KR20110038975A - Output voltage control apparatus for photovoltaic power generation system - Google Patents

Abstract

PURPOSE: An output voltage control device of a photovoltaic power generation system is provided to prevent an inverter trip phenomenon due to the decrease of an output voltage by maintaining an output voltage of a solar cell module within a normal operation range. CONSTITUTION: A solar cell module(10) converts sunlight to DC power and is comprised of a main solar cell module and a sub solar cell module(12). A switch unit(13) connects the main solar cell module to the sub solar cell module. A voltage sensing unit senses the voltage of the DC power. A voltage controller controls the operation of the switch unit.

Description

Output voltage control device for photovoltaic power generation system {Output Voltage Control Apparatus for Photovoltaic Power Generation System}

The present invention relates to an apparatus for controlling an output voltage of a photovoltaic power generation system, and more particularly, by maintaining the output voltage of a solar cell module used in the photovoltaic power generation system in a normal operating range of an inverter. The present invention relates to an output voltage control device for a photovoltaic power generation system that can improve overall energy efficiency by preventing a low voltage trip of an inverter supplying commercial AC power to a load.

Recently, there have been serious problems such as global warming by carbon dioxide emitted by fossil fuel use, accidents of nuclear power plant and radioactive pollution by nuclear waste, and increasing interest in the environment and energy of the earth, thus using solar as a clean energy source. Photovoltaic power generation is practical.

In the case of the solar power generation system, a DC voltage generated from a solar cell module in which a plurality of solar cells converting incident solar energy into electrical energy in a predetermined manner is converted into a commercial AC voltage by an inverter. It is built to power the customer.

In such a photovoltaic power generation system, the solar cell module is typically arranged to output a DC voltage of about several hundred volts, and the inverter converts the DC voltage (specifically, about 480 to 900 volts) into an input voltage. As described above, the commercial AC power is supplied to the power consumer.

However, when the amount of insolation decreases depending on weather conditions or the efficiency of the solar cell decreases due to high temperature, the output voltage of the solar cell module decreases below the input voltage (ie, operating voltage) of the inverter. The inverter is tripped (inverter slip phenomenon) for a predetermined time (about 5 minutes) according to the distributed power supply connection standard, and is configured to cut off the power supplied to each load of the power consumer.

In general, a low voltage trip occurs according to weather conditions such as solar radiation and temperature, but a low voltage trip occurs even though it is not an external failure. Such a trip has a problem of greatly reducing the overall energy efficiency due to the failure to generate power even though it is a natural environment in which power can be produced during the standby time (5 minutes) for synchronization by the distributed power supply connection standard.

The present invention is to solve the above-mentioned problems of the prior art, an object of the present invention is to maintain the output voltage of the solar cell module in the normal operating range of the inverter, thereby preventing the inverter from tripping due to the decrease in the output voltage. It is to provide an output voltage control device of the photovoltaic power generation system that can greatly improve the overall energy efficiency.

In order to achieve the above object, the output voltage control apparatus of the solar power generation system according to the present invention converts sunlight into DC power and outputs the main solar cell module and an auxiliary solar cell module. According to the solar cell module, the switch unit for selectively connecting the secondary solar cell module to the main solar cell module in series or in parallel, a voltage sensing unit for detecting the voltage of the DC power, and the detected voltage of the DC power It characterized in that it comprises a voltage control unit for controlling the operation of the switch unit.

The apparatus may further include an inverter configured to convert the DC power into an AC power and supply the load to the load, wherein the voltage controller is configured to prevent the low voltage trip of the inverter when the voltage of the DC power is greater than or equal to a preset value. The module and the auxiliary solar cell module are connected in parallel, and if less than the set value, the operation of the switch unit to control the main solar cell module and the auxiliary solar cell module in series.

In addition, each of the main solar cell module is configured by connecting at least one first sub-module connected in parallel with at least one solar cell in series, and each of the auxiliary solar cell modules has at least one solar cell in series. The connected second sub module is configured to be connected to each of the first sub module in series or in parallel.

As described in detail above, the output voltage control apparatus of the solar power generation system according to the present invention separates the solar cell module into a main solar cell module and an auxiliary solar cell module and separates the entire solar cell module. By selectively controlling the connection of the main solar cell module and the auxiliary solar cell module in series or parallel according to the output voltage, the total output voltage of the solar cell module can be always maintained at a constant voltage level. The advantage is that the low-voltage trip of the inverter generated in the system can be prevented and the overall energy efficiency can be greatly improved.

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

1 is a block diagram showing the configuration of the output voltage control device of the solar power generation system according to an embodiment of the present invention, Figure 2 is a configuration of a solar cell module applied to the output voltage control device of the solar power generation system of Figure 1 It is a diagram showing.

The output voltage control apparatus of the photovoltaic power generation system according to the present invention converts the incident sunlight into electrical energy of a direct current voltage solar cell module (10), and inputs a direct current voltage output from the solar cell module Inverter 20 for supplying power to each load of the power consumer 30 by changing to a commercial AC power source as a voltage, an output voltage detector 40 for detecting the magnitude of the DC voltage output from the solar cell module 10 ), According to the magnitude of the DC voltage detected by the output voltage detecting unit 40 as described below the output voltage control unit 50 for controlling the operation of the switch unit 13 provided in the solar cell module 10 It is configured to include.

In addition, the solar cell module 10 includes a main solar cell module 11, an auxiliary solar cell module 12 provided separately from the main solar cell module 11, and the main solar cell module. It comprises a switch unit 13 for selectively connecting the auxiliary solar cell module 12 in either serial or parallel to (11).

At this time, the solar cell module 10 is preferably configured to have an appropriate output voltage level and current amount by connecting in parallel to a plurality of solar cells (cell) 16 for converting and outputting solar energy into electrical energy. Do.

To this end, the output voltage control apparatus of the photovoltaic power generation system according to the present invention is the at least one first sub-module 14 in which the main solar cell module 11 is connected to at least one solar cell 16 in series, respectively. The auxiliary solar cell module 12 is configured to be connected in parallel, and each of the second sub module 15 to which at least one solar cell 16 is connected in series is serially connected to each of the first sub module 14. Or in parallel.

In addition, the switch unit 13 may be preferably implemented using various known switching elements that perform the same function, such as an electrical relay or a semiconductor switching element such as a transistor.

In this embodiment, as an example, the main solar cell module 11 is composed of twelve first sub modules 14 connected in series with 22 solar cells 16 connected in series, respectively, and the auxiliary solar cell. The module 12 is configured such that twelve second sub modules 15 each consisting of one solar cell 16 are connected to each of the first sub modules 14 in series or in parallel.

On the other hand, as described above, due to the change in weather conditions in the region where the photovoltaic power generation system is installed, the amount of solar radiation is reduced or the energy conversion efficiency of each of the solar cells 16 constituting the solar cell module 10 is reduced due to a high temperature phenomenon. In this case, the inverter 20 generates a low voltage trip for a predetermined time (for example, 5 minutes) for the protection of the internal circuit. As a result, the inverter 20 is a natural condition capable of producing electric power based on a distributed power supply connection standard. Nevertheless, the energy efficiency of the photovoltaic power generation is reduced due to the failure to generate power, and the internal circuit of the load may be fatally damaged due to the surge and arc generated during the inverter trip.

Therefore, in this embodiment, in order to prevent this, the output voltage controller 50 of the switch unit 13 depends on the magnitude of the output voltage of the solar cell module 10 detected by the output voltage detector 40. By controlling the operation, the input voltage of the inverter 20 (that is, the output voltage of the solar cell module 10) is maintained in the normal operating range of the inverter.

In detail, first, the output voltage controller 50 is the main solar cell module 11 and the auxiliary solar cell module when the voltage of the DC power detected by the output voltage detector 40 is greater than or equal to a preset value. The operation of the switch unit 13 is controlled to connect 12 in parallel.

At this time, the set value is preferably set to the normal operating voltage (about 480V to 900V) of the inverter 20, which is the case in which the solar radiation or the energy conversion efficiency of each of the solar cells 16 is normal The value corresponds to the output voltage of the solar cell module 10.

Therefore, as in the present embodiment, assuming that the output voltage of the first sub module 14 is greater than the output voltage of the second sub module 15 (that is, the number of solar cells 16 connected in series with each other is zero). 1 sub module 14 is larger than the second sub module 15), the output voltage (V output) of the solar cell module 10 under the normal operating conditions as described above to the main solar cell module 11 The output voltage (V first sub output) of each of the first sub modules 14 to be formed is the same.

That is, in the present embodiment, the output voltage (V output) of the solar cell module 10 may be calculated as shown in Equation 1 below, wherein the V cell constitutes each of the first sub modules 14. Is the voltage output from the solar cell 16.

V output = V first sub output = V cell * 22 ------------ [Equation 1]

On the other hand, when the voltage of the DC power detected by the output voltage detecting unit 40 is less than the set value, the output voltage controller 50 serially connects the main solar cell module 11 and the auxiliary solar cell module 12. To control the operation of the switch unit 13 to be connected to.

By such a configuration, when the output voltage (V output) of the solar cell module 10 falls below the operating voltage of the inverter 20 due to a decrease in solar radiation or a decrease in efficiency of the solar cell, the main solar cell module 11 ) And the auxiliary solar cell module 12 are connected in series so that the output voltage (V second sub output) of each of the second sub modules 15 constituting the auxiliary solar cell module 12 is equal to the solar cell module 10. Output voltage (V output) is increased.

Therefore, in the present embodiment, the output voltage (V output) of the solar cell module 10 may be calculated as shown in Equation 2 below.

V output = V first sub output + V second sub output = V cell * 23 (+) ---- [Equation 2]

That is, the output voltage control device of the photovoltaic power generation system according to the present invention is an auxiliary solar cell module connected in parallel to the main solar cell module 11 when the output voltage of the solar cell module 10 is reduced by external conditions in general. By connecting 12 in series, the output voltage of the reduced solar cell module 10 can be compensated.

At this time, when the output voltage of the auxiliary solar cell module 12 is connected in series with the main solar cell module 11, the output voltage of the solar cell module 10 reduced in abnormal operating conditions as described above in the normal operating state. It is desirable to be determined so as to maintain the output voltage level.

In the above described a case in which the main solar cell module 11 and the auxiliary solar cell module 12 is configured as shown in Figure 2 as a preferred embodiment of the present invention, the power generation capacity and / or inverter of the solar power system The number of the first and second sub modules 14 and 15 and the number of the solar cells 16 constituting each of the first and second sub modules 14 and 15 may be variously configured according to the operating voltage. Of course.

By the above configuration, the output voltage control apparatus of the solar power generation system according to the present invention reduces the amount of solar radiation by maintaining the output voltage of the solar cell module 10 providing the input voltage of the inverter 20 in the normal operating range of the inverter. Since it is possible to prevent the low voltage trip of the inverter 20 which may occur due to the reduction of the efficiency of the solar cell, the inverter 20 as described above is a natural condition that can produce power by the distributed power supply reference Nevertheless, there is an advantage in that the energy efficiency of the photovoltaic power generation can be prevented from being reduced and thus the overall energy efficiency of the photovoltaic power generation system can be greatly improved.

1 is a block diagram showing the configuration of an output voltage control apparatus of a photovoltaic power generation system according to an embodiment of the present invention;

2 is a view showing the configuration of a solar cell module applied to the output voltage control apparatus of the solar power generation system of FIG.

Claims (3)

A solar cell module which converts and outputs sunlight into a DC power source and comprises a main solar cell module and an auxiliary solar cell module; A switch unit selectively connecting the auxiliary solar cell module to either the series or parallel to the main solar cell module; A voltage sensing unit sensing a voltage of the DC power supply; And And a voltage control unit controlling the operation of the switch unit according to the sensed voltage of the DC power supply. The method of claim 1, And converting the DC power into AC power and supplying the load to the load. The voltage control unit connects the main solar cell module and the auxiliary solar cell module in parallel when the voltage of the DC power supply is greater than or equal to a preset value in order to prevent a low voltage trip of the inverter. And an operation of the switch unit to connect the auxiliary solar cell module in series. The method of claim 2, Each of the main solar cell modules is configured by connecting at least one first sub-module connected in series with at least one solar cell in parallel, The auxiliary solar module is an output voltage control device for a photovoltaic power generation system, characterized in that each of the at least one solar cell is connected in series to the second sub-module connected in series or in parallel to each of the first sub-module.

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