KR101776159B1 - Sunlight Generation System having Connection Band For increasing lifetime in Solor cell module - Google Patents

Abstract

The present invention relates to a solar power generation system having a connection panel capable of extending the service life of a solar cell module that prevents the PID (Porous Induced Degradation) of the solar cell module to extend the life of the solar cell module, A power converter for converting the power generated by the solar cell module into a power corresponding to the system; and a power conversion unit for converting power generated by the solar cell module into power supplied to the solar cell module, An insulation resistance detection unit configured to detect an insulation resistance flowing through the anode and the cathode terminals of the solar cell module; And a voltage / current detection unit configured to detect voltages and currents flowing through the positive and negative terminals of the solar cell module, And an insulation resistance detection unit for detecting the presence or absence of an abnormality in the solar cell module, and determining whether the power conversion unit is operated by receiving the voltage / current detected by the voltage / current detection unit And a PID compensator for compensating the PID of the solar cell module by applying positive (+) voltage to the positive and negative terminals of the solar cell module when the power conversion unit does not operate under the control of the control unit .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a solar power generation system having a connection module capable of extending the service life of a solar cell module,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar power generation system, and more particularly, to a solar power generation system in which a solar cell module having a connection half capable of prolonging the life of a solar cell module that prevents the PID (Porous Induced Degradation) Power generation system.

The pollution of the global environment and the depletion of fossil energy sources have already become a matter of considerable concern and become an important threat to humanity. As a result, efforts were made to reduce environmental pollution across countries and races, and to find environment-friendly renewable energy sources.

Renewable energy is the energy source that is expected to become a center for the paradigm shift of new energy. Especially, among the renewable energy, the photovoltaic power generation system is the development method closest to practical use.

The amount of solar energy poured into the entire earth in one year is approximately 9.5 × 1020 kcal, and the magnitude of this amount is equivalent to more than 10,000 times of the amount of energy consumed in a year in the world.

Solar power systems use solar energy, so they do not need to pay for fuel, and there is no air pollution or waste. In addition, it is easy to automate or automate the system so that the cost of operation and maintenance can be minimized. In addition, the photovoltaic power generation system has a peak power generation time zone similar to the summer peak power consumption time zone, It has been attracting attention as a power supply source that can effectively utilize the domestic resources by installing various types of buildings and roofs of houses and buildings, which can solve the imbalance of power supply and demand during the connection operation with the power system for residential buildings.

Photovoltaic power generation is currently experiencing a huge boom in the world, with an annual trend of more than 30% to 40%. In recent 2 ~ 3 years, it shows a remarkable increase trend, and it seems that the raw material shortage of silicon solar cell, which dominates the current 85% of the solar industry, has appeared.

In Korea, the accumulated PV system installed by 2003 was only 6MW. However, the supply of PV systems began to increase rapidly in 2004, and in 2005, a PV system of about 6 MW was installed in the year. According to the survey conducted by the World Energy Agency, Korea showed the second highest increase in the demand for PV systems after Germany, which has the most recent increase among the IEA member countries.

As described above, the photovoltaic device, which is attracting attention as a future renewable energy source, converts light energy incident from the sun into electric energy, collects the collected electric energy, and stores the collected electric energy. Energy is converted into alternating current energy and input to the transformer.

In such a photovoltaic power generation apparatus, a plurality of light collecting plates for collecting sunlight to be incident are provided, and each of the light collecting plates is provided with the above-described photovoltaic power generation system.

On the other hand, in order to prevent a circuit from being damaged by an electric shock in which a sudden voltage or current is generated which is unexpected in a photovoltaic power generation device, and to prevent unbalanced power generation characteristics of the condenser due to other factors such as changes in the surrounding environment Protection devices.

The protection device includes reverse voltage prevention means including a reverse voltage prevention diode for protecting a circuit at an input / output terminal by blocking a current flowing in a reverse direction, and a reverse voltage prevention means for detecting a power voltage and a current generated through the solar battery panel, It consists of a voltage and current measurement sensor to monitor and an overcurrent protection fuse that protects the circuit by cutting off the overcurrent. It is mainly composed of a connection panel installed between the photovoltaic power generation unit and the load or the central control unit.

With the recent spread of photovoltaic power generation, power systems such as megasolar are becoming large-scale, and there is also a trend toward higher voltage of the system voltage for the purpose of lowering the transmission loss. As the system voltage rises, the potential difference between the frame and the cell becomes large in the solar cell module.

That is, since the frame of the solar cell module is generally grounded, when the system voltage of the solar cell array becomes 600V to 1000V, the potential difference between the frame and the cell becomes 600V to 1000V So that power generation during the daytime can be maintained while the high voltage is applied.

In addition, the glass has a lower electrical resistance than the solar cell sealing material, and a high voltage is generated between the glass and the cell through the frame. That is, under the situation of developing during the daytime, the potential difference between the cell and the module and between the cell and the glass surface sequentially increases from the ground side in series-connected solar cell modules, and the high voltage potential difference of the system voltage is maintained almost at the largest. Among the solar cell modules used in such a state, there is also reported an example of a module using a crystal power generation device in which the output significantly decreases and PID (abbreviated as Potential Induced Degradation) phenomenon occurs in which characteristic deterioration occurs.

The PID phenomenon refers to the phenomenon that when the solar cell module is exposed to high temperature and high humidity environment, the insulation of the module is abruptly deteriorated due to the high voltage current applied to the module, and the output of the module is seriously degraded. This is due to various reasons, among which the insulating properties of the encapsulant used in the solar cell module are poor.

Accordingly, techniques for overcoming the PID generated in the solar cell module from the viewpoint of long-term reliability of the solar power generation system are being studied.

In order to solve the above-mentioned problem, the present invention provides a solar cell module in which a positive (+) voltage is applied to the (+) and (- The present invention aims to provide a solar power generation system having a connection panel capable of extending the service life of a solar cell module that increases the lifetime of the entire solar cell module by suppressing the PID of the solar cell module, have.

The present invention also provides a method and apparatus for controlling the operation of a power conversion unit (PCS) by stopping a power conversion unit (PCS) at regular intervals or at regular intervals for stable operation of a user and a power conversion unit Another object of the present invention is to provide a photovoltaic power generation system having a connection panel capable of extending the service life of a solar cell module for supplying electric power.

According to an aspect of the present invention, there is provided a photovoltaic power generation system including a connection panel capable of extending the lifetime of the solar cell module. The photovoltaic power generation system includes a photovoltaic And a power conversion unit configured to convert the power generated by the solar cell module into a supply power corresponding to the system, and a power conversion unit configured between the solar cell module and the power conversion unit, And an insulation resistance detecting unit configured to detect an insulation resistance flowing in the positive and negative terminals of the solar cell module, the insulation resistance detection unit being formed in the connection panel, A voltage / current detection unit for detecting a voltage and a current; A control unit for determining the presence or absence of an abnormality of the solar cell module and determining whether the power conversion unit is operated by receiving the voltage / current detected by the voltage / current detection unit; And a PID compensator that compensates the PID of the solar cell module by applying a positive voltage to the positive and negative terminals of the solar cell module when the solar cell module is not in use.

The photovoltaic generation system having the connection panel capable of extending the service life of the solar cell module according to the present invention has the following effects.

First, it suppresses the PID of the solar cell module by applying positive (+) voltage to the positive (+) and negative (-) terminals of the solar cell module when the photovoltaic Thereby extending the lifetime of the entire solar cell module and improving the power generation efficiency.

Secondly, for stable operation of the user and the power conversion unit, the power conversion unit PCS is stopped at a predetermined time or at regular intervals to measure the insulation resistance, and by checking the operation of the power conversion unit, .

Third, the voltage and current output from the solar cell module are measured to check the operation of the power converter. When the inverter is not in operation, the positive (+) voltage is applied to the positive and negative terminals of the solar cell module, It is possible to prevent the lowering of the power generation efficiency by proceeding without a negative stop.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view for explaining one solar cell module in a solar power generation system having a connection half capable of extending the service life of the solar cell module according to the present invention. FIG.
FIG. 2 is a flow chart for explaining the operation of the PID compensator in FIG. 1; FIG.
FIGS. 3A and 3B are views before and after a PID phenomenon occurs in a solar cell module, respectively. FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be noted that the drawings denoted by the same reference numerals in the drawings denote the same reference numerals whenever possible, in other 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. And certain features shown in the drawings are to be enlarged or reduced or simplified for ease of explanation, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

FIG. 1 is a view illustrating an embodiment of a solar cell module in a photovoltaic generation system having a connection panel capable of extending the life of the solar cell module according to the present invention.

As shown in FIG. 1, a solar power generation system having a connection panel capable of extending the life of the solar cell module according to the present invention is constructed such that electric power generated by incident solar light is supplied to the positive (+) terminal 111 and the negative A power conversion unit 130 for converting the power generated by the solar cell module 110 into a power corresponding to the system, A connection unit 120 provided between the solar cell module 110 and the power conversion unit 130 to supply the power generated by the solar cell module 110 to the power conversion unit 130, An insulation resistance detection unit 121 provided in the connection unit 120 and detecting an insulation resistance flowing to the positive (+) terminal 111 and the negative (-) terminal 112 of the solar cell module 110, The voltage and current flowing through the positive (+) and negative (-) terminals 111 and 112 of the solar cell module 110, And a voltage / current detection unit 122 for detecting the presence or absence of an abnormality in the solar cell module 110 by receiving the insulation resistance detected by the insulation resistance detection unit 121. In addition, A control unit 123 receiving the voltage / current from the power conversion unit 130 and determining whether the power conversion unit 130 is operated or not; And a PID compensator 124 for applying a positive voltage to the positive (+) and negative (-) terminals 111 and 112 of the module 110 to compensate the PID of the solar cell module 110, do.

The controller 123 can grasp the leakage current of the solar cell module 110 based on information of the insulation resistance detected through the insulation resistance detector 121. [ That is, the information about the insulation resistance detected by the insulation resistance detection unit 121 is applied to the control unit 124, and the control unit 123 analyzes the insulation resistance value to determine the leakage current of the solar cell module 110 .

The voltage / current detection unit 122 detects the voltage and current of the solar cell module 110 in real time by the voltage / current detection unit 122, The information detected by the voltage / current detector 122 is transmitted to the controller 123.

The controller 123 analyzes the information detected by the voltage / current detector 122 and analyzes the power generation state of the solar cell module 110. When the solar cell module 110 is not powered up, 124 to apply a positive voltage to the positive (+) terminal 111 and the negative (-) terminal 112 of the solar cell module 110, respectively, Prevent PID phenomenon.

A relay switch 125 is formed between the solar cell module 110 and the PID compensator 124. The controller 123 analyzes voltage / current information detected by the voltage / current detector 122, (+) And negative (-) terminals 111 and 112 (-) of the solar cell module 110 through the PID compensator 124 by turning on the relay switch 125 when the solar cell module 110 does not generate electricity To be applied with a positive voltage.

A reverse current prevention diode 126 for blocking current from flowing back from the solar cell module 110 to the PID compensator 124 is connected to the output terminal of the relay switch 125, Terminals 111, respectively.

In addition, a reverse current prevention diode 126 is also formed at the output terminal of the solar cell module 110.

The power conversion unit 130 converts the DC voltage from a DC voltage higher than a DC voltage input through the positive (+) terminal 111 and the negative (-) terminal 112 of the solar cell module 110 to a DC- (DC / DC) converter (not shown) for converting a DC voltage output from the DC-DC converter into a commercial AC voltage.

The PID compensator 124 applies a positive voltage to the positive terminal 111 and the negative terminal 112 of the solar cell module 110 at night during the day when the solar power is generated, The lifetime of the solar cell module 110 can be improved by suppressing the PID due to polarization of the solar cell module 110.

The control unit 123 may further include a timer unit (not shown) capable of setting a time or a communication unit (not shown) to perform communication with the power conversion unit 130 to control the power conversion unit 130 And controls the PID compensator 124 by checking the presence or absence of the operation.

FIG. 2 is a flow chart for explaining the operation of the PID compensator in FIG.

2, when the voltage / current output from the solar cell module 110 is detected in real time by the voltage / current detection unit 122 and the detected voltage / current is not detected, the relay switch 126 is turned on, And the positive voltage is applied to the anode and cathode terminals 111 and 112 of the solar cell module 110 by the PID compensator 124.

The controller 123 receives the voltage / current V detected by the voltage / current detector 122 and compares the detected voltage / current V with the reference voltage V *. When the current is equal to or lower than the reference voltage V * If the detected voltage / current (V) is greater than the reference voltage (V *), the PID compensator (124) So that the voltage / current is detected.

The control unit 123 measures the operation time t of the PID compensator 124 and compares the operation time t with the measurement reference time t *. When the operation time t is equal to or greater than the measurement reference time t * The relay switch 126 is turned off and the PID compensator 124 continues to operate when the operation time t is less than the measurement reference time t *.

FIGS. 3A and 3B are views showing a PID phenomenon before and after a solar cell module, respectively.

That is, PID is the most recently reported phenomenon of the reliability problem of the solar cell module. Since the electrochemical corrosion phenomenon of the solar cell module at the high voltage was observed, the leakage current of the solar cell module at the high voltage was analyzed, The same PID phenomenon was reported in the solar cell module, and it became a great interest. In the crystalline solar cell module installed outdoors, the excessive output decrease rate occurred in the state where the outlier singularity was not visible, and the cause of this was deduced as PID. The reason why the PID phenomenon that has not been seen in the past has recently become an issue is that the solar cell efficiency is 18% and the open-circuit voltage (Voc) value is 600 mV or more, Is 600 V or more.

As a main factor of the PID phenomenon, the Na ions contained in the tempered glass used in the solar cell module are transferred to the antireflection layer (SiNx) located on the front side of the cell through the EVA (Ethylene Vinyl Acetate) It is because the positive charge accumulates and disturbs the flow of electrons.

Accordingly, in order to prevent such a PID phenomenon, a reverse voltage having the same voltage as the high voltage generated in the solar cell module when the solar cell is generated at the night when the solar cell is not generated is applied to the anode of the solar cell module To the terminal and the negative terminal.

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 or constructions. Can be carried out within a limited range. Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

110: solar cell module 111: positive electrode terminal
112: negative terminal
120: connection board 121: insulation resistance detector
122: voltage / current detection unit 123:
124: PID compensator 125: Relay switch
126: Reverse current prevention diode 130: Power conversion section

Claims (5)

A solar cell module for outputting power generated by incident solar light through positive and negative terminals,
A power converter for converting the power produced by the solar cell module into power corresponding to the system,
A connection unit connected between the solar cell module and the power conversion unit to supply the power generated by the solar cell module to the power conversion unit,
An insulation resistance detector configured to detect an insulation resistance flowing in the positive and negative terminals of the solar cell module,
A voltage / current detecting unit configured to detect a voltage and a current flowing in the anode and the cathode of the solar cell module,
A controller receiving the insulation resistance detected by the insulation resistance detector to determine whether or not the solar cell module is abnormal, and determining whether the power converter is operated by receiving the voltage / current detected by the voltage / current detector;
A PID compensator for compensating the PID of the solar cell module by applying a positive voltage to the positive and negative terminals of the solar cell module when the power conversion unit does not operate under the control of the control unit;
And a relay switch formed between the solar cell module and the PID compensator and being turned on or off under the control of the control unit,
The control unit measures the operation time of the PID compensator, compares the operation time with the measurement reference time, turns off the relay switch when the operation time is equal to or longer than the measurement reference time, and continues to operate the PID compensator when the operation time is less than the measurement reference time and,
Wherein the control unit further comprises a communication unit configured to configure a timer unit capable of setting a time or perform communication with the power conversion unit. delete 2. The solar cell module as claimed in claim 1, wherein the output terminal of the solar cell module and the relay switch is formed with a reverse current prevention diode for preventing current from flowing back to the solar cell module and the PID compensator A photovoltaic power generation system with a half. delete delete

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