KR100702223B1 - solar photovoltaic system and method - Google Patents

Abstract

The present invention relates to a photovoltaic power generation system and method having an output regulator using an isolated step-down converter to increase the utilization efficiency of solar energy.

The photovoltaic power generation system according to the present invention includes a solar cell that collects solar light, a bypass circuit that bypasses a DC power source collected in the solar cell to a rear end, and a DC power source collected in the solar cell. And a plurality of output regulators output to the rear stage, a storage battery to receive and charge the DC power output from the bypass circuit or a plurality of output regulators, and a DC voltage output from the bypass circuit or a plurality of output regulators or batteries An inverter that converts into an AC power supply to a load, and a system control unit for controlling the operation of the bypass circuit and the plurality of output regulators by sensing the voltage and current input and output to the bypass circuit and the plurality of output regulators and batteries. It is provided.

Photovoltaic, Power Generation, Step-Up, Static Switch, DC-DC Converter

Description

Solar photovoltaic system and method             

1 is a functional block diagram of a solar power system according to the prior art,

2 is an internal circuit diagram of an output control unit using a step-down converter according to the prior art;

Figure 3 is a graph showing the operation pattern of the photovoltaic power generation system according to the prior art,

4 is a functional block diagram of a solar power system according to an embodiment of the present invention,

5 is an internal circuit diagram of an output regulator using a step-up converter according to the present invention,

6 is an internal circuit diagram of a bypass circuit according to the present invention;

7 is a graph showing an operation pattern of the output regulator according to the present invention.

     <Brief description of symbols for the main parts of the drawings>

21: solar cell 22: bypass circuit

23, 24: output regulator 25: storage battery

26: Inverter 27: Load

28: system control unit

The present invention relates to a photovoltaic power generation system and method for producing electricity from solar energy, and more particularly, to a photovoltaic power generation system that increases efficiency of solar energy using a plurality of output regulators using an isolated step-down converter. And to a method.

As Korea lacks resources, it is absolutely necessary to develop alternative energy, and in particular, to develop environmentally friendly energy to prevent environmental pollution. To this end, the development of photovoltaic power generation systems is being activated.

Such a photovoltaic power generation system is a facility that charges a direct current produced by a solar collector plate to a storage battery through an output control device or converts an inverter into an alternating current and supplies it to a customer. This solar power system uses no electricity during the night, so it uses electricity charged in the battery at night, and when it is rainy or when there is not enough sunlight to produce electricity, it operates a diesel generator to produce electricity and supply it to the audience. do.

Currently, the output regulator installed in the photovoltaic system mainly uses a non-isolated Buck converter. Non-isolated type does not use a transformer, and step-down converter is a structure that cannot produce an output voltage higher than the input voltage. Therefore, the conventional photovoltaic power generation system has a problem in that incident solar energy cannot be used when the amount of insolation decreases and the output voltage is lower than the voltage charged in the storage battery.

1 is a functional block diagram showing a conventional photovoltaic power generation system. The photovoltaic power generation system includes a plurality of solar cells 11, a bypass circuit 12 for bypassing the direct current power collected in the plurality of solar cells 11, and a plurality of solar cells 11 An output control unit 13 for reducing the output DC power to the rear stage and outputting it to the rear stage; a storage battery 14 for receiving and charging the DC power output from the bypass circuit 12 or the output control unit 13; and a bypass circuit. (12) or the inverter 15 for converting the DC voltage output from the output control unit 13 or the storage battery 14 into an AC power supply to the load 16, the bypass circuit 12 and the output control unit ( And a system control unit 17 for controlling the 13.

The DC power collected in the plurality of solar cells 11 is provided to the bypass circuit 12 or the output control unit 13 under the control of the system controller 17, and the bypass circuit 12 or the output control unit ( The output DC power output from 13) is charged to the battery 14 or supplied to the load 16 through the inverter 15. When the output controller 13 operates normally, the system controller 17 supplies DC power collected from the solar cell 11 to the output controller 13, and the output controller 13 does not operate normally. If not, the DC power collected in the solar cell 11 is supplied to the bypass circuit 12.

The output control unit 13 reduces the DC power input to generate the output DC power. As shown in FIG. 2, the output control unit 13 includes a capacitor C11 for smoothing the input voltage, an insulated gate bipolar transistor (IGBT) Q11 for switching the input voltage to the rear stage, and an IGBT Q11. Pulse width controller (PWM controller) U11 for controlling switching of the inductor, inductor L11 and capacitor C12 for rectifying the current passing through the IGBT 11 to output a DC voltage, and a reflux diode D11. And a zener diode D11 for providing a reference voltage to the PWM controller.

The PWM controller U11 receives the output voltage and generates a switch control signal according to the feedback, and provides it to the gate terminal of the IGBT Q11. When IGBT Q11 is ON, current is accumulated in inductor L11 from the input voltage. Next, when the IGBT Q11 is turned off, the energy accumulated in the inductor L11 is released to the output side through the reflux diode D11 to obtain an output voltage through the capacitor C12. The degree of decompression of the input voltage is set by the pulse width of the switch control signal provided from the PWM controller U11 to the IGBT Q11.

Figure 3 is a graph showing the operation pattern of the photovoltaic power generation system according to the prior art. According to the solar radiation, the input voltage collected in the solar cell is indicated by a dotted line. The output voltage of the output control unit 13 is indicated by a solid line. Since the output control unit 13 uses a buck converter, the output voltage of the output control unit is always lower than the input voltage, and if the input voltage is higher than the threshold, the output voltage is adjusted to a predetermined voltage or higher. Do not climb. When the solar radiation is reduced and the input voltage is lowered and the output voltage is lower than the charging voltage of the battery, the input voltage of the solar cell is not charged to the battery even when solar power is generated.

In other words, the conventional photovoltaic power generation system having an output regulator using a step-down converter does not charge the photovoltaic energy to the storage battery when the amount of solar radiation is even a little lower, so the actual charging time compared to the photovoltaic power generation time is very Short there is a problem that the utilization efficiency of solar energy is lowered.

An object of the present invention devised to solve the above problems of the prior art is to decompress when the input voltage is higher than the charging voltage of the battery and to increase the pressure when the input voltage is lower than the charging voltage of the battery, thereby continuously solar energy during solar power generation time. It is to provide a photovoltaic power generation system and method for charging the storage battery to increase the utilization efficiency of solar energy.

A photovoltaic power generation system according to the present invention for achieving the above object, a solar cell for collecting solar light, a bypass circuit for bypassing the direct current power collected in the solar cell to the rear stage, the current collector in the solar cell A plurality of output controllers for boosting or reducing the output DC power to a rear stage, a storage battery for receiving and charging a DC power output from the bypass circuit or a plurality of output controllers, the bypass circuit or a plurality of output controllers, or The inverter converts the DC voltage output from the battery into an AC power source and supplies it to the load. The bypass circuit and the plurality of output regulators sense the voltage and current input and output to the battery. Characterized in that it comprises a system control unit for controlling the operation of.

In addition, the photovoltaic power generation method according to the present invention includes a solar cell, a bypass circuit for charging the storage battery by bypassing the direct current power collected in the solar cell to the rear stage, and boosting or directing the direct current power collected in the solar cell. Controls the operation of the bypass circuit and the plurality of output regulators by sensing the voltage and current input to and output from the plurality of output regulators and the bypass circuit, the plurality of output regulators and the battery by reducing the pressure output to the rear stage A photovoltaic power generation method of a photovoltaic power generation system having a system control unit, comprising: a first step of the solar cell collecting solar light and outputting a direct current power source; The system controller outputs a voltage and a current of a DC power output from the solar cell, a charging voltage and a current of the storage battery, a bypass voltage output from the bypass circuit, a DC voltage output from the plurality of output regulators, and the like. A second step of receiving and operating the bypass circuit or a plurality of output regulators; In the second step, the bypass circuit operated by the system controller bypasses the DC power output from the solar cell to charge the storage battery, or the plurality of output controllers operated by the system controller perform the It characterized in that it comprises a third step of charging the storage battery by stepping up or down the DC power output from the battery.

Hereinafter, the solar power generation system and method according to an embodiment of the present invention with reference to the accompanying drawings in detail as follows.

4 is a functional block diagram of a photovoltaic power generation system according to the present invention. The photovoltaic power generation system includes a plurality of solar cells 21, a bypass circuit 22 for bypassing DC power collected at the plurality of solar cells 21 to the rear stage, and a plurality of solar cells 21. A battery that receives and charges a plurality of output controllers 23 and 24 outputting the DC power by increasing or reducing the output DC power to the rear stage and a DC power output from the bypass circuit 22 or the plurality of output controllers 23 and 24. (25), an inverter (26) for converting a DC voltage output from the bypass circuit (22) or a plurality of output regulators (23, 24) or a battery (25) into an AC power source and supplying it to a load (27), The bypass circuit 22 and the plurality of output regulators 23 and 24 and the battery 25 and the load 27 sense the voltage and current input and output to the bypass circuit 22 and the plurality of output regulators 23. And a system control unit 28 for controlling the operation of the control unit 24.

The direct current power collected by the plurality of solar cells 21 is provided to the bypass circuit 22 or the plurality of output regulators 23 and 24 under the control of the system controller 28, and the bypass circuit 22 or the plurality of The output DC power output from the output regulators 23 and 24 of the is charged to the storage battery 26 or is provided to the load 27 through the inverter 26.

The system controller 28 has an input DC voltage higher than the charging voltage of the battery 25 and the charging rate of the battery 25 is lower than a predetermined value (for example, 80%), or because a plurality of output controllers 23 and 24 have failed. If it does not function, the DC power collected in the solar cell 21 is supplied to the bypass circuit 22. When the battery 25 is charged through the bypass circuit 22, the power consumption of the bypass circuit 22 itself is low, so the solar utilization efficiency is very high, about 97%.

In addition, the system controller 28 has a plurality of output regulators 23 of the DC power collected in the solar cell 21 when the input DC voltage is lower than the charging voltage of the storage battery 25 or the charging rate of the storage battery 25 is greater than or equal to a predetermined value. , 24). When the battery 25 is charged through the plurality of output regulators 23 and 24, the power consumption of the plurality of output regulators 23 and 24 itself is rather large, so the solar utilization efficiency is lowered to about 94%. There is an advantage that the voltage can be boosted up to the charging voltage of the storage battery 25.

The system controller 28 may determine the charging rate of the storage battery 25 as the magnitude of the charging current input to the storage battery 25. When the charging rate of the storage battery 25 is low, the charging current input to the storage battery 25 increases. If the charge rate of the storage battery 25 is high, the charging current input to the storage battery 25 becomes small.

The plurality of output regulators 23 and 24 output the DC power by increasing or decreasing the DC power input from the solar cell 21. Each of the output regulators 23 and 24 has a capacitor C21 for smoothing the input voltage as shown in Fig. 5, and four insulated gate bipolar transistors connected in a bridge form to convert the input DC voltage into AC. (IGBT) (Q21, Q22, Q23, Q24), the pulse width controller (PWM controller) U21 for controlling the switching operation of the bridge IGBTs (Q21, Q22, Q23, Q24), and the bridge IGBTs (Q21, Q22, Transformer T21 for transforming AC power generated by Q23, Q24, bridge diodes D21, D22, D23, D24 for rectifying AC power output from transformer T21, and AC power rectified by bridge diode Inductor (L21) and capacitor (C22) for outputting a DC voltage by smoothing and a zener diode (D22) for providing a reference voltage to the PWM controller (U21). The PWM controller U22 receives the output voltage and generates a switch control signal according to the feedback, and provides it to the bridge IGBTs Q21, Q22, Q23, and Q24.

The bypass circuit 22 bypasses the DC power input from the solar cell 21 and outputs it to the storage battery 25. The bypass circuit 22 includes an insulated gate type bipolar transistor (IGBT) Q31 which bypasses the DC power input from the solar cell 21 to the storage battery 25, as shown in FIG. The resistor R31 serving as a passage of the control signal input from the 28, the photocoupler U31 turned on / off by the control signal input through the resistor R31, and the photocoupler U31 are turned on when the photocoupler U31 is turned on. The transistor Q32 is turned off when the photocoupler U31 is turned off, and is turned on when the transistor Q32 is turned on to apply a negative driving voltage (-V) to the gate terminal of the IGBT Q31. The transistor Q33 for turning off the IGBT Q31 and the transistor Q32 are turned on when the transistor Q32 is turned off to apply a positive driving voltage (+ V) to the gate terminal of the IGBT Q31 to supply the IGBT Q31. Includes a transistor (Q34) to turn on. In addition, the bypass circuit 22 includes a plurality of resistors R32, R33, R34, R35, and R36 and a zener diode D32.

As described above, the power generation method of the solar power generation system according to the present invention is as follows. The plurality of solar cells 21 collect solar light and output DC power. DC power output from the solar cell 21 is charged in the storage battery 25 through the bypass circuit 22 or a plurality of output regulators (23, 24). At this time, the system control unit 28 is the voltage and current of the DC power output from the solar cell 21, the charging voltage and current of the storage battery 25, the current of the load 27, the bypass output from the bypass circuit 22 The operation of the bypass circuit 22 or the plurality of output regulators 23 and 24 is controlled by receiving a pass voltage and a DC voltage output from the plurality of output regulators 23 and 24.

For example, when the charge rate of the storage battery 25 is equal to or less than a predetermined amount (eg, 80%) and the DC voltage input from the solar cell 21 is higher than the voltage charged in the storage battery 25, the system controller 28 may bypass the bypass circuit 22. ) To allow direct current power collected in the solar cell 21 to be charged directly to the storage battery 25 through the bypass circuit 22. If the charge rate of the storage battery 25 is equal to or greater than a predetermined amount (eg, 90%) or the DC voltage input from the solar cell 21 is lower than the voltage charged in the storage battery 25, the system controller 28 controls the plurality of output regulators 23. , 24 to operate so that the DC power collected in the solar cell 21 is boosted and stepped down through the plurality of output regulators 23 and 24 and then charged in the storage battery 25. The plurality of output regulators 23 and 24 step down when the DC power collected in the solar cell 21 is greater than or equal to the threshold voltage, and when the DC power collected in the solar cell 21 is less than or equal to the threshold voltage due to insufficient solar radiation, Output a constant DC voltage. 7 is a graph showing an operation pattern of the output regulator according to the present invention.

When operating the plurality of output regulators 23 and 24, the system controller 28 selects and operates the number of modules proportional to the total capacity, thereby reducing power consumption and increasing efficiency. In addition, when the plurality of output regulators 23 and 24 are all broken, the system controller 28 operates the bypass circuit 22 and repeats the switching when the battery 25 approaches full charge and overcharges the battery. Prevent over discharge.

Next, the operation of the output regulators 23 and 24 will be described with reference to FIG. 5. The direct current power collected in the solar cell 21 is converted into alternating current by the on / off operation of the bridge IGBTs Q21, Q22, Q23, and Q24, and is led to the secondary side in the transformer T21. On the secondary side of the transformer T21, the bridge diodes D21, D22, D23, and D24 rectify the AC power output from the transformer T21, and the inductor L21 and the capacitor C22 smooth the rectified AC power. Output DC voltage. At this time, the PWM controller U21 receives the control signal of the system controller 28 and the output DC voltage to control the on / off operation of the bridge IGBTs Q21, Q22, Q23, and Q24, which causes the output DC voltage to step down. Or boosted and output.

Next, the operation of the bypass circuit 22 will be described with reference to FIG. 6. The system controller 28 outputs a control circuit in an active high state when the bypass circuit 22 driving condition is satisfied to operate the photocoupler U31. When the photocoupler U31 operates, the transistor Q32 is turned off and the transistor Q34 is turned on to apply a positive driving voltage (+ V) to the gate terminal of the IGBT Q31, thereby applying the IGBT Q31. Is turned on. When the IGBT Q31 is turned on, the DC power collected in the solar cell 21 is bypassed and supplied to the storage battery 25 through the diode D31. On the other hand, when the control signal of the system controller 28 becomes low, the photocoupler U31 stops operating, the transistor Q32 is turned on, and the transistor Q33 is turned on, so that the gate terminal of the IGBT Q31 is (-). ) The driving voltage (-V) is applied. Then, the IGBT Q31 is turned off to cut off the bypass voltage supplied to the storage battery 25 in the bypass circuit.

Although the technical spirit of the present invention has been described above with reference to the accompanying drawings, it is intended to exemplarily describe the best embodiment of the present invention, but not to limit the present invention. In addition, it is obvious that any person skilled in the art may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

As described above, according to the present invention, when the charge rate of the battery is low and the input DC voltage is higher than the charge voltage, the battery is charged through the bypass circuit, thereby improving utilization efficiency of solar energy, and the charge rate of the battery is lowered or inputted. When the DC voltage is lower than the charging voltage, the DC voltage regulated by the step-up / output controller is charged to the battery, thereby preventing overcharging or overdischarging of the battery, thereby improving the reliability of the system.

Claims (9)

Solar cell which collects sunlight, Bypass circuit for bypassing the direct current power collected in the solar cell to the rear end, A plurality of output regulators for outputting the rear end by boosting or reducing the DC power collected in the solar cell; A storage battery which receives and charges DC power output from the bypass circuit or a plurality of output regulators; An inverter for converting a DC voltage output from the bypass circuit or a plurality of output regulators or accumulators into AC power and supplying the load to the AC power; And a system controller for controlling the operation of the bypass circuit and the plurality of output regulators by sensing voltage and current input to and output from the bypass circuit, the plurality of output regulators and the storage battery. The method of claim 1, wherein the system control unit, If the input DC voltage collected in the solar cell is higher than the charging voltage of the storage battery and the charging rate of the storage battery is lower than a predetermined value, or the plurality of output regulators do not function due to a failure, the DC power collected in the solar cell is To be supplied to the bypass circuit, If the input DC voltage collected in the solar cell is not higher than the charging voltage of the storage battery or the charging rate of the storage battery is a predetermined value or more, characterized in that the DC power collected in the solar cell is supplied to the plurality of output regulators Photovoltaic power generation system. The method of claim 1, wherein the output regulator is a capacitor (C21) for smoothing the DC power collected in the solar cell, and four insulated gate type bipolar transistors (IGBT) connected in the form of a bridge to convert the input DC power to AC (Q21, Q22, Q23, Q24), a pulse width controller (PWM controller) U21 for controlling the switching operation of the bridge IGBTs (Q21, Q22, Q23, Q24), and the bridge IGBTs (Q21, Q22, Transformers T21 for transforming AC power generated by Q23 and Q24, bridge diodes D21, D22, D23, and D24 rectifying AC power output from the transformer T21, and rectified by the bridge diode. A solar power generation system comprising an inductor (L21) and a capacitor (C22) for smoothing an AC power and outputting a DC voltage, and a zener diode (D22) for providing a reference voltage to a PWM controller (U21). 2. The bypass circuit according to claim 1, wherein the bypass circuit includes an insulated gate type bipolar transistor (IGBT) Q31 for bypassing direct current power input from the solar cell to the storage battery, and a passage of a control signal input from the system controller. The resistor R31, the photocoupler U31 turned on / off by the control signal input through the resistor R31, and the photocoupler U31 are turned off when the photocoupler U31 is turned on, and the photocoupler U31 is turned on. The transistor Q32 is turned on when it is turned off and the transistor Q32 is turned on when the transistor Q32 is turned on so that the IGBT Q31 is turned off by applying a negative driving voltage (-V) to the gate terminal of the IGBT Q31. The transistor Q33 and the transistor Q32 are turned on to apply a positive driving voltage (+ V) to the gate terminal of the IGBT Q31 so that the IGBT Q31 is turned on. Q34), characterized in that Solar power system. Bypass circuit for bypassing the solar cell, the direct current power collected in the solar cell to the rear stage and charging the storage battery, and a plurality of the direct-current output power charged in the solar cell to the rear stage by charging or depressurizing Of the solar power generation system having an output controller of the control circuit and a system controller for controlling the operation of the bypass circuit and the plurality of output regulators by sensing voltages and currents input and output to the bypass circuits and the plurality of output regulators and the battery. In the photovoltaic method, A first step of the solar cell collecting solar light and outputting a direct current power; The system controller outputs a voltage and a current of a DC power output from the solar cell, a charging voltage and a current of the storage battery, a bypass voltage output from the bypass circuit, a DC voltage output from the plurality of output regulators, and the like. A second step of receiving and operating the bypass circuit or a plurality of output regulators; In the second step, the bypass circuit operated by the system controller bypasses the DC power output from the solar cell to charge the storage battery, or the plurality of output controllers operated by the system controller perform the And a third step of charging the battery by stepping up or down the DC power output from the battery. The method of claim 5, wherein the second step, The system controller is configured to collect current in the solar cell when the input DC voltage collected in the solar cell is higher than the charging voltage of the battery and the charging rate of the battery is equal to or less than a predetermined value, or when the plurality of output regulators fail to function due to a failure. DC power is supplied to the bypass circuit, If the input DC voltage collected in the solar cell is not higher than the charging voltage of the storage battery or the charging rate of the storage battery is more than a predetermined, characterized in that the direct current power collected in the solar cell is supplied to the plurality of output regulators Photovoltaic power generation method. 7. The system of claim 6, wherein the system controller operates the bypass circuit if all of the plurality of output regulators fail to operate due to a failure. Switching to prevent the overcharge and over-discharge of the storage battery, characterized in that the solar power generation method. 6. The method of claim 5, wherein the plurality of output controllers operated by the system controller of the third step charge or step down the DC power output from the solar cell to charge the storage battery. The plurality of output regulators step down when the DC power supply of the solar cell is greater than or equal to the threshold voltage, and when the DC power supply of the solar cell is less than or equal to the threshold voltage due to insufficient solar radiation, boosts the output voltage to the storage battery. Solar power generation method. The method of claim 8, wherein the system controller selects and operates a number of modules proportional to a total capacity when operating the plurality of output regulators.

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