KR101604430B1 - Method and Apparatus of Inspecting Electroluminescence of Solar Module at Day and Outdoor - Google Patents

Abstract

In a daytime outdoors, an apparatus for inspecting an image of a solar cell module is provided with a power supply which is electrically connected to both ends of a solar cell module and supplies power having a predetermined period and waveform to the solar cell module as a turn- Device; An image detector for detecting a first image signal generated in the solar cell module when the turn-on is turned on and a second image signal generated in the solar cell module when the turn-off is passed through a band-pass filter in a specific frequency band; A signal generator for calculating a difference image signal from which the second image signal is removed from the first image signal received from the image detector and for amplifying and outputting the difference image signal; And a controller receiving the output difference image signal as a detection signal to determine internal defect information of the solar cell module and outputting the information.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus and method for inspecting an image of a solar cell module in a daytime and outside the daytime,

The present invention relates to an apparatus for inspecting an image of a solar cell module, and more particularly, to an apparatus and method for inspecting an image of a solar cell module during a daytime outdoors, in which an internal image of the solar cell module is inspected will be.

Solar cells are generally produced on the basis of a polycrystalline silicon substrate or a polycrystalline silicon substrate, and then subjected to quality information inspection prior to product shipment.

This quality information inspection method is mainly used in an EL (Electroluminescence) image acquisition inspection method of inspecting the quality of a solar cell using the characteristic of generating light when a solar cell is supplied with power.

The EL image acquisition inspection method is a method of measuring an electroluminescent image generated by applying a DC power to both ends of a solar cell with a camera.

The EL image acquisition inspection method has a problem in that when acquiring an electroluminescence image for inspecting defects of an outdoor photovoltaic module, there is a time limitation in obtaining an electroluminescent image in the sun-free night, It is necessary to take out and take it to the dark room environment to acquire an electroluminescent image, which is costly and has a limitation on the inspection.

In order to solve such problems, the present invention provides an apparatus and method for inspecting a light emitting image of a solar cell module in a daytime outdoors, in which a light emitting image of the solar cell module is taken outdoors during the daytime and an internal defect of the solar cell module is inspected .

According to an aspect of the present invention, there is provided an apparatus for inspecting a light emitting image of a solar cell module in a daytime outdoors,

A power supply unit electrically connected to both ends of the electrode of the solar cell module and applying power having a predetermined period and waveform to the solar cell module as a power control signal of turning on or off;

An image detector for detecting a first image signal generated in the solar cell module when the turn-on is turned on and a second image signal generated in the solar cell module when the turn-off is passed through a band-pass filter in a specific frequency band;

A signal generator for calculating a difference image signal from which the second image signal is removed from the first image signal received from the image detector and for amplifying and outputting the difference image signal; And

And a control unit receiving the output difference image signal as a detection signal to determine internal defect information of the solar cell module and outputting the information.

A method of inspecting a light emitting image of a solar cell module in a daytime outdoors according to an aspect of the present invention includes:

Applying a power control signal of a turn-on or a turn-off to a solar cell module by a power supply device electrically connected to both ends of the solar cell module and supplying power having a predetermined period and waveform;

A first image signal generated at a solar cell module at a turn-on time and a second image signal generated at a solar cell module at a turn-off time are detected by a video camera through a band-pass filter having a specific frequency band;

The signal generator for receiving the first image signal and the second image signal calculates a difference image signal from which the second image signal is removed from the first image signal, amplifies and outputs the difference image signal, And

And receiving the output difference image signal as a detection signal to determine internal defect information of the solar cell module and output the information.

According to the above-described configuration, the present invention can be applied to a solar cell module installed in a daytime or outdoors, without being time-consuming when inspecting an internal defect of the solar cell module, .

FIG. 1 is a view showing a configuration of an apparatus for inspecting a light emitting image of a solar cell module in a daytime outdoors according to an embodiment of the present invention.
2 is a block diagram briefly showing a configuration of a signal generator according to an embodiment of the present invention.
3 is a diagram illustrating a method of inspecting a light emitting image of a solar cell module in a daytime outdoors 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.

In the whole, when an element is referred to as "including" an element, it means that it can include other elements, not excluding other elements unless specifically stated otherwise.

FIG. 1 is a block diagram of an apparatus for inspecting a light emitting image of a solar cell module in a daytime outdoors according to an embodiment of the present invention, and FIG. 2 is a block diagram briefly showing a configuration of a signal generator according to an embodiment of the present invention.

The light emitting image inspection apparatus of the daytime outdoor photovoltaic module according to the embodiment of the present invention includes a power supply 100, a bandpass filter 120, an image detector 130, a signal generator 140, and a controller 150 do.

The power supply device 100 is connected to both ends of an electrode of a solar cell module 110 to be inspected and applies an alternating voltage or current having a predetermined period to generate alternating electric fields It is an AC power supply capable of driving light emission.

The band-pass filter 120 transmits light of a specific frequency band from the light emitted from the solar cell module 110. Here, the specific frequency band corresponds to the electroluminescence frequency of the solar cell, and in the case of the crystalline silicon solar cell, it represents the frequency range of 1000 nm to 1200 nm.

In other words, the band-pass filter 120 is an apparatus for transmitting light of a specific frequency band corresponding to the electroluminescent frequency of the solar cell and suppressing light of the remaining frequency band, thereby reducing noise and acquiring an electroluminescent signal.

The band-pass filter 120 may receive light directly from the sun or may receive light reflected by the solar cell module 110.

The image detector 130 receives the electroluminescent image passed through the band-pass filter 120 on a pixel-by-pixel basis using the video camera 132 and outputs the video signal (analog video signal or digital And a frame grabber 134 for digitizing and outputting or storing a video stream (e.g., a video stream) per bit defined per sample.

The video camera 132 is an apparatus for photographing an image signal from the solar cell module 110 and is composed of one or a plurality of cameras and transmits the acquired image signal to the frame grabber 134 and the signal generator 140.

The image detecting unit 130 detects an electroluminescent image passing through the band pass filter 120 from the solar cell module 110 when the power is on for each pixel of the solar cell module 110, The electro-luminescence image passing through the band-pass filter 120 is detected from the solar cell module 110. [

The signal generator 140 is electrically connected to the image detecting unit 130 and the power supply unit 100 and transmits a switching control signal for turning on and off the applied voltage to the solar cell module 110 to the power supply unit 100 The video camera 132 of the image detection unit 130 is activated to control the imaging control signal for acquiring the image signal and the switching control signal to be in synchronization with each other. The synchronization control synchronizes the photographing control signal and the switching control signal by using an internal phase detection circuit.

When receiving the turn-on switching control signal from the signal generator 140, the power supply apparatus 100 generates a power-on signal for turning on the solar cell module 110 in synchronization with the rise of the clock signal CLK And transmits it to the solar cell module 110.

When the power supply apparatus 100 receives the turn-off switching control signal from the signal generator 140, the power supply apparatus 100 outputs a power-off signal for turning off the solar cell module 110 in synchronization with the falling of the clock signal CLK And transmits it to the solar cell module 110.

In other words, the signal generator 140 controls the power supply 100 to turn on / off the voltage applied to the solar cell module 110, and simultaneously controls the video camera 132 to turn on the solar cell module 110 ) And an image signal when the solar cell module 110 is off (Off).

The signal generator 140 receives the first image signal of the solar cell module 110 and the second image signal of the solar cell module 110 from the video camera 132 and removes the second image signal from the first image signal Generates a detection signal, and amplifies and outputs the detection signal in a cumulative manner. Here, the signal generator 140 may be any device capable of amplifying a detection signal obtained by removing the second image signal from the first image signal, and may be a known device such as a lock-in amplifier.

In other words, when the first image signal and the second image signal are multiplied, the signal generator 140 converts the sum frequency component and the difference frequency component, and when the sum frequency component is removed by the low-pass filter, And outputs the detection signal to the control unit 150. [

Here, the first image signal is a pixel image signal including an image signal formed by projecting an electro-luminescence image signal and solar light to the solar cell module 110 as a pixel image signal acquired from the solar cell module 110 in a power- And the second image signal represents an image signal formed by projecting the solar light to the solar cell module 110 as a pixel image signal acquired from the solar cell module 110 whose power is off.

The signal generator 140 includes a signal synchronization unit 142, a signal channel unit 144, an operation unit 146, and an amplification unit 148.

The signal synchronizing unit 142 synchronizes the timing of turning on or off the power supplied to the solar cell module 110 and the timing of detecting the first image signal and the second image signal, And controls the feeding device 100. [

The signal channel unit 144 includes various types of filters such as a low pass filter and a band pass filter and properly filters and amplifies a received image signal mixed with noise to obtain an optimal sensitivity. There is a built-in circuit to remove the offset. The process of amplification is to select the maximum value by the mixer to improve the sensitivity. In the process using the filter, the ripple is removed from the final output value by removing the frequency signal other than the frequency signal to be detected. So that the alternating signal is switched by the mixer.

The arithmetic operation unit 146 is composed of a phase detection circuit and an arithmetic unit and performs arithmetic operation by comparing the first image signal with a second image signal which is a reference signal. The arithmetic unit 146 performs arithmetic operation on the difference image signal from which the second image signal is removed from the first image signal do.

Here, the differential image signal means an electroluminescent image signal obtained by the solar cell module 110 in which the background noise, which is an image signal formed by projecting sunlight to the solar cell module 110, is suppressed and the power is on.

The amplification unit 148 accumulates and amplifies the calculated difference video signal by more than a predetermined number of times, and transmits the amplified difference video signal to the control unit 150.

The control unit 150 electrically connects the image detector 130 and the signal generator 140 and transmits a control signal for controlling the image detector 130 and the signal generator 140, Signal, and determines the quality of the solar cell module 110, and outputs the defect information and the quality determination result as a digital signal.

The conventional method of inspecting the light emitting image of the solar cell module 110 is performed at night or after removing the solar cell module 110 and arranging the cell module 110 in a dark room environment. However, the present invention is applicable to the band pass filter 120, It is advantageous to perform the EL image acquisition test even in the daytime outdoors by using the signal generator 140, the video camera 132, and the power supply device 100.

A method of inspecting an electroluminescent image by applying an alternating voltage or an alternating current to the solar cell module 110 may be carried out without separating the solar cell module 110 installed outdoors during the daytime, , Hot spots, etc., as well as inspections can be performed at lower cost, safe, fast, and precise.

3 is a diagram illustrating a method of inspecting a light emitting image of a solar cell module in a daytime outdoors according to an embodiment of the present invention.

The power supply device 100 is electrically connected to both ends of the electrode of the solar cell module 110 to generate a power control signal for turning on or off and supplying the power control signal to the solar cell module 110 (S100).

The signal generator 140 generates a turn-on switching control signal or a turn-off switching control signal and transmits the turn-on switching control signal or the turn-off switching control signal to the power supply unit 100, , And at the same time synchronizes the time of detecting the image signal (the first image signal or the second image signal) with the video camera 132.

The video camera 132 passes through the band pass filter 120 of a specific frequency band when the second image signal generated in the solar cell module 110 when the first video signal generated in the solar cell module 110 is turned off when the video camera 132 is turned on (S102).

The video camera 132 transmits the detected first image signal and the second image signal to the signal generator 140.

The signal generator 140 calculates a difference image signal from which the second image signal is removed from the first image signal, and accumulates and amplifies the difference image signals over a predetermined number of times in units of pixels (S104).

The signal generator 140 transmits the amplified difference image signal to the controller 150. The controller 150 receives the amplified difference image signal as the detection signal to determine the internal defect information of the solar cell module 110 and outputs the information (S106).

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

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.

100: Power supply
110: solar cell module
120: Bandpass filter
130:
132: Video camera
134: frame grabber
140: Signal generator
142:
144: Signal channel section
146:
148:
150:

Claims (9)

A power supply device electrically connected to both ends of the electrode of the solar cell module and applying power having a predetermined period and waveform to the solar cell module with a power control signal of turning on or off;
An image detector for detecting a first image signal generated in the solar cell module at the time of the turn-on and a second image signal generated at the solar cell module at the time of the turn-off through the band-pass filter of a specific frequency band;
A video camera for photographing an image signal from the solar cell module;
Controlling the power supply device to turn on and off an applied voltage of the solar cell module and controlling the video camera to simultaneously turn on the first image signal when the solar cell module is turned on and the second image signal when the solar cell module is off, A signal generator for controlling to detect an image signal and calculating a difference image signal from which the second image signal is removed from the first image signal received from the image detector, and for amplifying and outputting the difference image signal;
An amplifying unit for amplifying the difference video signal by a predetermined number of times or more in units of pixels and for transmitting the amplified difference video signal; And
And a controller receiving the amplified difference image signal as a detection signal to determine internal defect information of the solar cell module and outputting the information,
Wherein the first image signal is a pixel image signal including an image signal formed by projecting an electroluminescence image signal and solar light to the solar cell module as a pixel image signal acquired from the solar cell module in a power- 2 image signal represents an image signal formed by projecting solar light to the solar cell module as a pixel image signal acquired from the solar cell module in a power off state and the difference image signal is obtained by projecting solar light onto the solar cell module Wherein a specific frequency band of the band-pass filter is a frequency band corresponding to an electric-field emission frequency of the solar cell module, The light emitting image inspection device of the solar cell module in the daytime outside the daytime. The method according to claim 1,
Wherein the signal generator controls the image detecting unit and the power supply unit to synchronize the time when the power is applied to the solar cell module and the time when the first image signal and the second image signal are detected, And a synchronizing unit, in the daytime and outside the daytime. delete delete delete delete delete delete delete

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