes 16 and 18 along the longitudinal direction.

At this time, the through hole 35 may be formed to have the same inner diameter as the insulator 20 and the insertion hole 18.

Meanwhile, the second conductor block 50 is coupled to the lower end of the insulating block 30, and includes a support 51 and a fastening part 52 having the same shape as the first conductor block 10, and the fastening part 52. The fastening hole 53 is formed through.

In addition, the second conductor block 50 is provided with an insulating coupling portion 55 and a conductive coupling portion 57 having the same structure as the insulating coupling portion 15 and the conductive coupling portion 17 of the first conductive block 10. .

Therefore, the same insulator 20 is inserted into and coupled to the insertion hole 56 of the insulating coupling part 55, and the insertion hole 58 having the same diameter as that of the insertion hole 18 is formed in the current coupling part 57.

However, the arrangement order of the insulating coupling portion 55 and the energizing coupling portion 57 of the second conductor block 50 is as shown in FIG. 2, the insulating coupling portion 15 and the first conductive block 10. It is arranged alternately so as to reverse the arrangement order of the energizing coupling portion 17.

That is, in the state in which the first conductor block 10, the insulating block 30, and the second conductor block 50 are sequentially stacked and coupled, the insulating coupling part 15 and the insulating block of the first conductor block 10 ( The through hole 35 of the through hole 35 and the conduction coupler 57 of the second conductor block 50 are positioned on the same center line, and the conduction coupler 17 of the first conductor block 10 and the insulating block ( The through hole 35 of the 30 and the insulating coupling part 55 of the second conductor block 50 are positioned on the same center line.

Here, the first and second conductor blocks 10 and 50 are preferably manufactured by performing gold plating on a brass material having excellent conductivity, but are not limited thereto. Various conductive materials may be used, and the first conductor block 10 may also be used. ) And the insulating block 30 and the second conductor block 50 may be sequentially laminated by using an adhesive or the like.

In addition, the insulating coupling parts 15 and 55 may be insulated by installing an insulating coating or various types of insulating members in addition to the method of inserting and insulating the hollow insulator 20.

Meanwhile, the probe 70 transmits electric charges generated in the solar cell 1 to the first and second conductor blocks 10 and 50 by contacting the bus bar 5 of the solar cell 1 with the ends thereof. And a probe 75 which is elastically slidable in the up and down directions in the 71 and the housing 71.

The probe 70 may be a general type of probe that may elastically pressurize the probe 75 to the surface of the bus bar 5 by incorporating a spring or the like.

The probe 70 presses the housing 71 upward from the lower side of the second conductor block 50 so as to be sequentially inserted into the second conductor block 50, the insulating block 30, and the first conductor block 10. Combine it.

In this case, the probe 70 may be formed of a metal material having excellent conductivity so as to transmit an electrical signal, and may be press-fitted by forming protrusions on the outer circumferential surface of the housing 71.

Therefore, the probe 70 is energized with the first conductor block 10 or the second conductor block 50 only when the housing 71 is inserted and coupled to the insertion holes 18 and 58 of the energization coupling portions 17 and 57. Since it is possibly connected, each of the plurality of probes 70 is optionally electrically connected to the first conductor block 10 and the second conductor block 50.

Hereinafter, a process of inspecting a current value and a voltage characteristic of the solar cell 1 using the probe unit of the present invention will be described.

First, by moving the probe unit so that the probe 70 is located on the bus bar 5 of the solar cell 1 by using a jig, and then moving the probe unit downward, the end of the probe 75 of the probe 70 Elastic contact with the upper surface of the bus bar (5).

 At this time, the charge generated in the solar cell 1 is moved to the probe 70 via the front electrode grid 2 and the bus bar 5, and the charge is transferred to the first conductor block 10 and the second conductor block 50. Only through the conductive coupling parts 17 and 57 will be moved to the first conductor block 10 or the second conductor block 50.

That is, the charge generated in the solar cell 1 is selectively transmitted to the first conductor block 10 and the second conductor block 50 through the probe 70 and then transmitted to the inspection equipment.

Here, the inspection equipment may set one of the first conductor block 10 and the second conductor block 50 to measure the current value, and the other to the voltage measurement.

Therefore, in the present invention, since the first and second conductor blocks 10 and 50 themselves serve as respective conductors to transfer electric charges, a separate conductor connection operation (soldering operation, etc.) for electrically connecting the respective probes 70 is performed. This eliminates the need for) and improves assembly, as well as reduces manufacturing costs, and enables partial replacement in the event of damage or breakage, making maintenance easier and ensuring durability and safety against external shocks and vibrations. will be.

As described above, the above embodiments are merely described as examples for convenience of description, and thus are not intended to limit the utility model registration claims, and various modifications may be made within the technical scope of the present invention.

Explanation of symbols on the main parts of the drawings
1 solar cell 2 front electrode grid
5: busbar 10: first conductor block
11,51 support 12,52 fastening
13,53: Fastening hole 15,55: Insulation coupling part
16,56,18,58: insertion hole 17,57: energized coupling portion
20: insulator 30: insulating block
35: through hole 50: second conductor block
70: probe 71: housing
75: probe 80: lead wire

Claims (5)

A first conductor block 10 having a plurality of insulating coupling parts 15 and a conductive coupling part 17 spaced apart from each other along the length direction and formed repeatedly alternately;
An insulating block 30 coupled to a lower end of the first conductor block 10 and having a plurality of through holes 35 formed to correspond to the insulating coupling part 15 and the conductive coupling part 17;
It is coupled to the lower end of the insulating block 30, and formed in the same structure as the first conductor block 10, the insulating coupling portion (inversely opposite to the arrangement order of the insulating coupling portion 15 and the conductive coupling portion 17) A second conductor block 50 having 55 and an energization coupler 57 alternately disposed; And
A probe 70 penetratingly coupled to the insulating coupling portions 15 and 55 and the conductive coupling portions 17 and 57, respectively;
Probe unit for solar cell inspection comprising a. The method of claim 1,
Insulated coupling portions 15 and 55 and the conductive coupling portions 17 and 57 of the first and second conductor blocks 10 and 50 are respectively formed with insertion holes penetrating through the center thereof so that the probe 70 can be press-fitted. Probe unit for solar cell inspection, characterized in that. The method of claim 2,
Probe unit for solar cell inspection, characterized in that the insulating coupling portion (15,55) by inserting a hollow insulator (20) to insulate. 4. The method according to any one of claims 1 to 3,
The first conductor block 10 and the second conductor block 50 are gold-plated brass, characterized in that the probe unit for solar cell inspection. The method of claim 4, wherein
The insulating block 30 is a probe unit for solar cell inspection, characterized in that the acrylic material is used.

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