JP5882443B1 - Solar power storage system - Google Patents

Abstract

To provide a solar power storage system that appropriately controls a storage battery to change from an operation stop state to an operation state. A solar power storage system according to an embodiment includes a solar panel, a storage battery, a control unit, and a solar radiation meter. The solar panel 11 generates power with sunlight. The storage battery 31 stores the power supplied from the solar panel 11. The control unit 35 controls the operation state of the storage battery device 30. The solar radiation meter 20 detects the amount of generated power in the solar panel 11. The solar radiation meter 20 transmits a control signal for switching from the stopped state to the operating state to the control unit 35 when the generated power amount is larger than the self-power consumption amount of the storage battery 31. [Selection] Figure 1

Description

  Embodiments described herein relate generally to a solar energy storage system.

  Conventionally, a solar system supplies electric power generated by sunlight to a load. This solar system generates power when there is sunshine such as daytime in fine weather, but does not generate power when there is no sunshine such as in bad weather such as cloudy weather, rainy weather, snowfall, or after sunset. When the solar system does not generate electricity, it is necessary to purchase power from a commercial power system (hereinafter simply referred to as a system). For this reason, when a power failure occurs in the system due to a natural disaster or the like, the power supply to the load is interrupted and the load side fails. Therefore, a solar power storage system is known that stores power generated by sunlight in a storage battery and supplies power from the storage battery to a load in the event of a power failure.

Japanese Patent Laid-Open No. 06-266453

  Since the storage battery requires self-power consumption when controlling the storage battery itself, the storage battery continues to be discharged and the storage battery is consumed. Therefore, in order to suppress the discharge of the storage battery, there is a case where the storage battery is stopped and the self-power consumption is controlled to be zero. However, when a storage battery in a stopped state is put into an operation state, if there is not enough sunshine, the self-power consumption amount of the storage battery becomes larger than the amount of solar radiation, and the storage battery is consumed.

  An object of the present embodiment is to provide a solar energy storage system that appropriately controls a storage battery to change from an operation stop state to an operation state.

The solar power storage system of the embodiment includes a solar power generation device, a storage battery, a control unit, and a generated power amount detection device. The solar power generation device generates power using sunlight. The storage battery stores electric power supplied from the solar power generation device. The control unit controls the operation state of the storage battery and operates by supplying power from the storage battery . When it is determined that the remaining amount of the storage battery is equal to or greater than the predetermined remaining amount and the commercial power system is operating normally, the control unit changes the control unit itself from the operating state to the stopped state. The generated power amount detection device detects the generated power amount in the solar power generation device. When the generated power amount is larger than the control unit operating state self-consumption power amount of the storage battery, the generated power amount detecting device transmits a control signal for making the operating state from the stop state to the control unit.

It is a block diagram which shows the structure of the solar energy storage system which concerns on Embodiment 1. FIG. It is a figure which shows the example of a characteristic of the solar panel of the solar energy storage system which concerns on Embodiment 1. FIG. It is a figure which shows the relationship between the electric power generation amount of the solar energy storage system which concerns on Embodiment 1, and self-power consumption. It is a block diagram which shows the structure of the solar energy storage system which concerns on Embodiment 2. FIG. It is a block diagram which shows the structure of the solar energy storage system which concerns on Embodiment 3. FIG. It is a block diagram which shows the structure of the conventional solar energy storage system. It is a figure which shows the relationship between the electric power generation amount of a conventional solar energy storage system, and self-power consumption.

  Hereinafter, the present invention will be described in detail with reference to the drawings. In addition, the following embodiment is an illustration and the range of invention is not limited to them. In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art or those that are substantially the same.

[Embodiment 1]
The solar power storage system 1 according to the present embodiment mainly stores power generated by sunlight in a storage battery 31 of a storage battery device 30 to be described later, and supplies power to a specific load using the storage battery 31 as a secondary power source when a system power failure occurs. To supply. Here, the specific load is an electrical device or electrical facility that is to be preferentially operated in the event of a power failure. For example, a 100V power system including lighting, security, and air conditioning, and a 200V power system including an elevator and water supply / drainage facility There is. These specific loads are connected to the storage battery device 30.

  Moreover, the solar energy storage system 1 is connected to a system | strain and general load via the receiving / transforming installation. Thereby, the solar energy storage system 1 stores power in the storage battery 31 with power from the system at the power usage off-peak, or discharges from the storage battery 31 to the system at the power usage peak. Here, the general load is an electric device including a home appliance. Specifically, it is an electric device that is used by inserting a plug into an outlet provided on a wall of a building.

  As shown in FIG. 1, the solar energy storage system 1 includes a hybrid system 10, a solar radiation meter (power generation amount detection device) 20, and a storage battery device 30.

  The hybrid system 10 includes a solar panel (solar power generation device) 11 and a storage battery device 30 described later. The hybrid system 10 outputs the electric power generated by the solar panel 11 to the storage battery device 30 during normal operation (during normal operation of the system and during sunshine), and stores the power in the storage battery 31 of the storage battery device 30 or the storage battery 31. The power stored in is supplied to a specific load or supplied to a general load via a receiving / transforming facility. In addition, the hybrid system 10 supplies power that has been stored from the storage battery 31 of the storage battery device 30 to a specific load by interrupting the transfer of power through the power receiving / transforming facility during a power failure. At this time, the hybrid system 10 outputs the power generated by the solar panel 11 to the storage battery device 30 when there is sunshine, and stores it in the storage battery 31 of the storage battery device 30.

  The hybrid system 10 has a single operation detection unit that has a function of detecting the line voltage of the system and detecting the single operation state of the hybrid system 10 (system power outage state). The isolated operation detection unit constantly monitors the line voltage of the system, and determines that the system is out of power when the line voltage of the system is detected as zero. Moreover, the isolated operation detection unit determines that the system is operating normally when it detects that the line voltage of the system is other than zero. The isolated operation detection unit transmits the detection result as a control signal to the control unit 35 of the storage battery device 30.

  The solar panel 11 is an assembly of solar cells that generate power by sunlight. The solar panel 11 is an assembly in which a plurality of solar cells are arranged in an array to form a panel, and one panel or a plurality of panels are arranged in an array. In each panel, the plurality of solar cells are electrically connected in series. The plurality of panels constituting the assembly are electrically connected in series or in parallel. Furthermore, a plurality of solar panels 11 may be arranged in an array. The number of solar cells constituting each panel, the number of panels constituting the aggregate, and the number of solar panels 11 are set according to the amount of power required by the solar panel 11. The amount of power required by the solar panel 11 is set according to the amount of load power required at the time of a power failure. The solar panel 11 has the characteristics shown as an example in FIG. That is, the amount of solar radiation and the amount of generated power are proportional. However, the generated voltage is substantially constant even when the amount of solar radiation increases, and only the current value increases in proportion to the amount of solar radiation. The generated power of the solar panel 11 is output to the solar DC / DC converter 32 of the storage battery device 30.

  The solar radiation meter 20 is installed in the vicinity of the solar panel 11 and always measures the solar radiation amount. The solar radiation meter 20 is an operation signal (wake-up signal) that makes the control unit 35 of the storage battery device 30 operate from a stopped state (including a resting state) to an operating state based on the measured amount of solar radiation. The operation signal transmission unit for performing the process of transmitting. Here, the predetermined condition is a condition that the power generation amount of the solar panel 11 is larger than the control unit operating state self-power consumption amount (hereinafter simply referred to as self-power consumption amount) of the storage battery 31 of the storage battery device 30. The amount of power generated by the solar panel 11 can be calculated based on, for example, the amount of solar radiation and the capacity of the solar panel 11 and a loss coefficient defined. Further, for example, data indicating the correspondence between the amount of solar radiation and the amount of generated power for each solar panel 11 may be stored in advance in the database, and the amount of generated power of the solar panel 11 may be acquired based on the data. . Thereby, the operation signal transmission part can calculate (acquire) the electric power generation amount of the solar panel 11 based on the measured solar radiation amount. In addition, the operation signal transmission unit stores the self-power consumption amount of the storage battery device 30. The self-power consumption is the amount of power consumed by the processing in the control unit 35 in the storage battery device 30. The self-power consumption is determined by the capacity of the storage battery 31 of the storage battery device 30.

  In this way, the operation signal transmission unit calculates (acquires) the generated power amount of the solar panel 11 based on the measured amount of solar radiation, and determines that the generated power amount of the solar panel 11 is greater than the self-consumed power amount. When it does, the operation signal which makes an operation state from a stop state with respect to the control part 35 of the storage battery apparatus 30 is transmitted.

  Here, the relationship between the power generation amount of the solar panel 11 and the self-power consumption amount in the present embodiment will be described with reference to FIG. A solid line indicates the amount of power generated by the solar panel 11, and a broken line indicates the remaining amount of the storage battery 31 of the storage battery device 30. When the generated power amount of the solar panel 11 is smaller than the self-power consumption amount (rightward from the point A in the figure), the operation signal transmission unit does not transmit an operation signal to the control unit 35. For this reason, even if the power generation amount of the solar panel 11 becomes larger than the control unit stop state self-consumption power amount (point B in the figure), the operation signal transmission unit does not transmit the operation signal to the control unit 35. . Thus, when the electric power generation amount of the solar panel 11 is smaller than the self power consumption amount, the control unit 35 maintains the stopped state. When the generated power amount of the solar panel 11 becomes larger than the self-power consumption amount (point A in the figure), the operation signal transmission unit transmits an operation signal for changing the operation state from the stop state to the control unit 35. Thereby, the control part 35 will be in an operation state from a stop state. In this case, since the power generation amount of the solar panel 11 is larger than the self-power consumption amount, the storage battery 31 of the storage battery device 30 is charged and the remaining amount increases.

  The storage battery device 30 mainly stores electric power generated by the solar panel 11 and electric power from the system, and supplies electric power to a specific load at the time of power outage of the system. The storage battery device 30 includes a storage battery 31, a solar DC / DC converter 32, a charge / discharge DC / DC converter 33, an AC / DC converter 34, and a control unit 35 that controls these. .

  The storage battery 31 is a secondary battery that stores electric power output from the solar panel 11 or electric power from the system. The storage battery 31 supplies the stored electric power to a specific load during a system power failure. In addition, the storage battery 31 is supplied to a general load via a power receiving / transforming facility during normal operation of the system. Moreover, the storage battery 31 supplies the self-power consumption required for the process in the control part 35 mentioned later. The storage battery 31 is configured by combining one or more lithium ion batteries and lead storage batteries, for example, in accordance with a desired capacity. The capacity of the storage battery 31 is set according to the amount of power generated by the solar panel 11, the amount of load power required during a power failure, and the like. The storage battery 31 charges direct-current power output from the charge / discharge DC / DC converter 33.

  Further, the storage battery 31 is provided with an ammeter for detecting current and a voltmeter for detecting voltage. Therefore, the remaining amount of the storage battery 31 can be calculated based on at least one of the current value detected by the ammeter or the voltage value detected by the voltmeter. The storage battery 31 transmits the calculated remaining amount of the storage battery 31 to the control unit 35 described later.

  The DC / DC converter 32 for sunlight converts the voltage and current of DC generated power output from the solar panel 11 into a voltage and current DC suitable for the storage battery device 30, and is a DC / DC converter for charging / discharging. To 33. The charge / discharge DC / DC converter 33 converts the direct current power output from the solar DC / DC converter 32 into a direct current of voltage and current suitable for charge / discharge and outputs the direct current to the storage battery 31 or the AC / DC converter 34. To do. Further, the charging / discharging DC / DC converter 33 converts the direct current power output from the storage battery 31 into a direct current of voltage and current suitable for discharging and outputs the direct current to the AC / DC converter 34. Further, the charge / discharge DC / DC converter 33 converts the direct current power output from the AC / DC converter 34 into a direct current of voltage and current suitable for charging and outputs the direct current to the storage battery 31. The AC / DC converter 34 converts the direct current power output from the charge / discharge DC / DC converter 33 into alternating current of voltage and current suitable for the load capacity, and supplies the alternating current to a specific load or via a receiving / transforming facility. Supply to general load or discharge to the grid. Further, the AC / DC converter 34 converts the AC voltage and current output from the system into a voltage and current DC suitable for the storage battery device 30, and outputs them to the DC / DC converter 33 for charging and discharging.

  The flow of power through the converters 32, 33, and 34 when the storage battery 31 is charged and discharged will be described. First, the case where the storage battery 31 is charged will be described. The storage battery 31 is charged with electric power generated by the solar panel 11 or electric power from the system. The solar DC / DC converter 32 converts the direct-current generated power output from the solar panel 11 into a direct current of voltage and current suitable for the storage battery device 30 and outputs the direct current to the charge / discharge DC / DC converter 33. The AC / DC converter 34 converts the AC power output from the system into a DC voltage or current suitable for the storage battery device 30 and outputs it to the DC / DC converter 33 for charging / discharging. The charge / discharge DC / DC converter 33 converts the direct current power output from the solar DC / DC converter 32 and the direct current power output from the AC / DC converter 34 into direct current voltage and current suitable for charging. Then, the battery 31 is charged.

  Next, a case where the storage battery 31 is discharged will be described. The charge / discharge DC / DC converter 33 converts the direct current power output from the storage battery 31 into a direct current of voltage and current suitable for the load capacity and outputs the direct current to the AC / DC converter 34. The AC / DC converter 34 converts the direct current power output from the charge / discharge DC / DC converter 33 into alternating current and supplies the alternating current to a specific load. Even when the storage battery 31 is discharged, if there is sunlight, the power generated by the solar panel 11 is output to the storage battery device 30 and stored in the storage battery 31 of the storage battery device 30 in the same manner as during the storage. In this way, the storage battery 31 is charged and discharged.

  The control unit 35 controls the operation state of the storage battery device 30. The control unit 35 is switched between an operation state in which the storage battery device 30 is in an operation state and a stop state in which the storage battery device 30 is in an operation stop state. When the control unit 35 is in an operating state, the storage battery 31 performs storage and discharge. When the control unit 35 is in an operating state, the control unit 35 sends control signals to the storage battery 31, the solar DC / DC converter 32, the charge / discharge DC / DC converter 33, and the AC / DC converter 34, respectively. Send. When the control unit 35 is in an operating state, power is supplied from the storage battery 31 to a specific load and a general load, and self-power consumption required for processing in the control unit 35 is consumed from the storage battery 31. Therefore, even when the storage battery 31 is in a fully charged state and power is not supplied from the storage battery 31 to the specific load or general load, the power of the storage battery 31 is consumed by self-power consumption if the control unit 35 is in an operating state. End up.

  Moreover, the control part 35 will be in a stop state from an operation state in the following cases. The control unit 35 switches from the operating state to the stopped state when power storage to the storage battery 31 is unnecessary and power supply to the specific load and general load is unnecessary. Specifically, for example, when the control unit 35 determines that the remaining amount of the storage battery 31 is equal to or greater than a predetermined remaining amount and the system is operating normally, the control unit 35 changes from the operating state to the stopped state. . Here, the predetermined remaining amount is set to a predetermined value (for example, 80% of full charge) at which full charge or power storage is stopped. Whether or not the system is operating normally is determined based on the detection result transmitted from the single operation detection unit of the hybrid system 10. When the control unit 35 is in a stopped state, the storage battery device 30 is in an operation stopped state, so that the self-power consumption in the control unit 35 is suppressed to zero (including a value close to zero).

  Further, the control unit 35 changes from the stopped state to the operating state based on the operating signal from the solar radiation meter 20. When the control unit 35 is switched from the stopped state to the operating state, the operation is stopped for the storage battery 31, the solar DC / DC converter 32, the charge / discharge DC / DC converter 33, and the AC / DC converter 34, respectively. A control signal for switching from to the operating state is transmitted. In this way, the storage battery device 30 is switched from the operation stop state to the operation state.

  The solar energy storage system 1 according to the present embodiment is configured as described above, and the operation thereof will be described below.

  First, the operation of the solar power storage system 1 in normal times will be described. The solar panel 11 outputs the generated power generated by sunlight to the solar DC / DC converter 32 of the storage battery device 30. The solar DC / DC converter 32 converts the direct current power output from the solar panel 11 into a direct current of voltage and current suitable for the storage battery device 30 and outputs the direct current to the charge / discharge DC / DC converter 33. The AC / DC converter 34 converts the AC power output from the system into a DC voltage or current suitable for the storage battery device 30 and outputs it to the DC / DC converter 33 for charging / discharging. The charge / discharge DC / DC converter 33 converts the direct current power output from the solar DC / DC converter 32 and the direct current power output from the AC / DC converter 34 into direct current voltage and current suitable for charging. Then, the battery 31 is charged. The charge / discharge DC / DC converter 33 converts the direct current power output from the solar DC / DC converter 32 into a direct current of voltage and current suitable for discharge and outputs the direct current to the AC / DC converter 34. The AC / DC converter 34 converts the direct current power output from the charge / discharge DC / DC converter 33 and the direct current power output from the storage battery 31 into alternating current and supplies it to a specific load, or via a receiving / transforming facility. Supply to general load or discharge to the grid. In this way, the solar power storage system 1 stores the generated power generated by the solar panel 11 and the power of the system in the storage battery 31 in normal times. Moreover, the solar energy storage system 1 supplies electric power to a specific load or a general load, or discharges the system.

  Next, the operation of the solar power storage system 1 during a power failure will be described. When the control unit 35 receives a control signal indicating that a power failure has been detected from the isolated operation detection unit of the hybrid system 10, the control unit 35 interrupts the transfer of power via the power receiving / transforming equipment of the hybrid system 10 and transfers from the storage battery 31 to the specific load. Supply power. The storage battery 31 outputs the stored DC power to the charge / discharge DC / DC converter 33. The charge / discharge DC / DC converter 33 converts the direct current power output from the storage battery 31 into a direct current of voltage and current suitable for the load capacity and outputs the direct current to the AC / DC converter 34. The AC / DC converter 34 converts the direct current power output from the charge / discharge DC / DC converter 33 into alternating current and supplies the alternating current to a specific load. In this way, the solar power storage system 1 supplies the power stored in the storage battery 31 to the specific load during a power failure. Moreover, if there is sunshine, the electric power generated by the solar panel 11 is output to the storage battery device 30 and stored in the storage battery 31 of the storage battery device 30 as in normal times.

  Below, the effect | action of the solar energy storage system 1 in the case of making the control part 35 into a stop state from an operation state is demonstrated. When it is determined that power storage to the storage battery 31 is unnecessary and power supply to the specific load and general load is unnecessary, the control unit 35 changes the control unit 35 from the operating state to the stopped state. That is, when it is determined that the remaining amount of the storage battery 31 is equal to or greater than the predetermined remaining amount and the system is operating normally, the control unit 35 changes the control unit 35 itself from the operating state to the stopped state. At this time, the control unit 35 provides a control signal for switching from the operation state to the operation stop state for the storage battery 31, the solar DC / DC converter 32, the charge / discharge DC / DC converter 33, and the AC / DC converter 34, respectively. Send. Thereby, the electrical storage and discharge in the storage battery 31 are stopped. In this way, the self-power consumption in the control unit 35 is suppressed to zero.

  Subsequently, for example, the operation of the solar energy storage system 1 when the control unit 35 is changed from the stopped state to the operating state after sunrise or the like will be described. The solar panel 11 starts power generation by sunlight. When the operation signal transmission unit of the solar radiation meter 20 determines that the generated power amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30 based on the measured solar radiation amount, An operation signal for switching from the stop state to the operation state is transmitted to the control unit 35. At this time, the control unit 35 provides a control signal for switching from the operation stop state to the operation state for the storage battery 31, the solar DC / DC converter 32, the charge / discharge DC / DC converter 33, and the AC / DC converter 34, respectively. Send. In this way, the control unit 35 is switched from the stopped state to the operating state, and the storage battery device 30 is switched from the operation stopped state to the operating state. At this time, since the power generation amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30, the consumption of the storage battery 31 by the supply of the self-power consumption in the control unit 35 is suppressed.

  The solar energy storage system 1 according to the embodiment is configured as described above, and the effects thereof will be described below.

  In the solar energy storage system 1, the operation signal transmission unit of the solar radiation meter 20 determines that the power generation amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30 based on the measured amount of solar radiation. When it does, the operation signal which makes an operation state from a stop state with respect to the control part 35 of the storage battery apparatus 30 is transmitted. Thus, when the power generation amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30, the control unit 35 is changed from the stopped state to the operating state. For this reason, even if the control part 35 becomes an operation state, it can suppress that the storage battery 31 is consumed by supply of the self-power consumption in the control part 35. That is, the solar energy storage system 1 can appropriately change the storage battery device 30 from the operation stop state to the operation state by appropriately controlling the control unit 35 to change from the stop state to the operation state.

  Moreover, when the electric power generation amount of the solar panel 11 is small, the control unit 35 remains in a stopped state. If the control unit 35 is in a stopped state, the self-power consumption amount in the control unit 35 is suppressed to zero. That is, the solar energy storage system 1 can suppress the storage battery 31 from being consumed due to the amount of self-power consumption.

  Here, for comparison, a conventional solar system 1C will be described with reference to FIGS. 6 and 7 as an example. As shown in FIG. 6, the solar system 1C includes a hybrid system 10C and a storage battery device 30C. The storage battery device 30C includes a storage battery 31, a solar DC / DC converter 32C, a charge / discharge DC / DC converter 33, an AC / DC converter 34, and a control unit 35C that controls these. . The solar DC / DC converter 32C detects the voltage when the solar panel 11 generates power. And DC / DC converter 32C for sunlight transmits the operation signal which makes an operation state from a stop state with respect to 35C of control parts. At this time, as shown in FIG. 7, the power generation amount of the solar panel 11 is in a state of a point B in the figure in which the control unit stopped state self-power consumption amount is larger. That is, the power generation amount of the solar panel 11 is in a state smaller than the self-power consumption amount of the control unit 35C. For this reason, the storage battery 31 is consumed by the supply of the self-consumption power of the storage battery 31.

  Thus, according to the solar energy storage system 1 according to the embodiment described above, when the generated power amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30, the control unit 35 is stopped. Change from state to operating state. Thereby, the storage battery device 30 can be appropriately controlled to change from the operation stop state to the operation state.

[Embodiment 2]
FIG. 4 is a block diagram illustrating a configuration of a solar power storage system 1A according to the second embodiment. In FIG. 4, the same parts as those in the first embodiment described above are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 4, the solar energy storage system 1A includes a hybrid system 10A and a storage battery device 30A. The hybrid system 10A includes a solar panel (solar power generation device) 11, a solar radiation measurement solar panel (generated power amount detection device, generated power meter, hereinafter simply referred to as a measurement solar panel) 11A, and a description later. Storage battery device 30A. In the present embodiment, the generated power amount detection device is configured by the measurement solar panel 11A and the generated power amount measurement unit 36 of the storage battery device 30A.

  The measurement solar panel 11 </ b> A measures a part of the generated power of the solar panel 11. In the present embodiment, the measurement solar panel 11A has a part of the solar panel 11 as a panel dedicated to measurement. The generated power of the measurement solar panel 11A is output to the generated power amount measuring unit 36 of the storage battery device 30A.

  The storage battery device 30A includes a storage battery 31, a solar DC / DC converter 32, a charge / discharge DC / DC converter 33, an AC / DC converter 34, a control unit 35A that controls these, and a measurement of generated electric energy. (Power generation amount detection device) 36.

  The generated power amount measuring unit 36 constantly monitors the generated power output from the measurement solar panel 11A. The generated power amount measurement unit 36 calculates the generated power amount of the solar panel 11 based on the generated power amount of the measurement solar panel 11A. When the power generation amount measurement unit 36 determines that the calculated power generation amount of the solar panel 11 is larger than the self power consumption amount of the storage battery 31 of the storage battery device 30A, the power generation amount measurement unit 36 from the stopped state to the control unit 35A of the storage battery device 30A. An operation signal for setting the operation state is transmitted. In this way, the storage battery device 30A is switched from the operation stop state to the operation state.

  According to such a solar power storage system 1A, as in the first embodiment, when the power generation amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30A, the control unit 35A is stopped. From the state to the operating state. For this reason, when the amount of power generated by the solar panel 11 is small, the control unit 35A remains in a stopped state. That is, it is possible to suppress the storage battery 31 from being consumed by the supply of self-power consumption in the control unit 35A.

  Further, when the solar power storage system 1A is large-scale, the solar panel 11 can be procured at a low cost because it is purchased in large quantities. For this reason, by using a part of the solar panel 11 as the measurement solar panel 11A, for example, the cost can be reduced as compared with the case where the solar radiation meter 20 is installed independently as in the first embodiment.

[Embodiment 3]
FIG. 5 is a block diagram illustrating a configuration of a solar energy storage system 1B according to the third embodiment. In FIG. 5, the same parts as those of the first embodiment described above are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 5, the solar energy storage system 1B includes a hybrid system 10B and a storage battery device 30B. The storage battery device 30B includes a storage battery 31, a solar DC / DC converter 32, a charge / discharge DC / DC converter 33, an AC / DC converter 34, and a control unit 35B that controls these. . In the present embodiment, the power generation amount of the solar panel 11 is constantly monitored by the control unit 35B. That is, the control unit 35B functions as a generated power amount detection device. When the control unit 35B determines that the generated power amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30B, the control unit 35B changes from the stopped state to the operating state. In this way, the storage battery device 30B is switched from the operation stop state to the operation state.

  According to such a solar power storage system 1B, as in the first embodiment, when the power generation amount of the solar panel 11 is larger than the self-power consumption amount of the storage battery 31 of the storage battery device 30B, the control unit 35B is stopped. From the state to the operating state. For this reason, when the amount of power generated by the solar panel 11 is small, the control unit 35B remains in a stopped state. That is, it can suppress that the storage battery 31 is consumed by supply of the self-power consumption in the control part 35B.

  Further, in this case, in the conventional solar system 1C shown in FIG. That is, it is only necessary to modify the conventional solar system 1C and can be introduced at low cost.

  The above-described embodiments can be combined without departing from the scope of the invention.

  For example, according to the capacity | capacitance of specific load, you may arrange | position the transformer matched to specific load other than the storage battery apparatus 30. FIG.

  Moreover, the control part 35 is good also as a stop state in predetermined time slots, such as the time slot | zone from sunset to sunrise, for example. Thus, what kind of case the control part 35 should be made into a stop state should just be suitably determined according to the installation conditions and installer of the solar energy storage system 1.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 Solar power storage system, 10 Hybrid system, 11 Solar panel (solar power generation device, solar power generation panel), 20 Solar radiation meter (power generation amount detection device), 30 Storage battery device (storage battery), 31 Storage battery, 32 Sun DC / DC for light, 33 DC / DC for charge / discharge, 34 AC / DC, 35 Control unit

Claims (3)

A solar power generation device that generates power by sunlight, a storage battery that stores electric power supplied from the solar power generation device, a control unit that controls an operation state of the storage battery, and operates by supplying power from the storage battery ; A power generation amount detecting device for detecting the amount of generated power in the solar power generation device, wherein the control unit has a remaining amount of the storage battery equal to or greater than a predetermined remaining amount, and the commercial power system is operating normally The control unit itself is changed from the operating state to the stopped state, and the generated power amount detection device is configured to control the control unit when the generated power amount is larger than the control unit operating state self-power consumption amount of the storage battery. A solar power storage system, characterized by transmitting a control signal for switching from a stopped state to an operating state. The power generation amount detection device is a solar power meter that measures the amount of solar radiation or a power generation power meter that measures the power generation amount of the solar power generation device,
The solar energy storage system according to claim 1. The solar power generation device is connected to a plurality of solar power generation panels,
The power generation meter measures the amount of power generated by a part of the photovoltaic power generation panel.
The solar energy storage system according to claim 2.

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