JP7529200B2 - Energy storage system, expansion function unit with storage battery, and expansion function unit - Google Patents

Description

The present invention relates to a power storage system, a battery-equipped expansion function unit that constitutes the power storage system, and an expansion function unit.

In order to prevent the depletion of limited environmental resources, there is growing awareness of the use of renewable energy sources such as solar, hydroelectric, and geothermal. In particular, the FIT (Feed-in Tariff) scheme for surplus electricity has led to the widespread use of solar panels installed in homes to sell surplus electricity.

For example, Patent Document 1 discloses a power storage system configured by retrofitting a storage battery to an existing power supply unit (photovoltaic power generation system) including a power generation device (PV panel). In the power storage system disclosed in Patent Document 1, the power conditioner performs MPPT control to extract maximum power from the solar panel. This power storage system utilizes the storage battery to efficiently utilize surplus power. Demand for such power storage systems is increasing, especially among ordinary households seeking to increase their self-consumption rate after the expiration of the FIT target period.

JP 2017-175785 A

However, the energy storage system disclosed in Patent Document 1 leaves room for improvement in terms of stably supplying a set amount of power from the storage battery to a power conditioner that performs MPPT control.

The present invention was made in consideration of the above-mentioned problems, and provides a power storage system, a storage battery-equipped expansion function unit, and an expansion function unit that stably supplies a set amount of power from a storage battery to a power conditioner.

The power storage system of the present invention comprises:
A power generation device which is a renewable energy power generation means for generating DC power;
a power conditioner capable of performing MPPT control including voltage scanning on the power generation device to extract the DC power from the power generation device at a predetermined power setting value;
a storage battery that is charged with the DC power supplied from the power generation device;
an extended function unit connected to the power generation device, the power conditioner, and the storage battery, and having a power sharing function of distributing power supplied from the power generation device between the power conditioner and the storage battery, and a power return function of supplying a predetermined set power from the storage battery to the power conditioner;
The extended function unit includes a simulation unit that variably adjusts a direct current discharged from the storage battery so as to follow the voltage scan of the MPPT control of the power conditioner in the power return function,
The simulation unit includes a bridge circuit connected to the storage battery and converting DC power output from the storage battery into AC power, an LLC resonant device connected to the bridge circuit, an isolation transformer that transforms an input voltage from the LLC resonant device and outputs it to a bridge diode, the bridge diode, a capacitor that smoothes the output from the bridge diode and outputs DC power to the power conditioner, a control unit that obtains a feedback signal for the output to the power conditioner, and a generation circuit that transmits a gate signal to the bridge circuit in response to a signal from the control unit to modulate a switching frequency or a pulse width, and is characterized in that impedance matching is performed to align the output impedance of the extended function unit, the input impedance of the power conditioner, and the characteristic impedance of a transmission path .
The battery-equipped expansion function unit of the present invention constitutes the power storage system,
The storage battery and the extended function unit are configured,
The power supply unit is characterized by having an interface unit that is retrofitted and electrically connected to a power supply unit that is previously configured with the power generation device and the power conditioner.
The expansion function unit of the present invention constitutes the battery-equipped expansion function unit,
The power conditioner is characterized by having an interface unit electrically connected between the storage battery and the power conditioner.

According to the power storage system of the present invention, the DC current is variably adjusted in accordance with the voltage scan from the power conditioner, thereby making it possible to stabilize the power supply from the storage battery to the power conditioner.
Furthermore, the battery-equipped expansion function unit can be retrofitted to an existing power supply unit to provide the same effects as the power storage system.
Furthermore, according to the expansion function unit, when power is supplied from the storage battery to the power conditioner, the effects achieved by the above-mentioned power storage system can be enjoyed.

1 is a schematic diagram showing an overall configuration of a power storage system according to a first embodiment; FIG. 2 is a schematic functional block diagram of the power storage system. FIG. 2 is a functional block diagram of an extended function unit. FIG. 2 is an explanatory diagram showing a configuration of a simulation unit. FIG. 11 is a schematic functional block diagram of a power storage system according to a second embodiment. FIG. 13 is a schematic functional block diagram showing a modified example, and is a diagram of a power storage system including a system control unit including a trigger information acquisition unit.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
The embodiment described below is merely an example for facilitating understanding of the present invention, and does not limit the present invention. In other words, the configuration, numerical values, etc. described below may be modified or improved without departing from the spirit of the present invention, and the present invention naturally includes equivalents. In this specification, there is no strict distinction between "less than" and "less than".
In addition, in all drawings, similar components are given similar symbols and duplicated explanations are omitted as appropriate.

＜＜Overview＞＞
First, an outline of the present invention will be described with reference mainly to FIGS.
FIG. 1 is a schematic diagram showing an overall configuration of a power storage system X according to an embodiment of the present invention, and FIG. 2 is a schematic functional block diagram of the power storage system X. As shown in FIG.

As shown in FIG. 1 , the energy storage system X of this embodiment includes a power generation device (solar panel 1) which is a renewable energy power generation means that generates DC power, a power conditioner 3 which is capable of performing MPPT control including voltage scanning on the solar panel 1 to extract DC power from the solar panel 1 at a predetermined power setting value, a storage battery 4 which charges the DC power supplied from the solar panel 1, and an expansion function unit 2 which is connected to the solar panel 1, the power conditioner 3, and the storage battery 4.
As shown in FIG. 2 , the extended function unit 2 variably adjusts the DC current discharged from the storage battery 4 so as to follow the voltage scan from the power conditioner 3 to the solar panel 1 , and supplies a constant power to the power conditioner 3 .
Specifically, "tracking" means adjusting the value of the current supplied from the expansion function unit 2 in accordance with the voltage value obtained by the voltage scan performed by the MPPT control unit 31 of the power conditioner 3 for the expansion function unit 2, thereby keeping the power supplied to the power conditioner 3 constant.

The simulation unit 24 that constitutes the extended function unit 2 variably adjusts the DC current discharged from the storage battery 4 in accordance with the voltage scan from the power conditioner 3 to the solar panel 1, and supplies a constant power to the power conditioner 3.

It should be noted that the "constant power" is, for example, a value that is the maximum power when DC power is extracted from the solar panel 1 under that environment (amount of sunlight irradiation).
In addition, in this embodiment, a solar panel 1 is described as the "renewable energy power generation means", but the present invention is not limited to the solar panel 1 and may be a wind power generation device, a hydroelectric power generation device, a geothermal power generation device, etc.

According to the above configuration, the DC current discharged from the storage battery 4 is variably adjusted in accordance with the voltage scan from the power conditioner 3, so that a constant power can be supplied from the storage battery 4 to the power conditioner 3.

<<Overall structure>>
Next, the overall configuration of the power storage system X will be described mainly with reference to FIGS.
The power storage system X is composed of an expansion function unit Y with a storage battery and a power supply unit Z, as shown in FIG.
The battery-equipped expansion function unit Y is composed of a storage battery 4 and an expansion function unit 2, and has an interface section 8 that is retrofitted and electrically connected to a power supply unit Z that is pre-configured with a power generation device (solar panel 1) and a power conditioner 3, as shown in FIG. 2 .
The expansion function unit 2 constitutes an expansion function unit Y with a storage battery, and has an interface section electrically connected between the storage battery 4 and the power conditioner 3 .

According to the above configuration, even if the power supply unit Z consisting of a power generation device (solar panel 1) and a power conditioner 3 is already installed, the battery-equipped expansion function unit Y can be attached to the power supply unit Z via the interface unit 8.
As will be described later, the provision of the battery-equipped expansion function unit Y does not affect the behavior or connection conditions of the power supply unit Z downstream.

Furthermore, by attaching the expansion function unit 2 to the location where the storage battery 4 and the power conditioner 3 are provided, charging of the storage battery 4 from the power generation device and output from the storage battery 4 to the power conditioner 3 can be performed efficiently.
Furthermore, the present invention is not limited to such a configuration, and the power storage system X may be configured such that the storage battery-equipped expansion function unit Y and the power supply unit Z are integrally configured.

The energy storage system X is composed of a solar panel 1 as a power generation device, a power conditioner 3, an expansion function unit 2 connected between the solar panel 1 and the power conditioner 3, and a storage battery 4 connected to the expansion function unit 2.

As shown in FIG. 2, the extended function unit 2 includes an output switching unit 20, a system control unit 21, a charger 22, an MPPT control unit 23, a simulation unit 24, a discharge control unit 26, and current sensors S1 and S2.
Although the extended function unit 2 has been described as being equipped with a current sensor S2, this is not limited to such a configuration, and the extended function unit 2 may be configured to acquire information regarding the current value from a current sensor (not shown) equipped in the power conditioner 3.

The output switching unit 20 distributes some or all of the power supplied from the solar panel 1 to the storage battery 4 during charging, and enables discharging from the solar panel 1 to the power conditioner 3 and/or from the storage battery 4 to the power conditioner 3 during discharging.
The system control unit 21 manages the output switching unit 20, the charge control unit 25, and the discharge control unit 26. The system control unit 21 has a memory and a CPU (not shown), and can control the output switching unit 20 according to the current value detected by the current sensor S1 to distribute power between the power conditioner 3 and the storage battery 4.
The charger 22 has a function of charging the storage battery 4 with the allocated power.

The MPPT control unit 23 performs MPPT control similar to that of an MPPT control unit 31 provided in the power conditioner 3 (described later) only when charging 100% of the power generated by the solar panel 1 .
MPPT control involves varying the voltage (scan voltage) to automatically find the combination of voltage and current (maximum output point) that maximizes power generation from the voltage and current, which constantly fluctuate depending on the amount of solar radiation and temperature, and controlling the amount of power generation to be maintained.

The simulation unit 24 will be described with reference to Fig. 4 in addition to Fig. 2. Fig. 4 is an explanatory diagram showing the configuration of the simulation unit 24.
When the simulation unit 24 is connected to the power conditioner 3, it matches the impedance and response time with the power conditioner 3, and thereafter performs discharging while following the voltage scan of the power conditioner.

As shown in FIG. 4, the simulation unit 24 includes a full bridge circuit 24a, an LLC resonator 24b, a transformer 24c, a bridge diode 24d, a control unit 24e, and a PFM/PWM generating circuit 24f.
The full-bridge circuit 24a is connected to the storage battery 4, converts the direct current output from the storage battery 4 into alternating current, and outputs the alternating current to the LLC resonant device 24b.
The LLC resonator 24b is connected to the full-bridge circuit 24a and is composed of a resonant inductance, an exciting inductance, and a capacitor.
The transformer 24c is an insulating transformer capable of preventing reverse current, which transforms the voltage input from the LLC resonator 24b and outputs the transformed voltage to the bridge diode 24d. By including the transformer 24c, the extended function unit 2 can be suitably connected to various power conditioners 3.
The bridge diode 24d inverts the negative voltage side of the AC input and outputs a pulsating current. A capacitor is connected to the output side to smooth the output, thereby enabling a DC voltage to be output.

The control unit 24e monitors both the current and voltage so that the current output from the bridge diode 24d becomes the set current, and sends a signal to the PFM, PWM generation circuit 24f to perform impedance matching and response time matching.
The PFM, PWM generating circuit 24f modulates the switching frequency and/or the pulse width by sending a gate signal to the full bridge circuit 24a.

The simulation unit 24 configured as described above is able to calculate a current that follows the voltage even if the voltage fluctuates due to MPPT control by the MPPT control unit 31 of the power conditioner 3, and supply a constant amount of power from the storage battery 4 to the power conditioner 3. In this way, the simulation unit 24 is able to output stable power from the storage battery 4 to the power conditioner 3 in the short term.
Furthermore, even if the voltage of the storage battery 4 decreases due to long-term use, for example, the simulation unit 24 can increase the voltage by the rate of the voltage decrease, thereby making it possible to supply a constant amount of power from the storage battery 4 to the power conditioner 3. In this way, the simulation unit 24 can output stable power from the storage battery 4 to the power conditioner 3 over the long term.
According to the above configuration, even for an existing power conditioner 3 that is not connected to a storage battery 4, by attaching an expansion function unit 2 equipped with a simulation unit 24, it is possible to supply power from the storage battery 4 to the power conditioner 3.

The charging control unit 25 controls charging by the charger 22 and the MPPT control unit 23 based on the values of the current sensors S1 and S2. The current sensor S1 detects the output current of the solar panel 1, and the current sensor S2 detects the output current from the extended function unit 2 to the power conditioner 3.
The discharge control section 26 controls the discharge by the simulation section 24 based on the values of the current sensors S1 and S2.
For example, the discharge control unit 26 continuously outputs a rated power of 1.2 kW during discharge from the storage battery 4 via the simulation unit 24. The output value from the storage battery 4 is not limited to the rated power, and may be, for example, a power value that matches a load power lower than the rated power.

The power conditioner 3 includes a DC/DC converter 30 , an MPPT control unit 31 , and an inverter 32 .
The power sharing function and the power return function, which are functions of the extended function unit 2, will be described next.

<Power sharing>
The power sharing function is a function that distributes the power supplied from the solar panel 1 to the expansion function unit 2 between the power conditioner 3 and the storage battery 4. The expansion function unit 2 has a power conditioner priority mode, a storage battery priority mode, and a surplus power charging mode as the power sharing function. These will be described next.

[Power conditioner priority mode]
As described above in the summary of the invention, the power conditioner priority mode is a mode in which supplying DC power from the solar panel 1 to the power conditioner 3 is given priority over supplying DC power from the solar panel 1 to the storage battery 4 .
In this mode, of the DC power supplied from the solar panel 1 to the expansion function unit 2, the amount of power exceeding the first threshold power set as the maximum power to be supplied to the power conditioner 3 is supplied to the storage battery 4.

For example, when the power generated by the solar panel 1 exceeds the processing load (capacity) of the power conditioner 3 , the surplus power from the solar panel 1 can be charged into the storage battery 4 .
This makes it possible to shift the timing of power generation and the timing of self-consumption, thereby suppressing losses in the power generated by the solar panels 1. In addition, when the amount of power generated by the solar panels 1 increases in the summer, for example, it is possible to charge the storage battery 4 with power that exceeds the capacity of the power conditioner 3. Furthermore, it becomes possible to mount solar panels 1 on a building that exceed the capacity of the power conditioner 3.
The first threshold power is configured to be set in the extended function unit 2 .

In addition, if the first threshold power as the planned power of the power conditioner 3 is set to 3 kW, when it is cloudy and the power generation of the solar panel 1 is 1 kW, the system control unit 21 supplies it all to the power conditioner 3 without allocating it to the storage battery 4.
The system control unit 21 is able to freely execute such control since it monitors the current values from the current sensors S1 and S2.
Specifically, the current sensor S1 detects a current value corresponding to the power generated by the solar panel 1, and the current sensor S2 detects a current value supplied from the extended function unit 2 to the power conditioner 3. The charger 22 includes a current sensor and a voltage sensor (not shown), and these sensors enable the charger 22 to detect the power to be charged to the storage battery 4.

For example, the first threshold power is the rated power (capacity) of the power conditioner 3. For example, this rated power is 4.4 kW or 5.5 kW.
According to the above configuration, as described above, when the power generated by the solar panel 1 exceeds the processing load (capacity) of the power conditioner 3, the surplus power of the solar panel 1 can be charged to the storage battery 4.

[Battery Priority Mode]
The system control unit 21 is capable of operating the output switching unit 20 in a battery priority mode which is selectively set to a power conditioner priority mode, and which prioritizes supplying DC power from the solar panel 1 to the storage battery 4 over supplying DC power from the power generation device (solar panel 1) to the power conditioner 3.
The output switching unit 20 operating in the battery priority mode supplies to the power conditioner 3 the amount of DC power supplied from the solar panel 1 to the expansion function unit 2 that exceeds the second threshold power set as the maximum power to be supplied to the storage battery 4.

For example, if the rated power of the storage battery 4, 1.2 kW, is set as the second threshold power, and the solar panel 1 outputs 4 kW, the system control unit 21 supplies 1.2 kW to the storage battery 4 while supplying 2.8 kW to the power conditioner 3.

According to the above configuration, by prioritizing charging the storage battery 4, it becomes easier to store power in the storage battery 4, and it becomes easier to accommodate the supply of power, especially when it is consumed by the home. For example, in a household with a low load during the day, it may be possible to keep costs low by storing power in the storage battery 4 rather than sending it to the grid 6 for sale. In this case, it is preferable to use the storage battery priority mode.

Furthermore, by supplying the power exceeding the second threshold power to the power conditioner 3, it is possible to prevent power loss caused by continuing to charge the storage battery 4 even after the storage battery 4 is fully charged.
The amount of power and time to be allocated to the storage battery 4 may be set by the system control unit 21 .

In addition, when the amount of self-consumption power is low compared to the power that the power conditioner 3 requests to be supplied from the solar panel 1, or when it is predicted that the amount of solar radiation will be low due to cloudy or rainy weather in the future, the system control unit 21 may control the output switching unit 20 to supply at least a portion of the power to the storage battery 4 without supplying the requested amount of power to the power conditioner 3.

The extended function unit 2 has an MPPT control unit 23 that performs MPPT control (maximum power point tracking control) on the power generation device (solar panel 1).
The MPPT control unit 23 functions in the battery priority mode when the power generated by the solar panel 1 is supplied to the storage battery 4 instead of being supplied to the power conditioner 3 .

For example, in the battery priority mode, when the second threshold power is 1.2 kW and the output of the solar panel 1 is only 1 kW, which is lower than the second threshold power, the system control unit 21 controls the output switching unit 20, the charging control unit 25 and the MPPT control unit 23 to supply power only to the storage battery 4.
In this case, the MPPT control unit 23 included in the extended function unit 2 functions, instead of the MPPT control unit 31 included in the power conditioner 3.

After that, when the output of the solar panel 1 exceeds 1.2 kW, the system control unit 21 will supply the power exceeding 1.2 kW to the power conditioner 3. In this case, the MPPT control unit 23 is stopped under the control of the system control unit 21, and the MPPT control unit 31 provided in the power conditioner 3 will function.

For example, in order to eliminate the effects of noise, when information is acquired that the output of the solar panel 1 has continued to exceed the second threshold power for a predetermined period of time (e.g., 10 minutes), the system control unit 21 may start supplying power to the power conditioner 3, stop the function of the MPPT control unit 23, and activate the MPPT control unit 31.

Conversely, if the output of the solar panel 1 is lower than the second threshold power and this state continues for a predetermined time (e.g., 10 minutes), the system control unit 21 may stop the supply of power to the power conditioner 3 and start the supply of power to the storage battery 4, stop the function of the MPPT control unit 31, and start the MPPT control unit 23.

According to the above configuration, power can be effectively supplied from the solar panel 1 to the storage battery 4 .
Conversely, the MPPT control unit 23 does not function when power from the solar panel 1 is being supplied to the power conditioner 3. In this case, the MPPT control unit 31 of the power conditioner 3 functions to supply the maximum power generated from the solar panel 1, and when power is supplied to the storage battery 4, a portion of the maximum power generated by the solar panel 1 is supplied to the storage battery 4.

[Excess power charging mode]
Next, the surplus power charging mode will be described mainly with reference to Fig. 5. Fig. 5 is a schematic functional block diagram of a power storage system S according to a second embodiment.

As shown in FIG. 5, the extended function unit 2 includes an information acquisition unit 21a that acquires information indicating the load power of the AC power converted by the power conditioner 3 and consumed by the external load.
The system control unit 21 is capable of operating the output switching unit 20 in an operating mode that can be selectively set to a power control priority mode, and can operate the output switching unit 20 in a surplus power charging mode in which the amount of DC power supplied from the power generation device (solar panel 1) to the expansion function unit 2 that exceeds the DC power corresponding to the load power is charged to the storage battery 4.

The “information indicating the load power of AC power consumed by an external load” is, for example, information acquired by the information acquisition unit 21a from a current sensor S3 provided upstream of the distribution board 5 and a current sensor S4 provided downstream of the distribution board 5.
The "DC power corresponding to the load power" specifically means "DC power required for converting the load power indicated by the information acquired by the information acquisition unit 21a into AC power by the power conditioner 3." The "corresponding DC power" may be equal to the load power or may be slightly more than the load power.

According to the above configuration, power according to the load power is supplied to the outside via the power conditioner 3, while the remaining power is charged to the storage battery 4, allowing for optimal self-consumption.

The storage battery 4 in this embodiment is a lead acid battery. In particular, if a lead acid battery is used as the storage battery 4, costs can be reduced compared to a lithium ion battery. In addition, it is environmentally friendly because it is easy to reuse, and by replacing it with a new one, it becomes possible to continue using it in a highly efficient state. Note that, instead of a lead acid battery, a lithium ion battery may also be used as the storage battery 4.

<Power Return>
The power return function is a function for supplying power from the storage battery 4 of the power storage system X to the power conditioner 3 via the extended function unit 2. The extended function unit 2 has, as the power return function, a cycle operation mode, a solar power reinforcement mode, and a VPP mode. These will be described later.

The power conditioner 3 is configured to be able to perform MPPT control including voltage scanning on the solar panel 1 and extract DC power from the solar panel 1 at a predetermined power setting value.
The extended function unit 2 stably supplies a predetermined set value of power from the storage battery 4 to the power conditioner 3 .

More specifically, the simulation unit 24 that constitutes the extended function unit 2 variably adjusts the output current that follows the voltage scan from the power conditioner 3 to the solar panel 1, and supplies a predetermined set value (e.g., rated) of power to the power conditioner 3.
For example, the "predetermined set value" is a value that provides the maximum power when DC power is extracted from the solar panel 1 under a certain environment (amount of sunlight irradiation).

According to the above configuration, the simulation unit 24 variably controls the current value in accordance with the voltage scan from the power conditioner 3, so that stable power can be supplied from the storage battery 4 to the power conditioner 3 without modifying the control that the power conditioner 3 performs on the solar panel 1.

The extended function unit 2 has a simulation unit 24 that, when connected to the power conditioner 3, acquires impedance and response time information from the power conditioner 3 and variably adjusts the direct current discharged from the storage battery 4 so as to match the impedance and response time of the power conditioner 3.
Specifically, the simulation unit 24 performs impedance matching using the LLC resonator 24b shown in FIG. 4 to match the output impedance from the extended function unit 2, the input impedance of the power conditioner 3, and the characteristic impedance of the transmission path.
In addition, the simulation unit 24 performs response time matching to match the response time with the MPPT control unit 31 of the power conditioner 3 by modulating the switching frequency using the PFM, PWM generation circuit 24f.

With the above configuration, the DC current discharged from the storage battery 4 is matched with the impedance and response time of the power conditioner 3, so that a predetermined amount of power can be stably supplied from the storage battery 4 to the power conditioner 3.

[Cycle operation mode]
Next, the cycle operation mode will be described with reference mainly to Fig. 3 in addition to Fig. 2. Fig. 3 is a functional block diagram of the extended function unit 2.
The extended function unit 2 includes a clock means 2a for acquiring time information and a time period setting means 2b for setting a predetermined time period of a day. The extended function unit 2 repeatedly supplies DC current from the storage battery 4 to the power conditioner 3 each day during the set predetermined time period.
According to the above configuration, during a specific time period, the power from the storage battery 4 can be consumed in-house, and during other time periods, the power charged in the storage battery 4 can be effectively used. Note that "daily" means over multiple days, and may be multiple consecutive days or multiple intermittent days. Furthermore, the multiple days may be every day or specific days of the week.

For example, the "predetermined time period" is the nighttime period (the period from sunset to sunrise). By discharging power from the storage battery 4 to the power conditioner 3 during the nighttime period in this manner, it is possible to shift the time when power is generated from the solar panel 1 (the sunshine period) and the time when power is supplied to the power conditioner 3.

For example, the extended function unit 2 allocates the amount of power to charge the storage battery 4 at about 5 kW·h per day. The storage battery 4 then discharges the power charged during the day in about four hours at night.
During discharging, it is preferable to discharge the storage battery 4 up to a certain threshold voltage rather than bringing the voltage of the storage battery 4 to zero in order to extend the life of the storage battery 4 .
In addition, the time when the storage battery 4 discharges electricity to the power conditioner 3 may be during sunshine hours (daytime) and can be set arbitrarily.

As shown in FIG. 5, the extended function unit 2 includes a load information acquisition unit (information acquisition unit 2c) that acquires information indicating the load power of the AC power converted by the power conditioner 3 and consumed by the external load.
The expansion function unit 2 supplies DC current from the storage battery to the power conditioner at a power level corresponding to the load power acquired by the information acquisition unit 2c.

As described above in the explanation of the surplus power charging mode, the “information indicating the load power of AC power consumed by an external load” is, for example, information acquired by the information acquisition unit 2c from a current sensor S3 provided upstream of the distribution board 5 and a current sensor S4 provided downstream of the distribution board 5.
In addition, the "DC power corresponding to the load power" specifically means "the DC power required to convert the load power indicated by the information acquired by the information acquisition unit 2c into AC power by the power conditioner 3."
According to the above configuration, in the cycle operation mode, discharge according to the load power is possible.

[Sunlight reinforcement mode]
The expansion function unit 2 includes a power monitoring means (current sensor S2 and a voltage sensor not shown) that monitors over time the power supply from the power generation device (solar panel 1) to the power conditioner 3, and a power setting means 2e (see Figure 3) that sets the required power to be supplied from the solar panel 1 to the power conditioner 3.

Here, the term "over time" specifically means at least a number of times during the daytime when sunlight is shining, and more specifically, preferably every few minutes.
The "when the power falls below the required power" may start supplying from the storage battery when the power actually falls below the required power, or when the power is predicted to fall below the required power (in the future) if the monitoring result of the power monitoring means shows a downward trend. In other words, the power supply may start when the power is equal to or above the set required power.
Similarly, the "deficient power" does not have to be completely equal to the power shortage.
In other words, it may be a value equal to the difference between the required power and the generated power at that time, or it may be a predetermined power (for example, the minimum level of power that can be extracted from the storage battery 4, or a constant value).

When the supply power monitored by the current sensor S2 (and a voltage sensor, not shown) falls below the required power set in the power setting means 2e, the expansion function unit 2 variably adjusts the direct current so that the shortage of power is supplied from the storage battery 4 to the power conditioner 3.

For example, the extended function unit 2 (discharge control unit 26) calculates the power supply from the solar panel 1 based on the current value detected by the current sensor S2 and the voltage detected by a voltage sensor (not shown), and controls the power supply from the storage battery 4 to the power conditioner 3 to make up for the power that is insufficient for the rated power of the power conditioner 3. At this time, the extended function unit 2 (simulation unit 24) variably adjusts the DC current discharged from the storage battery 4 to make up for the power that is insufficient for the rated power of the power conditioner 3 while matching it to the voltage from the solar panel 1.
As is clear from the fact that the sunlight supplementary mode is based on supplying power from the solar panel 1 to the power conditioner 3, the sunlight supplementary mode is a control that is performed during sunshine hours.

Specifically, a junction box (not shown) may be provided to aggregate the power output from the solar panel 1 and the power output from the storage battery 4. This makes it easier to match the impedance and response time of the power conditioner 3.

According to the above configuration, even if the power generated by the solar panel 1 is insufficient for the required power set to be supplied to the power conditioner 3, the expansion function unit 2 can control the storage battery 4 to supply current to the power conditioner 3.

The expansion function unit 2 is equipped with a voltage setting means 2f (see Figure 3) that sets a lower limit voltage value for the storage battery 4, and supplies DC power from the storage battery 4 to the power conditioner 3 until the voltage of the storage battery 4 drops and reaches the lower limit voltage value.
Here, "supplying DC power... until the lower limit voltage value is reached" includes the case where DC power is actually supplied until the lower limit voltage value is reached, and the case where DC power is supplied until the lower limit voltage value is not reached and after the power supply to power conditioner 3 begins to be controlled so as not to reach the lower limit voltage value.
According to the above configuration, the storage battery 4 can be prevented from entering a low charge state and the occurrence of sulfation can be prevented, thereby extending the life of the storage battery 4.

For example, the extended function unit 2 switches to the battery priority mode after receiving a signal from a voltage sensor (not shown) indicating that the voltage value of the storage battery 4 has reached a lower limit voltage value. In this way, the low charge state of the storage battery 4 can be quickly restored.

[VPP mode]
Next, the VPP mode will be described mainly with reference to Fig. 6. Fig. 6 is a schematic functional block diagram showing a modified example, which is a diagram of a power storage system equipped with a system control unit including a trigger information acquisition unit 21c.

The extended function unit 2 includes a trigger information acquisition section 21c that acquires trigger information from the outside via the network 7, and a discharge amount setting section 2g (see FIG. 3) that sets the amount of power to be taken out from the storage battery 4.
The extended function unit 2 supplies a set amount of DC power from the storage battery 4 to the power conditioner 3 based on the trigger information acquired by the trigger information acquisition unit 21c.
Specifically, a discharge control unit 26 constituting the extended function unit 2 supplies a set amount of DC power from the storage battery 4 to the power conditioner 3. The network 7 is, for example, a dedicated line such as Wi-Fi.

For example, by the trigger information acquisition unit 21c acquiring trigger information, the expansion function unit 2 may be configured to charge the power conditioner 3 without supplying power from the solar panel 1 except when the storage battery 4 is discharging, thereby maintaining a fully charged state.
Any time other than when trigger information is acquired and discharge occurs is referred to as "normal time."

With the above configuration, the power stored in the storage battery 4 can be efficiently used, for example, as an entire virtual power plant through the network 7, and can also be used for backup purposes during power outages.

It is preferable that the system control unit 21 appropriately combines the above various modes.
For example, when the storage battery 4 is not fully charged, the system control unit 21 controls the output switching unit 20 in power conditioner priority mode, and if the power supplied from the solar panel 1 is 3 kW or less, it supplies power to the power conditioner 3, and if it exceeds that, it supplies the excess power to the storage battery 4.
When the storage battery 4 is fully charged, the output switching unit 20 is controlled in the solar power supplementary mode, and when the power supplied from the solar panel 1 falls below 3 kW, power is supplied from the storage battery 4 as a supplementary supply.

The above embodiment encompasses the following technical ideas.
(1)
A power generation device which is a renewable energy power generation means for generating DC power;
a power conditioner capable of performing MPPT control including voltage scanning on the power generation device to extract the DC power from the power generation device at a predetermined power setting value;
a storage battery that is charged with the DC power supplied from the power generation device;
an expansion function unit connected to the power generation device, the power conditioner, and the storage battery;
The expansion function unit is characterized in that it variably adjusts the direct current discharged from the storage battery to follow the voltage scan from the power conditioner to the power generation device, thereby supplying a constant power to the power conditioner.
(2)
The storage system according to claim 1, wherein the expansion function unit includes a simulation unit that, when connected to the power conditioner, acquires impedance and response time information from the power conditioner and variably adjusts the direct current discharged from the storage battery so as to match the impedance and the response time of the power conditioner.
(3)
The expansion function unit includes a timing means for acquiring time information and a time zone setting means for setting a predetermined time zone within a day, and the storage battery repeatedly supplies the DC current to the power conditioner each day during the set predetermined time zone.
(4)
The extended function unit includes a load information acquisition unit that acquires information indicating load power of AC power converted by the power conditioner and consumed by an external load,
The power storage system according to claim 3, wherein the extended function unit supplies the direct current from the storage battery to the power conditioner at a power corresponding to the load power acquired by the load information acquisition unit.
(5)
The extended function unit includes a power monitoring means for monitoring over time the power supply being supplied from the power generation device to the power conditioner, and a power setting means for setting a required power to be supplied from the power generation device to the power conditioner,
The storage system according to any one of (1) to (4), wherein the expansion function unit variably adjusts the direct current so as to supply insufficient power from the storage battery to the power conditioner when the supply power monitored by the power monitoring means is equal to or less than the required power set in the power setting means.
(6)
The storage system according to any one of (3) to (5), wherein the expansion function unit includes a voltage setting means for setting a lower limit voltage value of the storage battery, and supplies the DC power from the storage battery to the power conditioner until the voltage of the storage battery drops and reaches the lower limit voltage value.
(7)
the extended function unit includes a trigger information acquisition unit that acquires trigger information from an external device via a network, and a discharge amount setting unit that sets an amount of power to be drawn from the storage battery;
The power storage system according to claim 1 or 2, wherein the expansion function unit supplies the DC power of the amount of power from the storage battery to the power conditioner based on the trigger information acquisition unit acquiring the trigger information.
(8)
The power storage system according to any one of (1) to (7), wherein the storage battery is a lead storage battery.
(9)
The storage system according to any one of (1) to (8) is configured,
The storage battery and the extended function unit are configured,
A battery-equipped expansion function unit, comprising an interface section that is retrofitted and electrically connected to a power supply unit that is previously configured with the power generation device and the power conditioner.
(10)
(9) A storage battery-equipped expansion function unit is configured,
An expansion function unit comprising an interface unit electrically connected between the storage battery and the power conditioner.

1. Solar panels (power generation equipment)
2 Extended function unit 2a Timekeeping means 2b Time zone setting means 2c Information acquisition unit 2e Power setting means 2f Voltage setting means 2g Discharge amount setting means 3 Power conditioner 4 Storage battery (lead storage battery)
5 Distribution board 6 System 7 Network 8 Interface unit 20 Output switching unit 21 System control unit 21a Information acquisition unit 21c Trigger information acquisition unit 22 Charger 23 MPPT control unit 24 Simulation unit 24a Full bridge circuit 24b LLC resonator 24c Transformer 24d Bridge diode 24e Control unit 24f PFM, PWM generation circuit 25 Charging control unit 26 Discharging control unit 30 DC/DC converter 31 MPPT control unit 32 Inverter S Power storage system S1 Current sensor S2 Current sensor (power monitoring means)
S3 Current sensor S4 Current sensor X Power storage system Y Expansion function unit with storage battery Z Power supply unit

Claims (10)

A power generation device which is a renewable energy power generation means for generating DC power;
a power conditioner capable of performing MPPT control including voltage scanning on the power generation device to extract the DC power from the power generation device at a predetermined power setting value;
a storage battery that is charged with the DC power supplied from the power generation device;
an extended function unit connected to the power generation device, the power conditioner, and the storage battery, and having a power sharing function of distributing power supplied from the power generation device between the power conditioner and the storage battery, and a power return function of supplying a predetermined set power from the storage battery to the power conditioner;
The extended function unit includes a simulation unit that variably adjusts a direct current discharged from the storage battery so as to follow the voltage scan of the MPPT control of the power conditioner in the power return function,
the simulation unit includes a bridge circuit connected to the storage battery and converting DC power output from the storage battery into AC power, an LLC resonator connected to the bridge circuit, an isolation transformer that transforms an input voltage from the LLC resonator and outputs the voltage to a bridge diode, the bridge diode, a capacitor that smoothes the output from the bridge diode and outputs DC power to the power conditioner, a control unit that acquires a feedback signal for the output to the power conditioner, and a generation circuit that transmits a gate signal to the bridge circuit in response to a signal from the control unit to modulate a switching frequency or a pulse width, and performs impedance matching to align an output impedance of the extended function unit, an input impedance of the power conditioner, and a characteristic impedance of a transmission line.
The present invention relates to an energy storage system. The simulation unit variably adjusts the DC current discharged from the storage battery so as to match the response time of the MPPT control of the power conditioner by modulating a switching frequency using the generation circuit .
The power storage system according to claim 1 . The extended function unit includes a clock means for acquiring time information and a time period setting means for setting a predetermined time period in a day, and repeatedly supplies the DC current from the storage battery to the power conditioner each day during the set predetermined time period.
The power storage system according to claim 1 or 2. The extended function unit includes a load information acquisition unit that acquires information indicating load power of AC power converted by the power conditioner and consumed by an external load,
The extended function unit supplies the DC current from the storage battery to the power conditioner at a power corresponding to the load power acquired by the load information acquisition unit.
The power storage system according to claim 3 . The extended function unit includes a power monitoring means for monitoring over time the power supply being supplied from the power generation device to the power conditioner, and a power setting means for setting a required power to be supplied from the power generation device to the power conditioner,
When the supply power monitored by the power monitoring means is equal to or less than the required power set in the power setting means, the extended function unit variably adjusts the DC current so as to supply the insufficient power from the storage battery to the power conditioner .
The power storage system according to claim 1 . The expansion function unit includes a voltage setting means for setting a lower limit voltage value of the storage battery, and supplies the DC power from the storage battery to the power conditioner until the voltage of the storage battery drops and reaches the lower limit voltage value .
The power storage system according to claim 3 . the extended function unit includes a trigger information acquisition unit that acquires trigger information from an external device via a network, and a discharge amount setting unit that sets an amount of power to be drawn from the storage battery;
The extended function unit supplies the DC power of the power amount from the storage battery to the power conditioner based on the trigger information acquisition unit acquiring the trigger information.
The power storage system according to claim 1 or 2. The power storage system according to any one of claims 1 to 7, wherein the storage battery is a lead storage battery. The power storage system according to any one of claims 1 to 8 is configured,
The storage battery and the extended function unit are configured,
A battery-equipped expansion function unit, comprising an interface section that is retrofitted and electrically connected to a power supply unit that is previously configured with the power generation device and the power conditioner. The battery-equipped expansion function unit according to claim 9 is configured,
An expansion function unit comprising an interface unit electrically connected between the storage battery and the power conditioner.

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