KR101459148B1 - Solar cell modul - Google Patents

Abstract

The present invention relates to a solar cell module management system that individually monitors the state of each solar cell module constituting a solar power plant and manages the solar cell module to maintain the best power production condition based on the monitored state, thereby maximizing power productivity.

According to the present invention, there is provided a solar cell module comprising: a multi-box for dividing each solar cell module constituting a solar power generation station and grouping wiring lines of each solar cell module for each group; A voltage measuring unit for measuring a voltage of a wiring line of each solar cell module focused on the multi-box; A transmitter for transmitting a value of the individual solar cell module of the voltage measuring unit collected; And a controller for receiving the transmitted signals and displaying the status of each solar cell module,

The multi-box includes a main line connecting the focused solar cell module lines in series and a bypass line bypassing each main line and connected to the next solar cell module line, A bypass switch is provided in the main line and a bypass switch is provided in the bypass line to operate in the opposite direction to the closing switch, and a driving unit for separately operating the switches is further added, and the control unit compares the states of the respective solar cell modules And a control signal for exclusion and restoration of the corresponding solar cell module is sent to display the abnormal solar cell module belonging to each group when it is displayed, To block the main line and to bypass the bypass line through the bypass switch It was characterized by one so as to close the solar cell module, until the cause of the problem solved and the bypass transmission.

Solar power, solar cell module, inverter, serial, parallel

Description

Solar Cell Module Management System of Solar Power Plant {SOLAR CELL MODUL}

The present invention relates to a solar cell module management system that individually monitors the state of each solar cell module constituting a solar power plant and manages the solar cell module to maintain the best power production condition based on the state, thereby maximizing power productivity.

5, the solar cell modules in each solar cell divided into a plurality of groups are connected in series to produce a DC current, and the inverter receives the generated DC current and converts it to AC, and at the same time, So as to transmit power.

 The quantity of the power is measured and the owner of the power plant is earned by every pre-contract with the power exchange by the quantified quantity.

Factors influencing power generation are largely divided into natural factors and technological factors. Natural factors are divided into the geographical elements where the array is installed and the most important climatic factors for the limited amount of light coming from the sun. It is a given resource that can not be secured by manpower.

Technical factors include the performance factors of the solar cell module, the light receiving behavior of the solar cell module, the electrical connection pattern between the solar cell module, and the maintenance factor of the solar cell module.

Here, the performance factor of the solar cell module is determined by the speed of technology development in the related art. Therefore, it takes a lot of time to overcome it, but the remaining factors are elements that can be overcome in the short term through management of installed devices.

This is a sensor and control program technology, which is a technique that is already implemented because it is a method to increase efficiency by tracking and actively receiving solar light in one axis or two axis in relation to the light receiving behavior of a solar cell module.

The electrical connection pattern between the solar cell modules depends on whether the solar cell modules are connected in series or in parallel, depending on the performance of the inverter. So far, there is no more choice after design and construction.

In addition, management of the solar cell module has until now been found in measuring the amount of final collected power in terms of performance degradation or failure. In other words, since the inverter records the generated electricity every day, the manager has to compare the records and judge the abnormality of the power generation system. Also, even if an abnormality of the power generation system is detected, it takes a lot of time to find the cause of the problem because it can not be relied on by a primitive method such as a visual inspection or individual performance test by an administrator. This means that you have to take a large amount of power loss during the time it takes to find the cause of the problem and take action. Particularly, this problem increases as the aging of the solar cell module progresses. In other words, each solar cell module has inherent characteristics such as life span and structural vulnerability. As time goes by, the characteristics of the solar cell modules become malfunction or deteriorate, which in turn has a negative impact on overall power generation efficiency. For example, if one of the solar cell modules connected in series leads to a degradation or failure of one of the solar cell modules, even if the functions of the other solar cell modules are normal, the overall power productivity will be negatively affected.

In addition, the inverter that boosts the DC power to the AC has a characteristic that it does not react when the voltage of the generated electricity is below the limit, and does not function when the light amount is small, such as the sunrise at sunset or the cloudy weather. If the voltage is higher than the performance of the inverter, the voltage is cut off more than necessary.

The electricity lost due to these factors will accumulate over time, and if it is accumulated over the long term of 15 or 20 years to guarantee the generation difference, the damage will increase enormously and it needs to be improved.

A monitoring system for individually managing the state of each solar cell module is constructed so as to promptly detect the cause of deteriorating the power productivity and to anticipate and cope with the cause promptly so that the power generation facility can maintain the best development condition at all times So as to maximize power productivity.

In addition, the present invention can be applied to other factors influencing the power productivity, such as the failure of the solar cell module, the degradation of the function of the solar cell, or the shading of the solar cell module due to the surrounding feature or artificial structure In the case where a factor of performance deterioration due to the factors is generated, the solar cell module is electrically excluded so as not to have the greatest influence on the overall power productivity.

In addition, when the power generation amount is below the limit of the inverter function due to lack of light such as sunrise, sunset time, and rainy weather, the inverter does not operate. At this time, since the power transmission is not performed, So that the wiring pattern of the solar cell module can be automatically converted to a state in which the voltage is maximized to minimize the loss of light energy.

That is, the inverter does not react when the voltage of the generated electricity is below the limit, and therefore, when the light amount is small, such as the sunrise time or the cloudy weather, the inverter does not perform its function, In parallel to increase the voltage by changing the serial, so that a small amount of power transmission is possible.

In addition, when the voltage of the solar cell module is higher than that of the inverter due to an excessive amount of received light, the present invention converts the wiring pattern of the entire solar cell module from serial to parallel and lowers the voltage so that the generated electricity can be transmitted without being discarded. There is a purpose.

According to an aspect of the present invention,

A multi-box for dividing each solar cell module constituting the photovoltaic power generation station and forming a group, and a wiring line of each solar cell module for each group;

A voltage measuring unit for measuring a voltage of a wiring line of each solar cell module focused on the multi-box;

A numerical value of an individual solar cell module of the collected voltage measurement unit is coded and transmitted

And a control unit for receiving the transmitted signal and displaying the state of each solar cell module.

Further, the present invention is characterized in that the voltage measuring unit measures the voltage sequentially according to the determined sequence number.

Further, the present invention is characterized by constituting a main line connecting each of the solar cell module lines focused in the multi-box in series and bypassing each main line to constitute a bypass line connected to the next solar cell module line, A switch that operates inversely to the line and the bypass line is provided,

A control unit for comparing and analyzing the state of the solar cell module with the control unit to select a problematic solar cell module and displaying a control signal for excluding the corresponding solar cell module and for excluding the corresponding solar cell module, A switch is provided to switch the connection state between the main line and the bypass line by the control signal of the control unit so that the corresponding solar cell module is closed and bypassed until the cause is solved.

Further, according to the present invention, a preliminary line connecting the multiboxes responsible for each solar cell module group is constructed, a main transmission line for supplying electricity produced by each group to the inverter, and a switch installed in the spare line, And each solar cell module of adjacent groups is connected in series through a switch so that the group can be regenerated to such an extent that power generation is possible and supplied to the inverter on a day when the light quantity is low as in the cloudy day, do.

In addition, the present invention controls the switches of each solar cell module to block some of the solar cell modules connected in series when the inverter discards a voltage exceeding the threshold value due to an excessively large amount of light, And the battery module is connected to the cell module, and the battery module is provided to the spare inverter so that the generated electricity is transmitted without being discarded.

Since the state of each solar cell module can be monitored individually, it is possible to promptly know the cause of the deterioration of the electric power generation efficiency, to predict the electric power generation property, and to cope with the situation promptly so that the power generation facility can maintain the best power generation condition at all times .

In addition, the system that monitors the status of each solar cell module determines the cause of the malfunction or degradation of the solar cell module mechanically so that the corresponding solar cell module is electrically excluded and power generation is performed. Therefore, It is possible to produce electricity even in the process of solving the problem. In addition, the factors of performance deterioration due to external factors such as surrounding landforms due to the change of the sun and shadows cast on the solar cell module due to the artificial structure are also mechanically judged, And thus it is possible to overcome the negative factors that affect the overall power productivity, thereby improving power productivity.

In addition, the present invention automatically converts the wiring pattern of the solar cell module to a series voltage when the generated voltage is lower than the limit of the function of the inverter due to a lack of light due to the weather such as sunrise sunset time with a small amount of received light, So that the power efficiency can be improved by operating the inverter.

In addition, when the voltage of the solar cell module is higher than that of the inverter due to an excessive amount of received light, the present invention automatically or manually converts the wiring pattern of the entire solar cell module from parallel to serial so that the voltage is lowered, Can be increased.

Because it saves most of the electric energy that is discarded invisible due to various reasons, even if it is a small amount, if it accumulates for 15 years and 20 years that the generation amount is saved, it will return the huge income to the owner of the power plant It has the effect of remaining a great profit nationwide.

Fig. 1 is a configuration diagram of a solar cell module management system constituting a power plant according to a first embodiment of the present invention, and Fig. 2 is a circuit diagram of the inside of the multi-box of the first embodiment.

In FIG. 1, the solar cell modules are grouped into a plurality of groups G1 to R4 and a plurality of boxes M1 to M4 are installed in the divided groups G1 to R4, C1 to C8 are connected to each other.

Sensors S1 to S8 for measuring voltages are connected to the multibox modules M1 to M4 through the wirings of the solar cell modules C1 to C8 connected to the multibox modules M1 to M4. (D) for sending the received signal to the base station (14).

The controller 14 displays the transmitted data value so that the manager can monitor the data value in real time.

The transmitting unit D can sense and transmit the voltage of each of the solar cell modules C1 to C8 at one time, but it can transmit the sensed signals in sequence with a time difference. When each solar cell module (C1 to C8) itself has a structure for sensing its own developed voltage, it is not necessary to use a separate sensor, and the value may be used.

When the voltage is measured by adding the voltages according to the connection order of the solar cell modules C1 to C8 during the voltage measurement, the voltage of each of the solar cell modules C1 to C8 can be known by subtracting the sensed voltage from the sensed voltage later .

3 is a circuit diagram of a solar cell module management system constituting a power plant according to a second embodiment of the present invention. (The circuit shown in the figure omits a circuit for sensing voltage due to visual complexity)

The results of monitoring the state of each of the solar cell modules (C1 to C8) constituting the power plant are analyzed and the abnormal solar cell modules (C1 to C8) are excluded from the corresponding groups (G1 to R4) So as not to adversely affect the efficiency.

The main lines 10 are connected to the main transmission lines L1a and L1b and connected to the main transmission lines L1a and L1b, Each of the main lines 10 blocks the incoming and outgoing lines of the solar cell modules C1 to C8 and constitutes a bypass line 12 connected in series to the next solar cell modules C1 to C8. The main line 10 and the bypass line 12 are provided with a switch for energizing and closing the reverse, and closing the solar cell module with the abnormality by the control of this switch. At this time, the switch may employ an electronic switch or relay operated by a control signal.

More specifically, the main lines 10 are connected in series to each of the solar cell modules (C1 to C8) which are focused on the multibox (M1 to M4) Closed switches R1 to R8 are installed in the main line 10 in the connection points at both ends of the bypass line 12 while configuring the bypass lines 12 connected to the next solar cell modules C1 to C8 And the detour line 12 is provided with detour switches R1 'to R8' operating in reverse to the closing switches R1 to R8 and further includes a driving unit MD for individually operating the switches.

The controller 14 compares and analyzes the state of each of the solar cell modules C1 to C8 to select and display the problematic solar cell modules C1 to C8 and displays the corresponding solar cell modules C1 to C8 The control signal for rejecting and restoring is sent.

Therefore, when there is an abnormality in the specific solar cell modules C1 to C8 belonging to the respective groups G1 to R4, they are displayed and the closing switches R1 through R8 are operated to shut off the main line 10 At the same time, the detour switches R1 ', ..., R8' are operated to energize the detour line 12 to close the corresponding solar cell modules C1-C8 and to detour transmission until the cause of the problem is solved.

When the problem has been solved by repairing or replacing the closed solar cell modules C1 to C8, the detour switches R1 'to R8' are operated again to shut off the detour line 12 and the closing switch R1 , To R8) to energize the main line 10 to recover the original state.

Since the solar cell modules (C1 to C8) having a negative influence on the overall power generation by the device are generated and transmitted in a state excluded from the corresponding groups (G1 to R4), the electric power production from the excluded solar cell modules (C1 to C8) The efficiency of the entire group G1 to R4 is higher than that of the entire group G1 to R4 due to the problem of the solar cell modules C1 to C8.

FIG. 4 is a configuration diagram of a solar cell module (C1 to C8) management system constituting a power plant according to a third embodiment of the present invention. FIG. 5 is a block diagram of the solar cell modules C1 to C8 according to the third embodiment of the present invention. And Fig.

As shown in the figure, a spare line is constructed between the multiboxes M1 to M4 that are responsible for each of the solar cell modules C1 to C8 (G1 to R4). The spare line is composed of two strands of wires, of which the first reserve line is connected in series with the main transmission line of each group (G1 to R4) (from the (-) pole to the (+) pole) Constitutes a circuit for connecting all (+) and (+) polar wires of each main transmission line.

At the same time, first and second preliminary line switches 12a and 12b (relays and electronic switches) for closing or energizing the lines are provided in the first and second preliminary lines L2a and L2b, -) pole and the (+) polarity wire of the first preliminary line switch 12c. The first main transmission switch 11a is also provided in the main transmission lines L1a and L1b for supplying the electric power generated by the groups G1 to R4 to the inverter I. The second main transmission switch 11b is also provided between the branch points to which the first and second spare lines L2a and L2b are connected.

The first, second and third preliminary line switches 12a, 12b and 12c are turned off and the first and second main transmission switches 11a 11b are turned on to generate electricity for each of the groups G1 to R4 generally partitioned.

The spare line is for increasing the voltage by collecting the solar cell modules (C1 to C8) of several groups (G1 to R4) composed of parallel circuits in series when the voltage of the generated electricity is low because the light amount is low, Set power generation mode.

The first, second, third, and fourth main transmission line switches 11a, 11b, and 11b are automatically turned on when the data value is below the inverter I limit, 11c and 11d are closed and the first, second and third preliminary line switches 12a, 12b and 12c are energized. At the same time, an inverter I is selected to energize the first and second main line switches 11a, 11b, 11c and 11d of the groups G1 to R4 connected thereto and the third and fourth main line switches (11c, 11d). In each group G1 to R4 connected in series by the group generation mode, two groups G1 to R4 are connected to one group. Of course, the other groups G1 to R4 are all connected to the two groups G1 to R4. One of the two groups G1 to R4 connected to the one group G1 to R4 is not required to have the third main transmission switch 11c and the other group G1 to R4 is connected to the fourth main transmission switch 11d ). Therefore, when the collective power generation mode proceeds, any one of the two groups G1 to R4 connected to the one group G1 to R4 is energized to operate the third main power transmission switch 11c, The groups G1 to R4 make the fourth main power transmission switch 11d energized.

When the collective power generation mode is progressed by this circuit configuration, all of the solar cell modules C1 to C8 of the groups G1 to R4 are connected in series and supplied to the selected inverter I to be transmitted.

Second, and third preliminary line switches 12a, 12b, and 12c are closed and the first, second, third, and fourth main power transmission switches 11a, 11b, 11c, and 11d are energized to recover the normal mode.

Light intensity is variable over time and weather conditions. According to the set generation mode of the present invention, the number of groups grouped in series according to the variable elements can be arranged in accordance with the scene conditions, and the solar cell module group can be rearranged from time to time according to the variable light amount.

FIG. 6 is a configuration diagram of a solar cell module (C1 to C8) management system constituting a power plant according to a fourth embodiment of the present invention. FIG. Circuit diagram.

The present invention can transmit power even when the voltage exceeding the limit value of the inverter (I) is produced due to an excessive amount of light, without power loss through power distribution.

In other words, the inverter I is designed so as to cut off a voltage higher than a threshold value due to its characteristics. This is a safety device for preventing the inverter I from being damaged. This operation of the inverter I causes power loss.

In order to prevent the power loss due to the above-described cause, each of the solar cell modules C1 to C8 connected in series to the respective groups G1 to R4 is divided into solar cell modules C1 to C4, C8) connected in series with each other. The connection pattern of the distributed generation mode measures the maximum generated voltage of the module, and determines the number of the appropriate solar cell modules (C1 to C8) and shapes the connection.

The operation in the distributed generation mode is performed by the operation of the installed switches and is automatically divided according to the voltage of the solar cell modules C1 to C8 to be generated.

That is, in the distributed building mode, the last solar cell modules (C1 to C8) constituted in series or several solar cell modules (C1 to C8) adjacent thereto are grouped in each group (G1 to R4) (K). At this time, the leading line of the solar module to be transferred to the transfer unit (K) is connected to the first preliminary line through the tie line (20), and the trailing line of the backward solar module is connected to the second preliminary line. Cell lines of the solar cell modules (C1 to C8) before being separated from the transfer portion (K) are connected directly to the second transmission line through the direct transfer line (22). A direct transmission line switch 23 is provided in the direct transmission line 22 and a first dispersion switch 24 is provided in a line between connection points of the direct transmission line 22 and the adjoining line 20, A second dispersion switch (25) is provided between the two transmission lines.

In the operation in the normal mode, the direct line switch 23 and the first and second preliminary line switches 12a and 12b are closed to operate the first and second dispersion switches 24 and 25 in the steady state .

At the time of switching to the distributed generation mode, the first and second dispersion switches (24, 25) are closed while the direct line switch (23) is energized, and the both circuits are interrupted based on the dispersion switch.

In the power generation circuit before the first dispersion switch 24, the generated electricity is transmitted through the second main transmission line L 1 b through the direct-transfer line 22, and in the power generation circuit of the transfer portion K, The first solar cell modules C1 to C8 are connected to the first solar cell modules C1 to C8, and the last solar cell modules C1 to C8 are connected to the second spare line.

Each of the solar cell modules C1 to C8 separated from the other groups G1 to R4 by the above circuit is connected to the spare inverter I 'so that the power consumed by the inverter I is maximized and transmitted .

1 is a configuration diagram of a solar cell module management system constituting a power plant according to a first embodiment of the present invention.

2 is a circuit diagram of the inside of the multi-box (M1 to M4) of the first embodiment.

3 is a circuit diagram of a solar cell module management system constituting a power plant according to a second embodiment of the present invention

4 is a configuration diagram of a solar cell module management system constituting a power plant according to a third embodiment of the present invention,

5 is a circuit diagram of a solar cell module management system according to a third embodiment of the present invention.

6 is a configuration diagram of a solar cell module management system constituting a power plant according to a fourth embodiment of the present invention;

7 is a circuit diagram of a multi-box according to a fourth embodiment of the present invention;

DESCRIPTION OF THE REFERENCE SYMBOLS

G1 to R4 - Group C1 to C8 - Solar Cell Module

M1 to M4 - Multibox D - Transmitter

10 - Main line R1, ~ R8 - Closing switch

12 - Bypass line R1 ', ~ R8' - Bypass switch

14 - Controllers L2a, L2b - First and second preliminary lines

l2a, l2b, l2c - first, third spare line switches L1a, L1b - first and second main transmission lines

11a, 11d First to fourth main power transmission switches K -

20 - Dislocation line 22 - Direct line

23 - direct line switch 24, 25 - first and second dispersion switches

I - Inverter I'CP - Preliminary inverter

Claims (4)

Each of the solar cell modules C1 to C8 constituting the photovoltaic power generation station is divided into groups G1 to R4 and the wiring lines of the solar cell modules C1 to C8 are arranged for each group G1 to R4 Multi-boxes (M1 to M4); A voltage measuring unit for measuring a voltage of a wiring line of each of the solar cell modules (C1 to C8) focused on the multibox (M1 to M4); And a control unit (14) for displaying the status of each of the measured solar cell modules (C1 to C8) The main lines 10 connecting the solar cell modules C1 to C8 in series are connected to the multibox M1 to M4 and the solar cell module Closed switches R1 to R8 are provided in the main line 10 in the both end connection points of the bypass line 12 while the bypass lines 12 connected to the lines C1 to C8 are respectively constituted, (RD) to R8 'that operate in the opposite direction to the closing switches R1 to R8 and further include a driving unit MD for individually operating the switches, The controller 14 compares and analyzes the state of each of the solar cell modules C1 to C8 to select and display the problematic solar cell modules C1 to C8, A control signal for exclusion and restoration is sent, When there is an abnormality in the specific solar cell modules C1 to C8 belonging to the respective groups G1 to R4, it is displayed, and at the same time, the main line 10 is blocked through the closing switches R1 through R8, (C1 to C8) are closed and bypass transmission is performed until the cause of the problem is solved by energizing the bypass line (12) through the lamp modules (R1 ', ..., R8'). Solar cell module management system. Each of the solar cell modules C1 to C8 constituting the photovoltaic power generation station is divided into groups G1 to R4 and the wiring lines of the solar cell modules C1 to C8 are arranged for each group G1 to R4 Multi-boxes (M1 to M4); A voltage measuring unit for measuring a voltage of a wiring line of each of the solar cell modules (C1 to C8) focused on the multibox (M1 to M4); And a control unit (14) for displaying the status of each of the measured solar cell modules (C1 to C8) A spare line is constructed between the multi-boxes (M1 to M4) responsible for each of the solar cell module groups (G1 to R4), and the spare line is formed by two strands of wires while the first spare line (L2a) The first and second main transmission lines L1a and L1b ((-) pole wire to (+) pole wire) of the groups G1 to R4 are all connected and the second spare line L2b is connected to the first and second Is connected in series with the main transmission line L1b (from the (-) pole to the (+) pole) First and second preliminary line switches 12a and 12b (relays and electronic switches) for closing or energizing lines are provided in the first and second preliminary lines L2a and L2b, The third preliminary line switch 12c is provided in the second preliminary line between the transmission lines L1a and L1b and the third preliminary line switch 12c is provided in the main transmission line for supplying the electricity produced in each of the groups G1 to R4 to the inverter I. 1 main transmission switch 11a is provided and a second main transmission switch 11b is also provided between the branch points to which the first and second spare lines L2a and L2b are connected, When the light amount is sufficient, the mode is switched to the normal mode and the first and second preliminary lines (L2a and L2b) are closed through the first, second and third preliminary line switches (12a, 12b and 12c) The main power transmission line 11a, 11b, 11c, and 11d to energize the main power transmission line, The reserve line is automatically switched to the collective power generation mode and the first, second, third, and fourth main transmission line switches 11a, 11b, and 11c are turned on when the voltage of the generated electricity is lowered below the limit of the function of the inverter (I) 11c and 11d are closed and the first, second and third preliminary line switches 12a, 12b and 12c are energized and one of the inverters I is selected and connected to the groups G1 to R4, The first and second main line switches of the third and fourth main line switches are energized, One group connected to one of the groups G1 to R4 connected in series by the group generation mode energizes the third main transmission switch 11c and the other group is connected to the fourth main transmission switch 11d, To supply electricity generated by the selected inverter (I) Second, third and fourth main power transmission switches 11a, 11b, 11c, and 11d (12a, 12b, 12c) are closed when the amount of light becomes sufficient and the first, ) Is energized to recover to the normal mode. The solar cell module according to claim 2, wherein the last solar cell modules (C1 to C8) and the plurality of solar cell modules (C1 to C8) adjacent to each other in the series (G1 to R4) And the second spare line is connected to the terminal lines of the last solar cell modules (C1 to C8) to be dispersed and the disconnection lines (20 ) Of the previous solar cell modules C1 to C8 are directly connected to the second transmission line through the direct-transfer line 22 provided with the direct-transfer line switch 23, A first dispersion switch 24 is provided in a line between a connection point of the direct transmission line 22 and the disconnection line 20 and a second dispersion switch 25 is provided between the first preliminary line and the second transmission line , In the normal mode, the direct line switch 23 and the first and second preliminary line switches 12a and 12b are closed, the first and second dispersion switches 24 and 25 are energized, In the distributed power generation mode, the first and second dispersion switches (24, 25) are closed while the direct-feed line switch (23) is energized so that both circuits are blocked based on the dispersion switch, In the power generation circuit before the first dispersion switch 24, the generated electricity is transmitted through the second main transmission line L 1 b through the direct-feed line 22, and in the power generation circuit after the first dispersion switch 24, The spare lines are connected directly to the distributed first and second solar cell modules C1 to C8 and the last lines of the last solar cell modules C1 to C8 are connected to the second spare line to be separated from the other groups G1 to R4 And connected to each of the solar cell modules (C1 to C8) in series to be connected to the spare inverter (I ') for transmission. delete

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