JP5969575B2 - Photovoltaic power generation system and charging control method in solar power generation system - Google Patents

Description

  The present invention relates to a solar power generation system that can more efficiently use power generated by a solar cell, and a charge control method in the solar power generation system.

  As a method for increasing charging efficiency in a solar power generation system, for example, maximum power point tracking control (MPPT control) is known. Maximum power point tracking control determines the increase or decrease of the output of the solar cell and changes the duty ratio of the PWM control following the determination result to bring it closer to the optimal power point that can maximize the output of the solar cell. is there.

  When the electric power supplied from the solar cell is sufficient, it can be efficiently charged by using such control. However, when the power consumption by the charging control exceeds the power supplied from the solar battery, the power consumption can be suppressed without performing the charging control. For this reason, Patent Document 1 discloses a technique for stopping the driving of the charging circuit when the output voltage of the photovoltaic power generation apparatus is smaller than a predetermined threshold value.

Japanese Patent Application Laid-Open No. 2014-174876

However, since the technique described in Patent Document 1 only stops driving the charging circuit when the output voltage of the solar cell is low, the effect of suppressing power consumption has to be limited. That is, even if the power consumption necessary for the charge control can be reduced by stopping the driving of the charging circuit, the power consumption of the CPU for processing the input from the sensor cannot be reduced.
Then, this invention makes it a subject to provide the solar power generation system which can further reduce power consumption rather than the conventional solar power generation system.

  The present invention has been made to solve the above-described problems, and is characterized by the following.

The invention according to claim 1 is a solar cell, a power conversion unit that converts power generated by the solar cell into stored power, a power storage unit that stores the stored power, a voltage of the generated power, and A voltage measurement unit that measures the voltage of the power storage unit, and a charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power measured by the voltage measurement unit and the voltage of the power storage unit. The charge control unit performs the operations of the voltage measurement unit and the power conversion unit when the voltage of the generated power is less than a predetermined power generation threshold value and the voltage of the power storage unit is equal to or higher than a predetermined power storage threshold value. It shifts to the suspend mode stopped for a fixed time .

The invention described in claim 2 is a solar cell, a power conversion unit that converts the generated power generated by the solar cell into stored power, a power storage unit for storing the stored power, and a voltage of the generated power. A voltage measuring unit that measures a voltage of the power storage unit and an output voltage of the power conversion unit, a voltage of the generated power measured by the voltage measurement unit, a voltage of the power storage unit, and an output voltage of the power conversion unit And a charge control unit that controls the operation of the power conversion unit.

The invention according to claim 3 is a solar cell, a power conversion unit that converts the generated power generated by the solar cell into stored power, a power storage unit for storing the stored power, and a voltage of the generated power. And a voltage measurement unit that measures the voltage of the power storage unit, and a charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power measured by the voltage measurement unit and the voltage of the power storage unit. The charge control unit compares the voltage measured by the voltage measurement unit with a predetermined voltage threshold, and the predetermined voltage threshold can be statically changed by a user .

The invention according to claim 4 is a solar cell, a power conversion unit that converts the generated power generated by the solar cell into stored power, a power storage unit for storing the stored power, and a voltage of the generated power. And a voltage measurement unit that measures the voltage of the power storage unit, and a charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power measured by the voltage measurement unit and the voltage of the power storage unit. When the voltage of the generated power is less than a predetermined power generation threshold and the voltage of the power storage unit is greater than or equal to a predetermined power storage threshold , the charge control unit includes the voltage measurement unit and The power conversion unit shifts to a suspend mode in which the operation of the power conversion unit is stopped for a predetermined time .

The present invention is as described above, and includes a charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power measured by the voltage measurement unit and the voltage of the power storage unit. The charging control can be performed in consideration of the state of the power storage unit.
Specifically, it is possible to perform charge control that switches whether priority is given to reducing power consumption or power storage processing depending on the state of the power storage unit.

  For example, when the output voltage of the solar battery is low and the remaining capacity of the power storage unit is sufficient, the power consumption of the CPU or the like can be reduced by putting the system in the sleep state. In addition, if the remaining capacity of the power storage unit is not enough, if only some functions such as charging control are stopped and the system is left activated, the power consumption reduction effect will be limited, Charging can be started quickly when the output voltage of the solar cell increases. Thus, by changing the content of the charge control according to the state of the power storage unit, the power consumption can be reduced more finely than before.

Further, the prior Symbol charge controller, the voltage of the generated power is less than a predetermined power threshold, and, when the voltage of the power storage unit is equal to or more than a predetermined power storage threshold, the voltage measuring unit and the power converting unit If the operation to shift to the suspend mode to stop a certain time, when the remaining amount of the power storage unit is sufficient, it is possible to reduce the power consumption of the CPU such as by the system in a sleep state.

It is a block diagram of a photovoltaic power generation system. It is a main flow figure of a photovoltaic power generation system. It is a flowchart of charge control of a solar power generation system. It is a flowchart of the suspend mode of a solar energy power generation system. It is a flowchart of the function restriction | limiting mode of a solar energy power generation system.

  Embodiments of the present invention will be described with reference to the drawings.

The solar power generation system according to the present embodiment stores the power generated by the solar battery 10 in the power storage unit 11, and the solar battery 10 and the power storage unit 11 are connected via the charging circuit 20 as shown in FIG. Are electrically connected. Further, the system includes a control device 100 for controlling the charging circuit 20. Although not particularly shown in FIG. 1, this system is a stand-alone system that operates using the power stored in the power storage unit 11, and operates using the power stored in the power storage unit 11. It is equipped with various devices.
The solar cell 10 has the same configuration as that generally used. For example, a solar panel receives sunlight to generate electric power.
The power storage unit 11 is configured by a general secondary battery, such as a lead storage battery or a lithium storage battery.

(Charging circuit 20)
As shown in FIG. 1, the charging circuit 20 includes a power conversion unit 30 that converts the generated power generated by the solar cell 10 into stored power that can be stored in the power storage unit 11, the power conversion unit 30, and the power storage unit 11. And a backflow prevention coil 42 provided between the resistor 41 and the power storage unit 11. Here, the power generated by the solar cell 10 is referred to as generated power, and the power converted by the power conversion unit 30 is referred to as stored power.

  The power conversion unit 30 is for converting the voltage VP of the generated power generated by the solar cell 10 into the rated voltage of the storage battery constituting the power storage unit 11. For example, when the voltage VP of the generated power generated by the solar cell 10 is 50V and the power storage unit 11 has a 12V rating, the power conversion unit 30 is configured by a step-down circuit of a DC-DC converter. Specifically, as shown in FIG. 1, a switching element 31, a diode 32, a coil element 33, and a capacitor 34 are provided. In such a configuration, the voltage output to the power storage unit 11 is adjusted by adjusting the cycle (duty ratio) for turning on / off the switching element 31.

  The voltage VP of the generated power is measured by a voltage measurement unit 110 described later at a first measurement point P1 provided between the solar cell 10 and the power conversion unit 30. The voltage VP of the generated power measured by the voltage measuring unit 110 is used when the charge control unit 120 described later determines the duty ratio of the switching element 31.

  The resistor 41 is for detecting the output voltage VB2 of the power conversion unit and the voltage VB1 of the power storage unit. Specifically, the output voltage VB2 of the power conversion unit and the voltage VB1 of the power storage unit are measured by a voltage measurement unit 110 described later at a third measurement point P3 and a second measurement point P2 provided before and after the resistor 41. Is done.

  The backflow prevention coil 42 is for preventing current from flowing back when the switching element 31 is turned off. If the backflow prevention coil 42 is not provided, the voltage value of the resistor 41 is reversed when the switching element 31 is turned off, so that the current may flow backward from the power storage unit 11 toward the solar cell 10. By providing the backflow prevention coil 42, such backflow of current can be prevented.

(Control device 100)
For example, the control device 100 is configured around a CPU, and the CPU executes various controls by reading a program stored in a storage device. As shown in FIG. 1, the control device 100 includes a voltage measurement unit 110 for measuring a voltage at a predetermined measurement point on the charging circuit 20, and a power conversion unit 30 based on a measurement result of the voltage measurement unit 110. A charge control unit 120 that controls the operation and a device control unit 130 that controls a communication function and the like are provided.

  The voltage measurement unit 110 is connected to the first measurement point P1, the second measurement point P2, and the third measurement point P3 on the charging circuit 20, and is for acquiring the voltage at each measurement point. The voltage measurement unit 110 is configured using, for example, an A / D converter (ADC) mounted on a CPU. When the CPU ADC is used as the voltage measurement unit 110, the voltage at each measurement point is input to the CPU ADC, and the voltage at each measurement point is measured. Specifically, the voltage VP of the generated power is measured at the first measurement point P1, the voltage VB1 of the power storage unit is measured at the second measurement point P2, and the output voltage VB2 of the power conversion unit is measured at the third measurement point P3. To do. The measurement value measured by the voltage measurement unit 110 is used by the charge control unit 120.

  Note that the voltage measurement method according to the present embodiment is merely an example, and any method may be used as long as the voltage VP of the generated power, the voltage VB1 of the power storage unit, and the output voltage VB2 of the power conversion unit can be measured. For example, voltage measurement may be performed using a voltmeter or the like.

  The charge control unit 120 acquires the measurement value measured by the voltage measurement unit 110 and executes various processes based on the measurement value. Specifically, the duty ratio is determined according to the measurement value measured by the voltage measurement unit 110, the switching element 31 of the power conversion unit 30 is switched on / off according to the determined duty ratio, the voltage measurement unit Processing such as shifting the system to a sleep mode or a function restriction mode is executed according to the measurement value measured by 110.

  In the present embodiment, a voltage threshold value for comparison with a measurement value measured by the voltage measurement unit 110 is stored in a ROM built in the control device 100, and the charge control unit 120 uses the voltage threshold value to perform various operations. Execute the process. As a specific voltage threshold value, a power generation threshold value for determining whether the output voltage of the solar cell 10 is larger than the power consumption of the charging control, and for determining whether the battery unit 11 has a sufficient remaining battery level. A storage threshold, a difference threshold for comparing the voltage VB1 of the storage unit and the output voltage VB2 of the power conversion unit, and a full charge threshold for determining whether the storage unit 11 is in a fully charged state are set. ing. These voltage threshold values are read by the charging control unit 120 and compared with the measured values measured by the voltage measuring unit 110. These voltage threshold values may be rewritable. For example, the user may be able to statically change the voltage threshold by rewriting a configuration file read at system startup.

  The device control unit 130 is for controlling various devices. For example, when communication devices such as WiFi and LAN are connected to the solar power generation system, the communication devices are for controlling these communication devices.

(About processing flow)
Next, a processing flow of the photovoltaic power generation system according to this embodiment will be described. Note that the processing flow described below extracts only a part of the entire processing, and may include processing not described here.

(Main flow)
FIG. 1 shows a main flow of the photovoltaic power generation system. When the solar power generation system is activated, this main flow is first executed.

  First, in step S100 shown in FIG. 2, the charging control unit 120 sets the PWM duty ratio to 0 (that is, turns off the switching element 31), and stops the operation of the power conversion unit 30. Then, the process proceeds to step S101.

  In step S101, the voltage measurement unit 110 measures the voltage at the first measurement point P1 (that is, the voltage VP of the generated power). The measured voltage VP of the generated power is output to the charging control unit 120. The charge control unit 120 determines whether or not the voltage VP of the generated power is greater than or equal to a predetermined power generation threshold value.

  When the voltage VP of the generated power is equal to or higher than the predetermined power generation threshold, it is determined that the output voltage of the solar cell 10 is larger than the power consumption of the charging control (it is advantageous to execute the charging control), and step S102 Proceed to When it progresses to step S102, charge control is performed.

  On the other hand, when the voltage VP of the generated power is less than the predetermined power generation threshold, it is determined that the output voltage of the solar cell 10 is smaller than the power consumption of the charging control (it is more advantageous to stop the charging control), Proceed to step S103.

  In step S103, voltage measurement unit 110 measures the voltage at second measurement point P2 (that is, voltage VB1 of the power storage unit). The measured voltage VB1 of the power storage unit is output to charge control unit 120. Charging control unit 120 determines whether or not voltage VB1 of the power storage unit is equal to or higher than a predetermined power storage threshold.

  If the voltage VB1 of the power storage unit is equal to or higher than the predetermined power storage threshold, it is determined that the power storage unit 11 has a sufficient remaining battery level, and the process proceeds to step S104. When the process proceeds to step S104, the charging control unit 120 shifts the system to the suspend mode.

  On the other hand, when the voltage VB1 of the power storage unit is less than the predetermined power storage threshold, it is determined that the remaining battery level of the power storage unit 11 is low, and the process proceeds to step S105. When the process proceeds to step S105, the charging control unit 120 shifts the system to the function restriction mode.

(Charge control)
The charge control is a process of charging the power storage unit 11 with the power generated by the solar cell 10 by a control method according to the state of the solar cell 10 or the power storage unit 11. This charging control is executed when it is determined in step S101 described above that the output voltage of the solar cell 10 is larger than the power consumption of the charging control. This charging control will be described with reference to the flow of FIG.

  First, in step S200 shown in FIG. 3, the stop of the power conversion unit 30 is released. Specifically, the charging control unit 120 sets the PWM duty ratio to an initial value, and the switching element 31 is operated so as to achieve the set duty ratio. By this operation, the power conversion unit 30 converts the generated power generated by the solar cell 10 into stored power. The output voltage VB2 of the power conversion unit is measured by the voltage measurement unit 110 at the third measurement point P3 and used for feedback of PWM control. Specifically, the measured output voltage VB2 of the power conversion unit is transmitted to the charge control unit 120, and the charge control unit 120 adjusts the duty ratio based on the acquired output voltage VB2 of the power conversion unit. By such processing, control is performed so that the output voltage VB2 of the power converter becomes a desired value. Then, the process proceeds to step S201.

  In step S201, the voltage VB1 of the power storage unit is compared with the output voltage VB2 of the power conversion unit. Specifically, if the value obtained by dividing the output voltage VB2 of the power conversion unit from the voltage VB1 of the power storage unit is equal to or greater than a predetermined difference threshold value, the process proceeds to step S202, and normal charge control is executed. On the other hand, when the value obtained by dividing the output voltage VB2 of the power conversion unit from the voltage VB1 of the power storage unit is less than a predetermined difference threshold value, the process proceeds to step S203.

  In step S203, it is checked whether or not the voltage VB1 of the power storage unit is equal to or higher than a predetermined full charge threshold. When the voltage VB1 of the power storage unit is equal to or higher than a predetermined full charge threshold, it is determined that the power storage unit 11 is in a fully charged state, and the process proceeds to step S204 to execute full charge control. On the other hand, when the voltage VB1 of the power storage unit is less than the predetermined full charge threshold, it is determined that the output voltage VB2 of the power conversion unit is not sufficient, and the process proceeds to step S205 to execute peak charge control.

  As described above, in the charge control, the control method is selected according to the state of the solar cell 10 or the power storage unit 11 (specifically, the value of the voltage VB1 of the power storage unit and the output voltage VB2 of the power conversion unit). The power storage unit 11 is charged by the control method performed. In the present embodiment, three control methods of normal charge control, full charge control, and peak charge control can be executed, and the most suitable one for the situation is selected and executed from these three control methods.

  The normal charging control according to the present embodiment is PWM control that adjusts the duty ratio so that a value obtained by dividing the output voltage VB2 of the power conversion unit from the voltage VB1 of the power storage unit is within a predetermined range. When the value obtained by dividing the output voltage VB2 of the power conversion unit from the voltage VB1 of the power storage unit is less than a predetermined difference threshold, the normal charge control is stopped and the process returns to step S100.

  In addition, the full charge control according to the present embodiment is trickle charge control in which charging is always performed with a minute current in order to compensate for natural discharge of the power storage unit 11. When the value obtained by dividing the output voltage VB2 of the power conversion unit from the output voltage VB2 of the power conversion unit during the full charge control is equal to or greater than a predetermined difference threshold value, or when a predetermined time has elapsed since the start of full charge control. Stops the full charge control and returns to step S100.

  The peak charge control according to the present embodiment is maximum power point tracking control that calculates an optimum power point that can maximize the output of the solar cell 10 and executes PWM control according to the calculation result. If the value obtained by dividing the voltage VB1 of the power storage unit from the output voltage VB2 of the power conversion unit during the peak charge control is equal to or greater than a predetermined difference threshold, the peak charge control is stopped and the process returns to step S100.

(Suspend mode)
The suspend mode is a process for suppressing power consumption by stopping the operation of the voltage measurement unit 110 and the power conversion unit 30 for a certain period of time. As described in the main flow, this suspend mode is executed when the voltage VP of the generated power is less than a predetermined power generation threshold value and the voltage VB1 of the power storage unit is equal to or higher than the predetermined power storage threshold value. This suspend mode will be described with reference to the flow of FIG.

  First, in step S300 illustrated in FIG. 4, the control device 100 transitions to a sleep state. When transitioning to the sleep state, the operations of the voltage measurement unit 110, the charge control unit 120 (the power conversion unit 30 operated by the charge control unit 120), and the device control unit 130 are stopped.

In addition, what function should be stopped in the sleep state may be freely set according to the purpose of use of the photovoltaic power generation system. For example, the power supply to the CPU may be completely stopped in the sleep state, or the data expanded in the RAM may be saved to the ROM when the sleep state is changed, and the power supply to the RAM is completely stopped. Also good. When the partial functions including the voltage measurement unit 110 and the power conversion unit 30 are stopped in this way and the state transitions to the sleep state, the process proceeds to step S301.
In step S301, the process waits until a predetermined time elapses. When the predetermined time has elapsed, the process proceeds to step S302.

  In step S302, the process returns from the sleep state. The return from the sleep state is automatically executed, for example, by a process of automatically starting power supply to the control device 100 after measuring a certain time with an internal timer. After returning from the sleep state, the process returns to step S100 and the main flow is executed.

  Thus, in the suspend mode, power consumption can be suppressed by stopping the charging function. That is, when the power generation amount of the solar cell 10 is small and there is a margin in the power storage amount of the power storage unit 11, the charging function is completely stopped by executing the suspend mode. Can be prevented from decreasing.

  Although not specifically described above, the standby time in step S301 may be changed according to the measurement result of the voltage measurement unit 110. For example, when the voltage VB1 of the power storage unit is large, the sleep state may be extended.

(Function restriction mode)
The function restriction mode is a mode in which the charging control is temporarily stopped, and is a process that allows the charging of the power storage unit 11 to be quickly restarted when the output voltage of the solar cell 10 increases. As described in the main flow, this function restriction mode is executed when the voltage VP of the generated power is less than a predetermined power generation threshold and the voltage VB1 of the power storage unit is less than the predetermined power storage threshold. This function restriction mode will be described with reference to the flow of FIG.
First, in step S400 shown in FIG. 5, some functions are stopped.

  Specifically, the switching element 31 is turned off and the operation of the power conversion unit 30 is stopped. At this time, the charging control unit 120 (a process in which charging control is executed in the control device 100) may be stopped.

In addition, power supply to devices (communication devices such as WiFi and LAN) may be stopped. At this time, the device control unit 130 (a process executing device control in the control apparatus 100) that controls the device may be stopped.
Then, the process proceeds to step S401.

In step S401, the voltage VP of the generated power is periodically checked, and the process waits until the voltage VP of the generated power becomes equal to or higher than a predetermined power generation threshold. If the voltage VP of the generated power is equal to or higher than a predetermined power generation threshold, it is determined that the output of the solar cell 10 has increased, and the process proceeds to step S402.
In step S402, the partial function stopped in step S401 is restored. And it progresses to step S403 and performs charge control.

  Thus, in the function restriction mode, the charging function is not completely stopped, but the voltage VP of the generated power is periodically checked, and when the output of the solar battery 10 returns, the battery is quickly charged. You can start.

  In this function restriction mode, unlike the suspend mode described above, the voltage measurement unit 110 is not stopped, so that the power supply to the CPU cannot be stopped. For this reason, it is inferior to the suspend mode in terms of suppressing power consumption, but is superior to the suspend mode in terms of quick start of charging. That is, when the power generation amount of the solar battery 10 is small and the power storage amount of the power storage unit 11 is not sufficient, the function restriction mode is executed to balance power consumption and charge opportunity loss in a balanced manner. be able to.

(Summary)
As described above, according to the present embodiment, the charging control unit 120 that controls the operation of the power conversion unit 30 based on the voltage VP of the generated power measured by the voltage measurement unit 110 and the voltage VB1 of the power storage unit is provided. The charging control can be performed in consideration of not only the output voltage of the solar battery 10 but also the state of the power storage unit 11.
Specifically, charge control can be performed to switch whether to prioritize reduction of power consumption or power storage processing depending on the state of the power storage unit 11.

  For example, when the output voltage of the solar battery 10 is low and the remaining amount of the power storage unit 11 is sufficient, the power consumption of the CPU or the like can be reduced by putting the system in a sleep state. In addition, when the remaining capacity of the power storage unit 11 is not sufficient, if only a part of functions such as charging control is stopped and the system is left activated, the effect of reducing power consumption is limited. When the output voltage of the solar cell 10 is increased, charging can be started promptly. Thus, by changing the content of the charge control according to the state of the power storage unit 11, the power consumption can be reduced more finely than before.

  In addition, the charging control unit 120 is configured such that when the voltage VP of the generated power is less than a predetermined power generation threshold and the voltage of the power storage unit 11 is equal to or higher than a predetermined power storage threshold, the voltage measurement unit 110 and the power Since the operation of the conversion unit 30 is shifted to the suspend mode in which the operation of the conversion unit 30 is stopped for a certain time, the power consumption of the CPU or the like can be reduced by putting the system in the sleep state when the remaining amount of the power storage unit 11 is sufficient.

  In addition, the charging control unit 120 determines that the voltage VP of the generated power is predetermined when the voltage VP of the generated power is less than a predetermined power generation threshold value and the voltage VB1 of the power storage unit is less than a predetermined power storage threshold value. Since it shifts to the function restriction mode in which the operation of the power conversion unit 30 is stopped until the power generation threshold becomes equal to or greater than the power generation threshold, the operation of the power conversion unit 30 is stopped when the remaining amount of the power storage unit 11 is not sufficient. Power consumption can be suppressed, and charging can be started quickly when the output voltage of the solar cell 10 increases.

  In addition, when the charging control unit 120 shifts to the function restriction mode, the charging control unit 120 stops a part of the functions of the solar power generation system and suppresses power consumption. For example, power consumption can be further suppressed by stopping some functions such as a communication function.

DESCRIPTION OF SYMBOLS 10 Solar cell 11 Power storage part 20 Charging circuit 30 Power conversion part 31 Switching element 32 Diode 33 Coil element 34 Capacitor 41 Resistance 42 Backflow prevention coil 100 Controller 110 Voltage measurement part 120 Charge control part 130 Device control part VP Voltage of generated power VB1 Voltage of power storage unit VB2 Output voltage of power conversion unit P1 First measurement point P2 Second measurement point P3 Third measurement point

Claims (4)

Solar cells,
A power converter that converts the generated power generated by the solar cell into stored power; and
A power storage unit for storing the stored power;
A voltage measuring unit that measures the voltage of the generated power and the voltage of the power storage unit;
A charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power and the voltage of the power storage unit measured by the voltage measurement unit;
Equipped with a,
When the voltage of the generated power is less than a predetermined power generation threshold and the voltage of the power storage unit is equal to or higher than a predetermined power storage threshold, the charge control unit keeps the operation of the voltage measurement unit and the power conversion unit constant. A photovoltaic power generation system characterized by shifting to a suspend mode for stopping time . Solar cells,
A power converter that converts the generated power generated by the solar cell into stored power; and
A power storage unit for storing the stored power;
A voltage measurement unit that measures the voltage of the generated power, the voltage of the power storage unit, and the output voltage of the power conversion unit ;
A charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power measured by the voltage measurement unit, the voltage of the power storage unit, and the output voltage of the power conversion unit;
A photovoltaic power generation system comprising: Solar cells,
A power converter that converts the generated power generated by the solar cell into stored power; and
A power storage unit for storing the stored power;
A voltage measuring unit that measures the voltage of the generated power and the voltage of the power storage unit;
A charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power and the voltage of the power storage unit measured by the voltage measurement unit;
Equipped with a,
The charging control unit compares the voltage measured by the voltage measuring unit with a predetermined voltage threshold,
A solar power generation system, wherein a user can statically change the predetermined voltage threshold . Solar cells,
A power converter that converts the generated power generated by the solar cell into stored power; and
A power storage unit for storing the stored power;
A voltage measuring unit that measures the voltage of the generated power and the voltage of the power storage unit;
A charge control unit that controls the operation of the power conversion unit based on the voltage of the generated power and the voltage of the power storage unit measured by the voltage measurement unit;
In the solar power generation system with
When the voltage of the generated power is less than a predetermined power generation threshold and the voltage of the power storage unit is equal to or higher than a predetermined power storage threshold, the charge control unit keeps the operation of the voltage measurement unit and the power conversion unit constant. A charge control method for a photovoltaic power generation system, wherein the system is shifted to a suspend mode for stopping time .

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