KR101904502B1 - Apparatus for measuring characteristic for solar cell - Google Patents

Abstract

The present invention relates to an apparatus for measuring solar cell characteristics, which comprises an upper first connection part connected to a top surface of a solar cell and a lower first connection part connected to a lower surface of the solar cell, A solar simulator connected to an upper second connection part connected to an upper surface of the solar cell and a lower second connection part connected to a lower surface of the solar cell and measuring a current characteristic of the solar cell; A first switching area connected to the upper first connection part and the lower first connection part to switch the polarity inversely and to be connected to the voltage measurement part, and a second switching part connected to the upper second connection part and the lower second connection part, And a switching unit for performing a switching operation of the first switching area and the second switching area simultaneously according to a switching signal, including a second switching area connected to the current measuring part. Therefore, when the polarity of the solar cell to be measured is opposite to the polarity of the solar cell, it is possible to save time for replacing the solar simulator, thereby reducing the time and cost required for product inspection in the solar cell production line.

Description

[0001] APPARATUS FOR MEASURING CHARACTERISTIC FOR SOLAR CELL [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar cell characteristic measuring apparatus, and more particularly, to an apparatus for measuring electrical characteristics of a solar cell.

The solar simulator 10 used to measure the electrical characteristics of a solar cell formed of a p-type substrate and forming a negative (-) light receiving portion has an electrical characteristic of the p-type solar cell 1 A voltage measuring unit 11 and a current measuring unit 12 are provided for measurement.

1, the voltage measuring unit 11 of the solar simulator 10 includes an upper first connection unit 21 connected to a negative (-) electrode on the front surface of the p-type solar cell 1, Type solar cell 1 and the lower first connection unit 31 connected to the positive electrode of the p-type solar cell 1 to measure the voltage characteristics of the p-type solar cell 1 and measure the current of the solar simulator 10 Type solar cell 1 is connected to an upper second connecting portion 22 connected to the negative electrode of the front portion which is the light receiving portion of the p-type solar cell 1 and a lower second connecting portion 22 connected to the positive electrode of the p- And the connection portion 32 to measure the current characteristics of the p-type solar cell 1.

1, the upper first connecting portion 21 and the upper second connecting portion 31 connected to the (-) pole of the conventional p-type solar cell 1 are connected to the p-type solar cell 1 The lower first connecting portion 22 and the lower second connecting portion 32 connected to the (+) pole of the p-type solar cell 1 can be connected to the (-) pole of the p- -Type solar cell 1 through a characteristic measuring tip to the (+) pole of the solar cell 1.

As described above, the solar simulator 10 can measure the electrical characteristics of the p-type solar cell 1. Recently, the efficiency of the solar cell has been improved and an n-type solar cell having an n-type substrate in addition to a p- Type solar cell, it is necessary to measure the electrical characteristics of the n-type solar cell. Since the device used for measuring the characteristics of the p-type solar cell is designed to be optimized for the polarity of the p-type solar cell, There is a problem in measuring the electrical characteristics of the n-type solar cell formed in the opposite manner.

In the case of a double-sided solar cell having a p-type solar cell and an n-type solar cell at the same time, the polarity of the p-type and the n- There is an inconvenience that the wiring of the current measuring unit 12 must be changed.

Accordingly, since a solar cell is formed as a p-type, n-type, or both-sided type, it is necessary to provide a solar simulator capable of solving the inconvenience of replacing wiring for measuring the electrical characteristics of a solar cell and easily measuring electrical characteristics. to be.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to easily measure the electrical characteristics of the solar cell without changing the wiring even if the polarities of the solar cells are reversed.

An apparatus for measuring solar cell characteristics according to an exemplary embodiment of the present invention includes an upper first connection unit connected to a top surface of a solar cell and a lower first connection unit connected to a lower surface of the solar cell to measure a voltage characteristic of the solar cell A solar simulator including a voltage measuring unit, an upper second connecting unit connected to an upper surface of the solar cell, and a current measuring unit connected to a lower second connecting unit connected to a lower surface of the solar cell to measure current characteristics of the solar cell; A first switching area connected to the upper first connection part and the lower first connection part to switch the polarity inversely and to be connected to the voltage measurement part, and a second switching part connected to the upper second connection part and the lower second connection part, And a second switching region connected to the current measuring unit and performing a switching operation of the first switching region and the second switching region simultaneously according to a switching signal.

And the switching signal for operating the switching unit is a signal input from the outside.

The controller may further include a controller for detecting a change in polarity of the solar cell according to an output value measured by the voltage measuring unit and the current measuring unit to generate a switching signal, And operates in accordance with the switching signal.

The first switching region may include a first point at which the upper first connection portion is drawn, a second point at which the lower first connection portion is drawn, a third point at which the (-) pole portion of the voltage measurement portion is drawn, And a fourth point to be drawn into the negative (+) pole portion, wherein the switching portion switches the upper first connection portion, which is connected from the first point to the third point, And the first switching area is switched by connecting the lower first connection part connected from the second point to the fourth point to the third point from the second point.

The switching signal is generated when the top surface is a (+) pole and the bottom surface is a (-) pole instead of a p-type solar cell whose upper surface is a (-) pole and a lower surface is And the switching unit is operated, or when the n-type solar cell is replaced with the p-type solar cell, the switching unit is operated.

The switching unit is formed of a relay or an electromagnetic contactor, and performs a switching operation according to the switching signal.

And a display unit for outputting the voltage characteristic or the current characteristic measured by the solar simulator.

According to another aspect of the present invention, there is provided an apparatus for measuring solar cell characteristics, comprising: an upper connection unit connected to a solar cell upper substrate; and a lower connection unit connected to a lower solar cell substrate, And a switching unit for switching connection points of the upper connection unit and the lower connection unit. When the polarity of the solar cell is reversed, the connection point between the upper connection unit and the lower connection unit is switched to easily measure the electrical characteristics of the solar cell having the opposite polarity There is an effect that can be.

FIG. 1 is a schematic view showing the structure of the conventional solar cell and the solar simulator.
FIG. 2 is a schematic view illustrating a structure for measuring the characteristics of a solar cell according to an embodiment of the present invention.
3 is a circuit diagram schematically showing the structure of an apparatus for measuring solar cell characteristics according to an embodiment of the present invention.
FIG. 4 is a block diagram illustrating a structure for measuring characteristics of a solar cell according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Hereinafter, an apparatus for measuring solar cell characteristics according to an embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 2, a structure of a solar cell characteristic measuring apparatus according to an embodiment of the present invention will be described. The solar cell characteristic measuring apparatus includes a solar simulator 10 and a switching unit 50.

At this time, the solar simulator 10 has the same configuration as the conventional solar simulator 10 shown in Fig. 1, and includes a voltage measuring unit 11 and a current measuring unit 12. [

At this time, the voltage measuring unit 11 is connected to the upper first connecting unit 21 connected to the upper part of the solar cell 2 and the first lower connecting unit 31 connected to the lower part of the solar cell 2, The electric characteristics of the solar cell 2 as a target, and the voltage characteristics among them are measured.

The current measuring unit 12 is connected to the upper second connecting unit 22 connected to the upper part of the solar cell 2 and the second lower connecting unit 32 connected to the lower part of the solar cell 2, The electrical characteristics of the solar cell 2, in particular the current characteristics, are measured.

2, since the solar cell 2 is an n-type solar cell, unlike the p-type solar cell 1 shown in FIG. 1, the upper surface is formed as a (+) pole, And the polarities to be connected to the voltage measuring unit 11 and the current measuring unit 12 of the solar simulator 10 are formed opposite to each other.

However, since the n-type solar cell 2 has a polarity opposite to that of the p-type solar cell 1, the upper portion of the n-type solar cell 2, which is connected to the voltage measuring portion 11, The connecting portion 21 should be connected to the (+) pole connecting portion, not the (-) pole connecting portion of the voltage measuring portion 11.

Likewise, the upper first and second connection portions 21 and 22 connecting the n-type solar cell 2 and the solar simulator 10, and the wiring of the lower first and second connection portions 31 and 32, Type solar cell 1 shown in FIG. 1, the conventional wiring is switched to the opposite polarity according to the operation of the switching unit 50, The upper first connecting portion 21 connected to the positive electrode of the n-type solar cell 2 is connected to the (+) pole connecting portion of the voltage measuring portion 11 and the lower first connecting portion 21 connected to the (-) pole connection portion of the voltage measuring unit 11, respectively.

Hereinafter, the switching unit 50 for switching the wiring of the first and second connection units 21 and 22 and the first and second connection units 31 and 32 will be described in more detail. The first switching region 51 and the second switching region 52 are reversely formed by the switching signal applied from the first switching region 51 and the second switching region 52, respectively.

In the example shown in FIG. 2, in switching the wirings of the first switching region 51 and the second switching region 52 by the switching signal inputted from the outside by the switching unit 50, the first switching region 51 of the voltage simulator 10 is connected to the negative first portion 21 of the voltage measuring portion 11 of the solar simulator 10 as the switching signal is inputted to the positive electrode portion Lt; / RTI >

The upper first connection part 21 is connected to the first switching part 51 at a first point 51a of the first switching area 51 The switching unit 50 switches the upper first connection unit 21 from the first point 51a to the fourth point 51d in accordance with the switching signal. Switch wiring.

At this time, the switching unit 50 switches the connection of the lower first connection unit 31, which is wired so as to reach the fourth point 51d from the second point 51b of the first switching region 51, The wiring is switched so as to reach the third point 51c from the second point 51b of the first switching area 51. [

The switching part 50 switches the wiring of the first switching area 51 to be opposite to the existing wiring structure in accordance with the switching signal so that the wiring of the voltage measuring part 11 of the solar simulator 10 is fixed Connected to the respective poles (-, +) of the solar cell 2 to be brought into the voltage measuring unit 11 through the switching, even if the polarities of the solar cells 1 and 2 are changed, State can be switched to the opposite pole.

That is, even if the solar simulator 10 is formed to correspond to the polarity of the p-type solar cell 1, even if the solar cell is changed to the n-type solar cell 2, The electric characteristics of the solar cell 2 can be measured by the solar simulator 10 through the switching unit 50 without changing the solar cell 10 to another solar simulator having a different polarity direction, It is possible to save time for replacing with a solar simulator, and it is possible to reduce the time and cost required for product inspection in a solar cell production line.

In the same context, when the solar simulator 10 is connected to the p-type solar cell 1 as shown in Fig. 1 and replaced with the n-type solar cell 2 as shown in Fig. 2, ) Connected to the voltage measuring unit 11 of the solar cell 2 so that the wiring of the connecting part connected to the both poles of the solar cell 2 is changed in the opposite direction.

At this time, the switching unit 50 switches the conventional configuration in which the lower first connection unit 31 passing through the first switching region 51 passes the second point 51b and the fourth point 51d according to the switching signal, Type solar cell 2 so that the lower first connection part 31 connected to the negative electrode of the n-type solar cell 2 is connected to the first connection part 31 of the solar simulator 10 via the third point 51c at the point 51b, To be connected to the (-) pole connection portion of the voltage measuring unit 11.

As the switching unit 50 switches to switch the point passing through the first switching region 51 according to the switching signal, even if the polarity of the solar simulator 10 is reversed due to the replacement of the solar cells 1 and 2, The polarity of the connection portion connected to the voltage measuring portion 11 of the first embodiment can be appropriately changed.

In one example, the switching signal that causes the switching unit 50 to perform the switching operation may be a signal directly input from an external manager for switching the wiring according to the type (p or n) of the solar cell having the opposite polarity.

To this end, a switch button may be further formed outside the solar simulator 10, and a switching signal may be generated by applying an input signal to the switch button.

In another example, the switching signal for causing the switching unit 50 to perform the switching operation is such that the polarity of the solar cells 1 and 2 is reversed, that is, the polarity opposite to that of the solar cell connected to the solar simulator 10 Which is a switching signal generated by sensing that the solar cell is replaced with a solar cell.

At this time, the switching signal is generated when the polarity of the solar cells 1 and 2 connected to the solar simulator 10 is reversed as the measured value input to the voltage measuring unit 11 of the solar simulator 10 is detected as a negative value The solar simulator 10 may further include a control unit for generating a switching signal according to a voltage input to the voltage measuring unit 11. In this case,

3 and 4, the operation of switching the upper first connection part 21 and the lower first connection part 31, which the switching part 50 passes through the first switching area 51 according to the switching signal, A block diagram and a circuit diagram.

Referring to FIG. 3, the solar cell characteristic measuring apparatus according to an embodiment of the present invention further includes a control signal generating unit 60 and a display unit 90.

The control signal generator 60 is connected to the switching device 80, generates a control signal, and transmits the generated control signal to the switching device 80.

In one example, the control signal generating section 60 generates a control signal for controlling the switching device 80 as a computer. At this time, the control signal generating unit 60 generates a control signal for switching the connection state of the connection unit connected to each pole of the solar cell 2 to the opposite polarity.

As described above, the control signal generator 60 may be a controller for automatically generating a switching control signal according to a measured voltage or a manual switch for inputting a manual control signal.

The switching device 80 receives the control signal generated by the control signal generator 60 and switches the connection between the solar cell 2 and the solar simulator 10, And a switching unit 50 shown in FIG.

4, the electrode direction changing unit 70 of the switching device 80 may be formed of a relay or a magnetic contactor mc.

The switching device 80 includes the electrode direction changing part 70 and the switching part 50 and is connected to the solar cell 2 according to the control signal generated by the control signal generating part 60 Controls the connection between the connection portions (21, 22, 31, 32) and the solar simulator (10).

3, the apparatus for measuring solar cell characteristics according to an embodiment of the present invention includes a display unit 90 connected to the solar simulator 10 for outputting characteristics of the solar cell to be measured by the solar simulator 10, ). ≪ / RTI >

2, the structure of the apparatus for measuring solar cell characteristics according to an embodiment of the present invention will be described. The current measuring unit 12 of the solar simulator 10 is connected to the n-type solar cell 2 The solar simulator 10 is connected to the p-type solar cell 1 at this time by connecting the upper second connection unit 22 and the lower second connection unit 32 to measure the current of the n-type solar cell 2. [ Type solar cell 2, that is, when the solar cell is replaced with a solar cell having the opposite polarity, the current can not be measured properly. Therefore, the wiring is reversely switched in the second switching region 52, (10).

More specifically, the switching unit 50 reversely switches the positions of the upper second connection unit 22 and the lower second connection unit 32 passing through the second switching area in response to the generated switching signal, Is connected to the (+) pole of the current measuring part 12 and the lower second connecting part 32 is connected to the (-) pole of the current measuring part 12.

As a result, the p-type solar cell 1 is formed and replaced with the n-type solar cell 2, and the polarity of the upper surface and the polarity of the lower surface are reversed, The current measuring unit 12 can measure the current value of the solar cell 2 by switching the connecting portions 22 and 32 connected to the current measuring unit 12 of the solar simulator 10 in the opposite direction, It is possible to measure the characteristics of the solar cell 2 from the switching of the switching unit 50 without replacing the solar simulator 10 according to the replacement of the battery, thereby reducing the time required for replacing the solar simulator 10 It is effective.

The structure for switching the connection points of the upper second connection part 22 and the lower second connection part 32 through the second switching area 52 of the switching part 50 is shown in FIG. It should be interpreted in the same context as that described with reference to the first switching region 51 and the present invention should not be limited thereby.

In the above description with reference to Fig. 2, the p-type solar cell 1 is connected to the solar simulator 10 to measure the electrical characteristics of the solar cell 1, and the solar cell 2 having the opposite polarity is replaced The connection point 21, 22, 31, 32 is connected to the solar simulator 10 when the solar cell is connected to the solar simulator 10, but in the opposite case, that is, the solar cell 2 is formed of n-type The switching unit 50 can be operated to be connected to the solar simulator 10 in accordance with the polarity of the replaced angular battery 1 even when the switching unit 50 is replaced with the p-type solar cell 1.

As described above, the p-type or n-type solar cells 1 and 2 are formed as double-sided electrodes as shown in Figs. 1 and 2, The characteristics of the solar simulator 10 can be changed without replacing the solar simulator 10 having the opposite polarity even if it is replaced with the solar cell having the opposite polarity according to the operation of the switching unit 50 for switching the connection part connected to the solar simulator 10 It is possible to measure the electrical characteristics of the solar cells 1 and 2, thereby eliminating the need for measurement using the solar simulator 10 for each polarity, and it is possible to reduce inspection time and cost .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

1: p-type solar cell 2: n-type solar cell
10: Solar simulator 11: Voltage measuring unit
12: current measuring part 21: upper first connection part
22: lower first connection part 31: upper second connection part
32: lower second connection part 50: switching part
51: first switching region 52: second switching region

Claims (7)

A voltage measuring unit connected to an upper first connection unit connected to an upper surface of the solar cell and a lower first connection unit connected to a lower surface of the solar cell to measure a voltage characteristic of the solar cell; And a current measuring unit connected to a second connection unit and a lower second connection unit connected to a lower surface of the solar cell, for measuring current characteristics of the solar cell; And
A first switching area connected to the upper first connection part and the lower first connection part to switch the polarity of the first upper connection part and the lower first connection part and to connect the upper first connection part and the lower first connection part to the voltage measurement part, A switching unit that includes a second switching region for connecting the first switching region and the second switching region to the current measuring unit, the switching unit being a relay or an electromagnetic contactor for simultaneously performing switching operations of the first switching region and the second switching region according to a switching signal;
Wherein the switching unit determines that the polarity of the solar cell connected to the solar simulator is reversed as the measured value inputted to the voltage measuring unit of the solar simulator is detected as a negative value, Wherein the solar cell is a solar cell.
The method according to claim 1,
Wherein the switching signal for operating the switching unit is a signal input from the outside. The method according to claim 1,
A controller for detecting a change in the polarity of the solar cell according to an output value measured by the voltage measuring unit and the current measuring unit to generate a switching signal;
Wherein the switching unit operates in accordance with the switching signal generated by the control unit. The method according to claim 1,
The first switching region may include a first point at which the upper first connection portion is drawn, a second point at which the lower first connection portion is drawn, a third point at which the (-) pole portion of the voltage measurement portion is drawn, And a fourth point drawn into the negative (+) pole portion,
The switching unit connects, in accordance with the switching signal, the upper first connection unit connected from the first point to the third point to the fourth point from the first point and from the second point to the fourth point And switches the first switching area by connecting the lower first connection part connected to the third point from the second point. The method according to claim 1,
The switching signal is generated when the top surface is a (+) pole and the bottom surface is a (-) pole instead of a p-type solar cell whose upper surface is a (-) pole and a lower surface is Type solar cell is operated when the switching unit is operated or when the n-type solar cell is replaced with a p-type solar cell to operate the switching unit. delete The method according to claim 1,
Further comprising a display unit for outputting a voltage characteristic or a current characteristic measured by the solar simulator.

Images