JP2014050297A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system that can continue power supply from a power storage element to an essential load by interrupting a power conditioner when a DC voltage of the power storage element rises.SOLUTION: The power supply system includes: a power storage element 4; a power converter 3 connected to the power storage element and a load 7 to control the charge/discharge of the power storage element and supply power in the power storage element to the load; a power generation element 6 for supplying a generated output to the load or supplying the generated output to the power storage element via the power converter; a voltage detector 9 for detecting a DC voltage of the power storage element; and a control device 10 for reducing the generated output or stopping the power generation element if the generated output of the power generation element exceeds the power of the load and the power converter cannot admit the generated output on the basis of the DC voltage detected by the voltage detector.

Description

  The present invention relates to a power supply system including a distributed power source that is linked to a commercial system.

  In recent years, there has been an increasing demand for introduction of renewable energy such as solar power generation devices and wind power generation devices. However, since it takes time and cost to introduce renewable energy into a large-scale power generation system, distributed power sources (microgrids) such as ordinary homes and office buildings are being spread.

  The photovoltaic power generation system is advantageous in terms of cost and power generation efficiency even with a relatively small power generation capacity as compared with other power generation methods of renewable energy, and can be easily introduced into the microgrid system.

  However, since solar power generation can only be generated during the daytime, and the amount of power generation varies depending on the season, weather, etc., when it is introduced into a microgrid system, a power compensation device using a power storage element is also used.

  FIG. 13 is a configuration block diagram of a conventional power supply system. This power supply system includes a commercial power supply 1, a high-speed switch (high-speed SW) 2, a power converter 3, a power storage element 4, a power conditioner (PCS) 5, a solar power generation device (PV) 6, and an important load 7. .

  An important load 7 is connected to the commercial system power supply 1 via the high-speed switch 2, and the system power is supplied from the commercial system power supply 1 to the important load 7. A power converter 3 and a power conditioner 5 are connected between the high speed switch 2 and the important load 7. A power storage element 4 is connected to the power converter 3, and a solar power generation device 6 is connected to the power conditioner 5.

  The solar power generation device 6 generates power with sunlight and outputs the power generation amount to the power conditioner 5. The power conditioner 5 converts the generated power (DC power) of the photovoltaic power generator 6 into predetermined AC power and supplies it to the important load 7 or the power converter 3. The power converter 3 controls charging / discharging with respect to the electrical storage element 4 such as a lead storage battery.

  According to the above configuration, at the time of grid connection, the high-speed switch 2 is turned on, and power is supplied to the important load 7 by the commercial grid power supply 1 and the solar power generation device 6. At this time, the power converter 3 charges and discharges the power storage element 4 to absorb fluctuations in the generated power of the solar power generation device 6 and suppress fluctuations in the voltage and frequency at the grid connection point. In addition, when solar power generation is not performed at night, the power storage element 4 is fully charged with low-cost late-night power, and power peak cut control at the time of maximum power demand during the day is also performed.

  On the other hand, when the commercial power supply 1 is abnormal, the high-speed switch 2 is turned off, the power converter 3 is controlled at a constant voltage and constant frequency (CVCF), and power is supplied from the power storage element 4 to the important load 7 without interruption. In addition, the generated power of the solar power generation device 6 is also supplied to the important load 7 during the daytime.

  Further, during the CVCF control, when the power consumption of the important load 7 is small, the power of the solar power generation device 6 increases, and the power of the solar power generation device 6 exceeds the power consumption of the important load 7, it is automatically The storage element 4 is charged. And when the electrical storage element 4 approaches a fully charged state, the DC voltage of the electrical storage element 4 may rise and reach a voltage at a protection level.

  As a conventional technique, a self-sustained operation control system for important loads described in Patent Document 1 is known.

JP 2011-10412 A

  However, in the power supply system shown in FIG. 13, since the power converter 3 is CVCF-controlled, the connection point voltage and frequency with the power conditioner 5 are held at a constant voltage and a constant frequency. For this reason, before the power conditioner 5 shuts off, the power converter 3 detects an overvoltage of the DC voltage, and the power converter 3 stops the alarm. For this reason, the power supply to the important load 7 by the power storage element 4 is stopped. In addition, since the power conditioner 5 also performs the independent operation detection, the power supply from the solar power generation device 6 to the important load 7 is also stopped.

  Furthermore, in order to restart the power supply, a startup circuit in a power failure state is required. In this case, an emergency power supply or manual activation operation is required.

  An object of the present invention is to provide a power supply system that can establish a condition that a power conditioner stops when a DC voltage of a power storage element rises and can continue power supply to an important load by the power storage element.

  The power supply system of the present invention includes a power storage element, a power converter connected to the power storage element and a load, controlling charging / discharging of the power storage element and supplying power of the power storage element to the load, and generated power A power generation element that supplies power to the load or supplies the generated power to the power storage element via the power converter, a voltage detector that detects a DC voltage of the power storage element, and a DC voltage detected by the voltage detector And a control device that suppresses the generated power or stops the generated power element when the generated power of the power generating element exceeds the power of the load and the power converter cannot take in the generated power. And

  According to the present invention, based on the DC voltage detected by the voltage detector, the control device suppresses or generates power when the generated power of the power generation element exceeds the power of the load and the power converter cannot capture the generated power. Stop the element. More specifically, when the DC voltage of the power storage element rises, the control device establishes a condition for stopping the power conditioner and suppresses the generated power or stops the power generation element to power the load by the power storage element. Supply can be continued.

1 is a configuration block diagram of a power supply system according to a first embodiment of the present invention. It is a detailed block diagram of the configuration of the control device provided in the power supply system according to the first embodiment of the present invention. 3 is a flowchart for explaining an operation of a control device provided in the power supply system according to the first embodiment. It is a block diagram of the configuration of the power supply system according to the second embodiment of the present invention. It is a detailed block diagram of an output voltage control device provided in the power supply system of Example 2 of the present invention. 6 is a flowchart for explaining an operation of an output voltage control device provided in the power supply system of Embodiment 2. It is a block diagram of the configuration of the power supply system according to the third embodiment of the present invention. It is a detailed block diagram of the output frequency control apparatus provided in the power supply system of Example 3 of the present invention. 12 is a flowchart for explaining an operation of an output frequency control device provided in the power supply system of the third embodiment. It is a block diagram of a configuration of a power supply system according to a fourth embodiment of the present invention. It is a detailed block diagram of the control apparatus provided in the electric power supply system of Example 4 of this invention. 12 is a flowchart for explaining an operation of a control device provided in the power supply system of the fourth embodiment. It is a block diagram of a conventional power supply system.

  Hereinafter, a power supply system according to an embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a configuration block diagram of a power supply system according to a first embodiment of the present invention. The power supply system according to the first embodiment monitors the DC voltage of the power storage element 4, and when the DC voltage rises, shuts off the power conditioner 5 and continues power supply to the important load 7 by the power storage element 4. When the DC voltage decreases, the power conditioner 5 is turned on again, and the power supply to the important load 7 is continued by the generated power of the solar power generation device 6.

  This power supply system is a photovoltaic grid-connected system for microgrids, which includes a commercial power supply 1, a high-speed switch (high-speed SW) 2, a power converter 3, a power storage element 4, a power conditioner (PCS) 5, solar power. A power generation device (PV, corresponding to a power generation element) 6, an important load 7, a voltage detector 9, a control device 10, and a switch 11 are provided. That is, the power supply system shown in FIG. 1 further includes a switch 11 connected in series to the voltage detector 9, the control device 10, and the power conditioner 5 in addition to the configuration of the power supply system shown in FIG. It is characterized by that.

  Voltage detector 9 detects the DC voltage of power storage element 4 at DC voltage detection point 8 and outputs the detected DC voltage to control device 10.

  Based on the DC voltage detected by the voltage detector 9, the control device 10 generates a switch-off signal for turning off the switch 11 and a switch-on signal for turning on the switch 11, and outputs them to the switch 11. That is, based on the DC voltage detected by the voltage detector 9, the control device 10 detects the solar power when the generated power of the solar power generator 6 exceeds the power of the important load 7 and the power converter 3 cannot take in the generated power. The photovoltaic device 6 is stopped.

  Although not shown, the control device 10 includes a central processing unit (CPU) and a memory. As shown in FIG. 2, the upper limit voltage determination unit 21, the lower limit voltage determination unit 22, the upper limit continuation timer 23, and the lower limit continuation timer 24 are included. And.

  Upper limit voltage determination unit 21 determines whether or not the DC voltage of power storage element 4 exceeds upper limit voltage determination value HD. If the DC voltage of power storage element 4 exceeds upper limit voltage determination value HD, upper limit voltage is determined. The determination output signal is output to the upper limit continuation timer 23. The upper limit continuation timer 23 measures the time during which the upper limit voltage determination output signal output from the upper limit voltage determination unit 21 is output, that is, the time during which the DC voltage of the storage element 4 exceeds the upper limit voltage determination value HD. When the measured time exceeds the upper limit duration HT, a switch-off signal for turning off the switch 11 is output to the switch 11 to turn off the switch 11.

  Lower limit voltage determination unit 22 determines whether or not the DC voltage of power storage element 4 is less than lower limit voltage determination value LD, and when the DC voltage of power storage element 4 is lower than lower limit voltage determination value LD, the lower limit voltage determination output signal Is output to the lower limit continuation timer 24. The lower limit continuation timer 24 measures the time during which the lower limit voltage determination output signal output from the lower limit voltage determination unit 22 is output, that is, the time during which the DC voltage of the storage element 4 is less than the lower limit voltage determination value LD. When the elapsed time exceeds the lower limit duration LT, a switch-on signal for turning on the switch 11 is output to the switch 11 and the switch 11 is turned on.

  Next, the operation of the power supply system according to the first embodiment configured as described above will be described with reference to the flowchart shown in FIG.

  First, when the switch 11 is turned off, the upper limit voltage determination unit 21 determines whether or not the DC voltage of the power storage element 4 exceeds the upper limit voltage determination value HD (step S1). When the DC voltage of the storage element 4 exceeds the upper limit voltage determination value HD, the upper limit continuation timer 23 counts the time during which the DC voltage of the storage element 4 exceeds the upper limit voltage determination value HD. It is determined whether the time exceeds the upper limit duration HT (step S3). If the measured time exceeds the upper limit duration HT, a switch-off signal is output to the switch 11 (step S5). As a result, the switch 11 is turned off and the power conditioner 5 is shut off. Even if the generated power of the solar power generation device 6 becomes excessive during power supply from the power storage element 4 to the important load 7 by the CVCF control in a state where a power failure has occurred, before the DC voltage rises to a dangerous voltage The power conditioner 5 can be shut off.

  On the other hand, if the DC voltage of the power storage element 4 does not exceed the upper limit voltage judgment value HD in step S1 or if the time counted in step S3 does not exceed the upper limit duration HT, that is, the power conditioner 5 is turned on again. If so, the lower limit voltage determination unit 22 determines whether the DC voltage of the power storage element 4 is less than the lower limit voltage determination value LD (step S7).

  When the DC voltage of the storage element 4 is less than the lower limit voltage determination value LD, the lower limit continuation timer 24 counts the time that the DC voltage of the storage element 4 is less than the lower limit voltage determination value LD, and the measured time is It is determined whether or not the lower limit duration LT is exceeded (step S9).

  If the measured time exceeds the lower limit duration LT, a switch-on signal is output to the switch 11 (step S11). As a result, even when the switch 11 is turned on and the power conditioner 5 is turned on again and the important load 7 increases and the DC voltage decreases, the power supply from the solar power generator 6 to the important load 7 can be continued. .

  Since the upper limit voltage determination value HD and the lower limit voltage determination value LD can be set individually, the hysteresis operation of the switch 11 can be easily performed when the switch 11 is not frequently turned on and off. Further, by providing the upper limit continuation timer 23 and the lower limit continuation timer 24, it is possible to prevent the switch 11 from malfunctioning due to instantaneous voltage fluctuations or noise.

  Moreover, since the switch 11 should just be provided collectively in the main circuit of a photovoltaic power generation system, even if it installs the several power conditioner 5 and the interruption | blocking conditions of each power conditioner 5 differ, one switch 11 is provided. Since all the power conditioners 5 can be shut off by setting, it is not necessary to perform individual shut-off control of the power conditioners 5.

  FIG. 4 is a configuration block diagram of the power supply system according to the second embodiment of the present invention. The power supply system of Example 2 shown in FIG. 4 is characterized in that a voltage detector 9 and an output voltage control device 12 are further provided in the configuration of the power supply system shown in FIG.

  The output voltage control device 12 calculates an output voltage command for changing the output voltage based on the DC voltage detected by the voltage detector 9, and outputs this output voltage command to the power converter 3.

  FIG. 5 is a detailed block diagram of the output voltage control apparatus provided in the power supply system according to the second embodiment of the present invention. Although not shown, the output voltage control device 12 includes a central processing unit (CPU) and a memory, and includes an upper limit voltage determination unit 21, a lower limit voltage determination unit 22, an upper limit continuation timer 23, a lower limit continuation timer 24, and an output voltage command calculation. Part 25. Since the upper limit voltage determination unit 21, the lower limit voltage determination unit 22, the upper limit continuation timer 23, and the lower limit continuation timer 24 have been described in the power supply system according to the first embodiment, they are omitted.

  The output voltage command calculation unit 25 outputs an output voltage command for increasing the output voltage to the power converter 3 based on the signal from the upper limit continuation timer 23, and outputs the output voltage based on the signal from the lower limit continuation timer 24. An output voltage command for making a constant voltage is output to the power converter 3.

  Next, the operation of the power supply system according to the second embodiment configured as described above will be described with reference to the flowchart shown in FIG.

  In addition, since the process of step S1, S3, S7, S9 was demonstrated with the flowchart of Example 1 shown in FIG. 3, the description is abbreviate | omitted here.

  In step S <b> 3, when the measured time exceeds the upper limit duration HT, the output voltage command calculation unit 25 outputs an output voltage command for increasing the output voltage based on the signal from the upper limit duration timer 23. It outputs to the power converter 3 (step S4). The power converter 3 raises the output voltage according to the output voltage command from the output voltage command calculation unit 25. The power conditioner 5 shuts off based on the increased output voltage of the power converter 3. Thereby, the effect similar to the effect of the electric power supply system which concerns on Example 1 is acquired.

  Next, when the measured time exceeds the lower limit duration LT in step S9, the output voltage command calculation unit 25 sets the output voltage to a constant voltage based on the signal from the lower limit duration timer 24. Is output to the power converter 3 (step S10). The power converter 3 makes the output voltage constant according to the output voltage command from the output voltage command calculation unit 25. The power conditioner 5 is turned on again based on the constant voltage of the power converter 3. Thereby, the effect similar to the effect of the electric power supply system which concerns on Example 1 is acquired.

  Moreover, since the power conditioner 5 is shut off using the protection function of the power conditioner 5, no switch or wiring is required.

  FIG. 7 is a block diagram showing the configuration of the power supply system according to the third embodiment of the present invention. The power supply system of the third embodiment shown in FIG. 7 is characterized in that a voltage detector 9 and an output frequency control device 13 are further provided in the configuration of the power supply system shown in FIG.

  The output frequency control device 13 calculates an output frequency command for changing the output frequency based on the DC voltage detected by the voltage detector 9 and outputs the output frequency command to the power converter 3.

  FIG. 8 is a detailed configuration block diagram of an output frequency control device provided in the power supply system according to the third embodiment of the present invention. Although not shown, the output frequency control device 13 is composed of a central processing unit (CPU) and a memory, and an upper limit voltage determination unit 21, a lower limit voltage determination unit 22, an upper limit continuation timer 23, a lower limit continuation timer 24, an output frequency command calculation. Part 26.

  The output frequency command calculation unit 26 outputs an output frequency command for increasing the output frequency to the power converter 3 based on the signal from the upper limit continuation timer 23, and sets the output frequency based on the signal from the lower limit continuation timer 24. An output frequency command for setting a constant frequency is output to the power converter 3.

  Next, the operation of the power supply system according to the third embodiment configured as described above will be described with reference to the flowchart shown in FIG.

  In addition, since the process of step S1, S3, S7, S9 was demonstrated with the flowchart of Example 1 shown in FIG. 3, the description is abbreviate | omitted here.

  In step S3, when the time measured exceeds the upper limit duration HT, the output frequency command calculation unit 26 outputs an output frequency command for increasing the output frequency based on the signal from the upper limit duration timer 23. It outputs to the power converter 3 (step S6). The power converter 3 increases the output frequency according to the output frequency command from the output frequency command calculation unit 26. The power conditioner 5 cuts off based on the output frequency raised by the power converter 3. Thereby, the effect similar to the effect of the electric power supply system which concerns on Example 1 is acquired.

  Next, in step S9, when the measured time exceeds the lower limit duration LT, the output frequency command calculation unit 26 sets the output frequency to a constant frequency based on the signal from the lower limit duration timer 24. Is output to the power converter 3 (step S12). The power converter 3 sets the output frequency to a constant frequency according to the output frequency command from the output frequency command calculation unit 26. The power conditioner 5 is turned on again based on the constant frequency of the power converter 3. Thereby, the effect similar to the effect of the electric power supply system which concerns on Example 1 is acquired.

  Moreover, since the power conditioner 5 is shut off using the protection function of the power conditioner 5, no switch or wiring is required.

  FIG. 10 is a configuration block diagram of the power supply system according to the fourth embodiment of the present invention. In the power supply system according to the first embodiment illustrated in FIG. 1, the switch 11 is turned on / off by the control device 10 and the generated power of the solar power generation device 6 is stopped. However, the power supply system according to the fourth embodiment includes the switches 11a and 11b. And power conditioners 5a and 5b and solar power generation devices 6a and 6b, and the control device 10a turns on and off the switch 11a and the switch 11b to suppress the power generated by the solar power generation device 6. To do.

  Although not shown, the control device 10a includes a central processing unit (CPU) and a memory. As shown in FIG. 11, the first upper limit voltage determination unit 21a, the second upper limit voltage determination unit 21b, and the first lower limit voltage determination Unit 22a, second lower limit voltage determination unit 22b, first upper limit duration timer 23a, second upper limit duration timer 23b, first lower limit duration timer 24a, and second lower limit duration timer 24b.

  First upper limit voltage determination unit 21a determines whether or not the DC voltage of power storage element 4 exceeds first upper limit voltage determination value HD1, and the DC voltage of power storage element 4 exceeds first upper limit voltage determination value HD1. In this case, the first upper limit voltage determination output signal is output to the first upper limit continuation timer 23a. The first upper limit continuation timer 23a outputs the first upper limit voltage determination output signal output from the first upper limit voltage determination unit 21a, that is, the DC voltage of the power storage element 4 sets the first upper limit voltage determination value HD1. When the measured time exceeds the first upper limit duration HT1, a switch-off signal for turning off the switch 11a is output to the switch 11a to turn off the switch 11a. .

  Second upper limit voltage determination unit 21b determines whether or not the DC voltage of power storage element 4 exceeds second upper limit voltage determination value HD2, and the DC voltage of power storage element 4 exceeds second upper limit voltage determination value HD2. In this case, the second upper limit voltage determination output signal is output to the second upper limit continuation timer 23b. The second upper limit continuation timer 23b outputs the second upper limit voltage determination value HD2 when the second upper limit voltage determination output signal output from the second upper limit voltage determination unit 21b is output, that is, the DC voltage of the power storage element 4 When the measured time exceeds the second upper limit duration HT2, a switch-off signal for turning off the switch 11b is output to the switch 11b to turn off the switch 11b. .

  First lower limit voltage determination unit 22a determines whether or not the DC voltage of power storage element 4 is less than first lower limit voltage determination value LD1, and when the DC voltage of power storage element 4 is less than first lower limit voltage determination value LD1 The first lower limit voltage determination output signal is output to the first lower limit continuation timer 24a. In the first lower limit continuation timer 24a, the time during which the first lower limit voltage determination output signal output from the first lower limit voltage determination unit 22a is output, that is, the DC voltage of the power storage element 4 is less than the first lower limit voltage determination value LD1. When the measured time exceeds the first lower limit duration LT1, a switch-on signal for turning on the switch 11a is output to the switch 11a, and the switch 11a is turned on.

  The second lower limit voltage determination unit 22b determines whether or not the DC voltage of the storage element 4 is less than the second lower limit voltage determination value LD2, and when the DC voltage of the storage element 4 is less than the second lower limit voltage determination value LD2 The second lower limit voltage determination output signal is output to the lower limit continuation timer 24b. The second lower limit continuation timer 24b outputs the second lower limit voltage determination output signal output from the second lower limit voltage determination unit 22b, that is, the DC voltage of the power storage element 4 is less than the second lower limit voltage determination value LD2. When the measured time exceeds the second lower limit duration LT2, a switch-on signal for turning on the switch 11b is output to the switch 11b to turn on the switch 11b.

  Next, the operation of the power supply system according to the fourth embodiment configured as described above will be described with reference to the flowchart shown in FIG.

  First, when turning off the switch 11a, the first upper limit voltage determination unit 21a determines whether or not the DC voltage of the power storage element 4 exceeds the first upper limit voltage determination value HD1 (step S21). When the DC voltage of the storage element 4 exceeds the first upper limit voltage determination value HD1, the first upper limit continuation timer 23a sets the time during which the DC voltage of the storage element 4 exceeds the first upper limit voltage determination value HD1. Time is measured and it is determined whether or not the measured time exceeds the first upper limit duration HT1 (step S22). If the measured time exceeds the first upper limit duration HT1, the first switch-off signal is output to the switch 11a (step S23). Thereby, the switch 11a is turned off and the power conditioner 5a is shut off.

  Next, the second upper limit voltage determination unit 21b determines whether or not the DC voltage of the power storage element 4 exceeds the second upper limit voltage determination value HD2 (step S24). When the DC voltage of the storage element 4 exceeds the second upper limit voltage determination value HD2, the second upper limit continuation timer 23b sets the time during which the DC voltage of the storage element 4 exceeds the second upper limit voltage determination value HD2. Time is measured, and it is determined whether or not the measured time exceeds the second upper limit duration HT2 (step S25). If the measured time exceeds the second upper limit duration HT2, a second switch-off signal is output to the switch 11b (step S26). Thereby, the switch 11b is turned off and the power conditioner 5b is shut off.

  On the other hand, when the DC voltage of the power storage element 4 does not exceed the first upper limit voltage determination value HD1 at step S21 or when the time counted at step S22 does not exceed the first upper limit duration HT1, that is, the power condition In the case of turning on the na 5a and 5b again, the first lower limit voltage determination unit 22a determines whether or not the DC voltage of the power storage element 4 is less than the first lower limit voltage determination value LD1 (step S27).

  When the DC voltage of the storage element 4 is less than the first lower limit voltage determination value LD1, the first lower limit continuation timer 24a times the time during which the DC voltage of the storage element 4 is less than the first lower limit voltage determination value LD1. Then, it is determined whether the measured time exceeds the first lower limit duration LT1 (step S28).

  If the measured time exceeds the first lower limit duration LT1, a first switch-on signal is output to the switch 11a (step S29). That is, the power conditioner 5a is turned on again.

  Furthermore, the second lower limit voltage determination unit 22b determines whether the DC voltage of the power storage element 4 is less than the second lower limit voltage determination value LD2 (step S30).

  When the DC voltage of the storage element 4 is less than the second lower limit voltage determination value LD2, the second lower limit continuation timer 24b counts the time during which the DC voltage of the storage element 4 is less than the second lower limit voltage determination value LD2. Then, it is determined whether the counted time exceeds the second lower limit duration LT2 (step S31).

  If the measured time exceeds the second lower limit duration LT2, a second switch-on signal is output to the switch 11b (step S32). That is, the power conditioner 5b is turned on again.

  As described above, according to the power supply system of the fourth embodiment, the switches 11a and 11b, the power conditioners 5a and 5b, and the solar power generation devices 6a and 6b are provided, and the switch 11a and the switch 11b are provided by the control device 10a. The power generated by the solar power generation device 6 can be suppressed by turning on and off.

1 Commercial power supply 2 High-speed switch (High-speed SW)
3 Power converter 4 Storage element
5 Power conditioner (PCS)
6 Photovoltaic generator (PV)
7 Important load 8 DC voltage detection point 9 Voltage detector 10 Controller 11 Switch 12 Output voltage controller 13 Output frequency controller 21 Upper limit voltage determination unit 22 Lower limit voltage determination unit 23 Upper limit continuation timer 24 Lower limit continuation timer 25 Output voltage command calculation 26 Output frequency command calculation unit

Claims (7)

A storage element;
A power converter connected to the power storage element and a load, for controlling charging / discharging of the power storage element and supplying power of the power storage element to the load;
A power generation element that supplies generated power to the load or supplies the generated power to the power storage element via the power converter;
A voltage detector for detecting a DC voltage of the storage element;
Based on the DC voltage detected by the voltage detector, when the generated power of the power generation element exceeds the power of the load and the power converter cannot capture the generated power, the generated power is suppressed or the power generation element is A control device to stop;
A power supply system comprising: A first switch for connecting a commercial power system, the load, the power generation element, and the power converter;
A power conditioner that converts the generated power of the power generation element into predetermined AC power;
A second switch having one end connected to the power conditioner and the other end connected to the load, the power converter, and the first switch;
The control device turns off the second switch to cut off the power conditioner or turns on the second switch to turn on the power conditioner again based on the DC voltage detected by the voltage detector. The power supply system according to claim 1. The control device includes an upper limit voltage determination unit that determines whether a DC voltage of the power storage element exceeds an upper limit voltage determination value;
Based on the output of the upper limit voltage determination unit, the time when the DC voltage of the power storage element exceeds the upper limit voltage determination value is timed, and if the measured time exceeds the upper limit duration time, the power generation element is An upper limit duration timer that outputs a signal for turning off to the power generation element;
A lower limit voltage determination unit for determining whether or not the DC voltage of the power storage element is less than a lower limit voltage determination value;
Based on the output of the lower limit voltage determination unit, the time during which the DC voltage of the power storage element is less than the lower limit voltage determination value is counted, and the power generation element is turned on when the measured time exceeds the lower limit duration. A lower limit duration timer that outputs a signal to the power generation element,
The power supply system according to claim 2, further comprising: A first switch for connecting a commercial power system, the load, the power generation element, and the power converter;
A power conditioner that converts the generated power of the power generation element into predetermined AC power;
The control device outputs an output voltage command for changing an output voltage to the power converter based on the DC voltage detected by the voltage detector,
The power converter changes an output voltage according to an output voltage command from the control device,
The power supply system according to claim 1, wherein the power conditioner is cut off or turned on again based on an output voltage changed by the power converter. The control device includes an upper limit voltage determination unit that determines whether a DC voltage of the power storage element exceeds an upper limit voltage determination value;
Based on the output of the upper limit voltage determination unit, the time when the DC voltage of the power storage element exceeds the upper limit voltage determination value is counted, and a signal is output when the counted time exceeds the upper limit duration. An upper limit duration timer;
A lower limit voltage determination unit for determining whether or not the DC voltage of the power storage element is less than a lower limit voltage determination value;
Based on the output of the lower limit voltage determination unit, it counts the time during which the DC voltage of the storage element is less than the lower limit voltage determination value, and outputs a signal when the measured time exceeds the lower limit duration A duration timer;
Based on the signal from the upper limit duration timer, outputs an output voltage command for increasing the output voltage to the power converter, and based on the signal from the lower limit duration timer, the output voltage for setting the output voltage to a constant voltage An output voltage command calculation unit that outputs a command to the power converter;
The power supply system according to claim 4, further comprising: A first switch for connecting a commercial power system, the load, the power generation element, and the power converter;
A power conditioner that converts the generated power of the power generation element into predetermined AC power;
The control device outputs an output frequency command for changing an output frequency to the power converter based on the DC voltage detected by the voltage detector,
The power converter changes an output frequency according to an output frequency command from the control device,
The power supply system according to claim 1, wherein the power conditioner is cut off or turned on again based on an output frequency changed by the power converter. The control device includes an upper limit voltage determination unit that determines whether a DC voltage of the power storage element exceeds an upper limit voltage determination value;
Based on the output of the upper limit voltage determination unit, the time when the DC voltage of the power storage element exceeds the upper limit voltage determination value is counted, and a signal is output when the counted time exceeds the upper limit duration. An upper limit duration timer;
A lower limit voltage determination unit for determining whether or not the DC voltage of the power storage element is less than a lower limit voltage determination value;
Based on the output of the lower limit voltage determination unit, it counts the time during which the DC voltage of the storage element is less than the lower limit voltage determination value, and outputs a signal when the measured time exceeds the lower limit duration A duration timer;
Based on the signal from the upper limit duration timer, outputs an output frequency command for increasing the output frequency to the power converter, and based on the signal from the lower limit duration timer, the output frequency for setting the output frequency to a constant frequency An output frequency command calculation unit that outputs a command to the power converter;
The power supply system according to claim 6, further comprising:

Images