JP6787706B2 - Power storage control device, storage battery system and power storage control program - Google Patents

Description

The present invention relates to a storage control device, a storage battery system, and a storage control program for performing processing related to storage.

A consumer who uses electric power installs power generation equipment such as solar power generation and wind power generation on his / her own premises and uses the electric power generated by such power generation equipment (hereinafter referred to as "green power"). Is widely practiced.

In this respect, green power is a device whose output power fluctuates depending on the weather conditions and the amount of power generation is unstable. Therefore, in order to supply a predetermined electric power to the consumer in a relatively stable manner, it is preferable to use a storage battery system in combination.
In order to further promote the spread of such a storage battery system, it is desired that a high economic effect can be obtained when the storage battery system is used.

In order to obtain a high economic effect, for example, it is conceivable to preferentially supply the green power generated by solar power generation or the like or the green power stored in the storage battery system to the electric equipment which is the load of the consumer. .. In this way, the power charge of the distribution system, which is a commercial power source, can be suppressed, so that the economic effect can be enhanced. In addition, in this case, of the generated green power, surplus power that is not used by the customer's load can be sold to the power company so that the power sales fee can be obtained, which is a higher economy. You can also get the effect.

However, this is just a general theory, and some consumers may prioritize the use of green electricity rather than the economic effect. In this case, the storage battery system may be set to a mode in which charging the storage battery is prioritized over selling the surplus power to the electric power company. As described above, the mode for preferentially charging the storage battery is called, for example, a name such as "green mode". A technique for setting the green mode is disclosed in, for example, Patent Document 1.

Japanese Unexamined Patent Publication No. 2015-159726

Here, the charging of the surplus power to the storage battery is to charge the storage battery with the surplus power generated by the private power generation device, and originally, the system power does not intervene in charging the storage battery. However, in reality, there is a shortage of input (that is, buying power from the grid power) or surplus output (that is, selling power to the grid power) with the grid power that should not intervene during charging. It may be a problem. The reason for this is that depending on the amount of electricity purchased, the electricity purchased during charging may exceed the electricity sold during charging, which may result in economic loss. In this respect, as mentioned above, the green mode does not emphasize the economic effect. However, even if this is the case, it is not desirable that an unintended situation occurs in which a power purchase charge is incurred even though there is surplus power.

In this way, the reason why input / output with system power occurs, which should not occur originally, will be described. When charging the storage battery with surplus power, the amount of power generated and the load fluctuate, so the value of surplus power is not constant and changes erratically. In order to respond to such a change, it is necessary to change the value of the charging power so as to follow the change to the value of the surplus power, instead of continuing the charging with the value of the charging power once determined. In consideration of this point, in general, the system controller performs power measurement and calculation, and controls the power conditioner based on the calculation result to change the value of the charging power. However, the change in the charging power value by the system controller is not performed immediately each time a change in the surplus power occurs, but is performed at regular time intervals. On the other hand, there is a delay.

Since there is such a delay, when the surplus power changes, the surplus power and the charging power do not match, and input / output with the system power occurs as described above.

That is, as long as the charging power is changed by the system controller at regular time intervals, the above-mentioned situation "a power purchase charge is incurred even though there is surplus power" occurs. It is unavoidable and is problematic as it can result in economic losses.

Therefore, an object of the present invention is to provide a power storage control device, a storage battery system, and a power storage control program capable of compensating for the economic loss that may occur due to the power purchase charge.

According to the first aspect of the present invention, the surplus power which is the power supplied from the power generation device in excess of the power supplied to the load while supplying the power supplied from the distribution system and the power generation device to the load. Is a power storage control device that controls a system that stores power, and is a time point in which the power storage is performed for a predetermined time at the power value of the surplus power at the first time point and the predetermined time elapses from the first time point. Based on the power value of the surplus power at the second time point, it is determined whether or not the power has been purchased from the distribution system for the storage of electricity performed during the predetermined time, and the power purchase is performed. If it is determined that the power is purchased, a power storage control device is provided, which comprises a control means for selling power to the distribution system in order to compensate for the charge generated by the power purchase.

According to the second aspect of the present invention, there is a storage battery system including a power storage control device, the power generation device, and a storage battery provided by the first aspect of the present invention, and the power generation device is photovoltaic power generation. The storage control device supplies the power obtained by the solar power generation to the load, and the surplus power which is the power supplied in excess of the power supplied to the load. Is provided with a storage battery system characterized in that the storage battery stores the power.

According to the third aspect of the present invention, the surplus power which is the power supplied from the power generation device in excess of the power supplied to the load while supplying the power supplied from the distribution system and the power generation device to the load. Is a power storage control program for operating a computer as a power storage control device for controlling a system for storing power, in which the storage is performed for a predetermined time with the power value of surplus power at the first time point, and the first Whether or not power was purchased from the distribution system for electricity storage performed during the predetermined time based on the power value of the surplus power at the second time point when the predetermined time has elapsed from the time point. If it is determined that the power has been purchased, the computer is used as a power storage control device including a control means for selling the power to the distribution system in order to compensate for the charge generated by the power purchase. A power storage control program characterized by functioning is provided.

According to the present invention, it is possible to compensate for the economic loss that may occur due to the electricity purchase charge.

It is a block diagram which shows the basic structure of the whole storage battery system which is an embodiment of this invention. It is a block diagram which shows the structure of the system system controller included in the storage battery which is an embodiment of this invention. It is a flowchart (1/2) which shows the basic operation of the system controller in embodiment of this invention, and is especially the flowchart which shows the accumulation of the power purchase power amount and the power sale power amount during charging. It is a flowchart (2/2) which shows the basic operation of the system controller in embodiment of this invention, and is especially the flowchart which shows the power selling operation by the difference for reducing the electricity charge. It is a graph which shows the example of the relationship between surplus power and time for demonstrating the processing of the storage battery system which is an embodiment of this invention.

First, an outline of an embodiment of the present invention will be described. In the green mode, the embodiment of the present invention is charging the surplus power in order to automatically compensate for the economic loss caused by the grid power trading caused by the delay time in which the system follows the fluctuation of the surplus power value. It records the purchase and sale of grid power in the system, and intentionally sells power at a certain timing to settle the payment.

More specifically, in the present embodiment, a generated power sensor that measures the amount of power generated by solar power generation, a load power sensor that measures the power consumed by the load, and a system input / output power that measures the power output to the distribution system. Equipped with a sensor, the system controller acquires these power values at predetermined intervals and sends an instruction to the power conditioner to control the charge / discharge power. During charging of surplus power, the system power is divided into positive and negative and accumulated in a predetermined cycle, and these are used as the amount of power purchased and the amount of power sold. When the difference between the purchased power charge and the sold power charge becomes a loss, the surplus power is sold without charging a considerable amount of power. The difference in electricity will be sold on a daily or monthly basis by setting a due date in advance.
The above is the outline of the present embodiment.

Next, a mode for carrying out the invention will be described in detail with reference to the drawings.
First, referring to FIG. 1, the storage battery system 1 of the present embodiment includes a system controller 100, a storage battery subsystem 200, a generated power sensor 310, a load power sensor 320, and a system input / output power sensor 330. The storage battery subsystem 200 also includes a power conditioner 210 and a storage battery 220. Further, a load 2, a photovoltaic power generation device 3, and a power distribution system 4 are connected to the storage battery system 1.

The system controller 100 is a part that controls the entire storage battery system 1. The system controller 100 uses the power conditioner 210 based on the power values calculated by the power sensors of the generated power sensor 310, the load power sensor 320, and the system input / output power sensor 330 by converting the measured current values. Charging and discharging are controlled by controlling. For example, the power supplied from the photovoltaic power generation device 3 or the distribution system 4 to the load 2 is controlled. Along with this, control is performed regarding whether to sell the surplus power or charge the storage battery 220. For example, a calculation is performed using the power value measured by each power sensor, and the power conditioner 210 is controlled based on the calculation result to change the charging power. The functional blocks included in the system controller 100 will be described later with reference to FIG.
The storage battery subsystem 200 includes a power conditioner 210 and a storage battery 220.

Based on the control of the system controller 100, the power conditioner 210 converts the AC power supplied from the distribution system 4 into DC power that can be stored in the storage battery 220, and stores the converted AC power in the storage battery 220. Further, the DC power discharged from the storage battery 210 is converted into AC power that can be supplied to the load 2 and the distribution system 4, and is supplied to the load 2 and the distribution system 4.

The storage battery 220 is a battery that stores electricity, and is realized by, for example, a secondary battery such as a lithium ion rechargeable battery, a Ni-Cd battery, or a nickel-hydrogen (Ni-MH) battery.

The generated power sensor 310 is a power sensor that measures the amount of power generated by the photovoltaic power generation device 3. Further, the load power sensor 320 is a power sensor that measures the power value of the power consumed by the load 2.

The grid input / output power sensor 330 measures the power value of the power output to the distribution system 4 (that is, the power to be sold) and the power value of the power input from the distribution system 4 (that is, the power to be purchased). It is a sensor. The grid input / output power sensor 330 has a positive power value of the power output to the distribution system 4 (that is, power to be sold) and a negative power value of the power input from the distribution system 4 (that is, power to be purchased). It is installed in the direction of measurement.

The load 2 is an electric device of a consumer who uses the storage battery system 1, and operates by the electric power supplied by the storage battery system 1. For example, if the storage battery system 1 is used in a general household, the home electric appliance used by the consumer becomes the load 2.
The photovoltaic power generation device 3 is a device that converts sunlight into electric power using a solar cell and supplies the converted electric power to the storage battery system 1.

The distribution system 4 is a commercial distribution system installed by an electric power company. The storage battery system 1 receives power from the distribution system 4 (that is, buys power) and supplies power to the power distribution system 4 (that is, sells power). In this case, as a matter of course, if the power is purchased, a power purchase charge to be paid to the electric power company is incurred. In addition, if the electricity is sold, the electricity sales fee will be charged by the electric power company.
Next, each functional block included in the system controller 100 will be described with reference to FIG.

The system controller 100 has a power sensor measurement value acquisition unit 110, a control unit 120 that operates by program control, a compensation information storage unit 130 that stores information for performing processing for compensation of economic loss, and a date and time. Includes a calendar clock 140 to count.

The power sensor measurement value acquisition unit 110 is connected to each of the generated power sensor 310, the load power sensor 320, and the grid input / output power sensor 330, and acquires the power value measured by each of these power sensors from each power sensor. is there. The power sensor measurement value acquisition unit 110 outputs the acquired power value to the control unit 120. By inputting such an output, the control unit 120 can grasp the power value measured by each power sensor.

The control unit 120 is a part that controls the operation of each functional block in the system controller 100. Specifically, the control unit 120 is realized by an arithmetic processing unit such as a CPU (Central Processing Unit) and a storage device. Here, the storage device is, for example, a ROM (Read Only Memory) or HDD (Hard disk drive) that stores an OS (Operating System) and various control programs, and is temporarily required for the CPU to execute a program. It is realized by a RAM (Random Access Memory) or the like for storing the data.

Then, in the control unit 120, the CPU reads the OS and various control programs from the ROM, and while expanding the read OS and the control programs into the RAM, performs arithmetic processing based on these OSs and various control programs. Then, the control unit 120 controls the hardware in the system controller 100 based on the calculation result, so that the function of the system controller 100 is realized. That is, the system controller 100 can be realized by the cooperation of hardware and software.

Here, the control unit 120 is used for compensating for economic loss, which is a process peculiar to the present embodiment, in addition to a general process for operating the system controller 100, for example, a process for switching to the green mode for operation. Perform processing. Of these processes, the former is described in Patent Document 1 and the like and is well known to those skilled in the art, and thus detailed description thereof will be omitted. On the other hand, the latter will be described later with reference to the flowcharts of FIGS. 3 and 4.

The compensation information storage unit 130 is a unit that stores various types of information used by the control unit 120 to perform processing for compensation for economic loss, which will be described later. This information is referred to by the control unit 120 and is updated as appropriate. Each piece of information stored in the filling information storage unit 130 will be described.

The power purchase amount 131 during charging includes the power sale amount 132 during charging, the power sale target power amount 133 for the difference, and the power sale power amount 134 for the difference in the process of compensating for the economic loss described later. The value to be updated. These values are initialized to zero at the startup of the storage system 1 or at a predetermined stage during the process for compensating for the economic loss. Then, it remains zero until charging of surplus power is started. After that, the value is updated in the process of compensating for the economic loss described later. The update of these values will be described together with the processing for compensating for the economic loss described later.

The electricity rate table 135 is a table that records the electricity purchase charge per unit electric energy and the electricity sale electricity charge per unit electric energy. Further, the power sale implementation date 136 is the date for carrying out the power sale for the difference, which is a part of the processing for compensating for the economic loss. These two pieces of information are stored in the compensation information storage unit 130 in advance prior to the processing for compensation of the economic loss.

The calendar clock 140 is a clock that counts the current date and time. The calendar clock 140 outputs the counted current date and time to the control unit 100. The control unit 120 can grasp the current date and time by inputting such an output.

Next, the process for compensating for the economic loss will be described in detail with reference to the flowcharts of FIGS. 3 and 4 and the graph of FIG. Unless otherwise specified, the following processing shall be realized by the control of the control unit 120.

Here, the processes after step S12 are processes executed when surplus power is generated. Therefore, first, in order to determine whether or not surplus power is generated, it is determined whether or not the power value of the generated power exceeds the power value of the load power (step S11). Here, if the power value of the generated power exceeds the power value of the load power (Yes in step S11), it means that surplus power is generated, so the process proceeds to step S12. On the other hand, if the power value of the generated power is equal to or less than the power value of the load power (No in step S11), it means that no surplus power is generated, so this determination is repeated and the standby is performed (step S11).

Next, in step S12, the power sale implementation date 136 is compared with the input from the calendar clock 140, and it is determined whether or not the power sale implementation date is currently. If it is the power sale implementation date (Yes in step S12), the process proceeds to step S31 in FIG. On the other hand, if it is not the power sale implementation date (No in step S12), the process proceeds to step S13.

The process in which Yes is set in step S12 and the process proceeds to step S31 or later will be described later with reference to FIG. 4, and the case where No is set in step S12 will be described first.
Here, in order to make it easier to understand the present embodiment, the image diagram of FIG. 5 will be further referred to for explanation.

FIG. 5 is a graph showing the relationship between the power value of surplus power, which is the power value obtained by subtracting the power value measured by the load power sensor 320 from the power value measured by the generated power sensor 310, and the time. In this graph, the vertical axis is surplus power and the horizontal axis is time.

T0, t1, t2, t3, and t4 shown in FIG. 5 indicate the timing at which the system controller 100, which acquires and controls the power value in a predetermined cycle, actually acquires and controls the power value in the predetermined cycle. .. The distances of t0, t1, t2, t3 and t4 from t adjacent to themselves are all equal to Δt. Here, this graph is a graph assuming that the photovoltaic power generation increased during the daytime. In other words, t0 represents the time when the power generated by photovoltaic power generation increases with sunrise and is balanced with the load power, and then t1 represents the time when the surplus power increases as time passes. , T2, and then t3 represents the time when the surplus power decreases as time elapses, and then t4 represents the time when the surplus power remains constant even though time has passed. Is.
In this way, the case where the surplus power changes will be described as an example.

First, at the time of t0, since the surplus power P0 is exactly zero, it becomes No in step S11. After that, the determination in step S11 is performed at the timing of t1 after Δt has elapsed.

Then, since it is assumed that the power value of the generated power exceeds the power value of the load power (Yes in step S11) and the power sale implementation date has not been reached this time (No in step S12), step S13 is performed. move on. In step S13, the surplus power P1 which is the surplus power at the time of t1 is calculated by subtracting the load power value at the time of t1 from the power value of the generated power at the time of t1. As a result, the system controller 100 recognizes the surplus power P1 which is the surplus power at the time of t1 (step S13). At this time, the system input / output power sensor 330 indicates P1 as a positive value. This is because, of the surplus power P1, the power used for charging the storage battery 220 is zero, so that all of P1 is output (that is, sold) to the distribution system 4. ..

Then, the system controller 100 subtracts P0, which is the surplus power at the time of t0 in the past for a certain period of time (that is, Δt), from the P1 which is the surplus power at the time of t1 where the processing is performed this time. Therefore, ΔP1 which is the change in the system input / output power between t0 and t1 is calculated. Here, since the value of P0 is zero, it is calculated as "ΔP1 = P1-0".

Next, it is determined whether or not the calculated value of ΔP1 is equal to zero. Since ΔP1 is not zero this time (Yes in step S15), the process proceeds to step S16. Next, in step S16, it is determined whether or not the calculated value of ΔP1 is larger than zero.

Here, since the value of P1 is larger than zero, that is, the surplus power is larger than the surplus power at the time of the previous t (Yes in step S16), the process proceeds to step S17. In this case, since the storage battery 220 was charged based on the value of the surplus power at the time of t, the increased surplus power was sold without being used for charging. You can see that. In this example, since the surplus power is zero at t0, the storage battery 220 is not charged until t1. Nevertheless, since surplus power is actually generated, it can be seen that the generated surplus power would have been sold.

Therefore, the electric energy W1, which is the electric energy sold between t0 and t1, is obtained by "ΔP1 × Δt / 2". Then, it is considered that the electric energy W1 has been sold to the distribution system 4, and the electric energy W1 is added to the electric energy sold 132 during charging (step S17). In this example, since the power selling power amount 132 is zero before the processing of t1 is performed, the power selling power amount 132 becomes W1. The electric energy W1 is represented by the area of a triangle with a reference numeral W1 in FIG. That is, in the present embodiment, the value PN-1 of the surplus power at the previous processing time point tN-1 (N is a natural number) is constant over time Δt from the value PN-1 of the surplus power at the current processing time point tN. It is considered that the amount of change in is changed in proportion to time.

After that, the power conditioner 210 is controlled to charge the storage battery 220 for a certain period of time (that is, Δt) using the current surplus power as charging power (step S19). In this example, the current surplus power P1 is used as the charging power, and charging is performed until t2.

Next, at t2, the process from step S13 is performed again. In this respect, the surplus power increases from P1 to P2 between t1 and t2. This is the same state in which the surplus power increases from P0 to P1 between t0 and t1. Therefore, in the process from step S13 to be performed again, the electric energy W is calculated in the same manner as the content of the process performed in t1 described above, and the calculated W is added to the electric energy sold 132 during charging.

Specifically, it is calculated that the surplus power is P2 at t2 (step S13). Next, it is calculated that P2 is increased from P1 (Yes in step S14 and S15, Yes in step S16).

In this case, since the storage battery 220 was charged based on the value of the surplus power at the time of the previous t, the increased surplus power is not used for charging and is sold. You can see that it was done. In this example, since the surplus power is P1 at the time of t1, the storage battery 220 is charged with P1 until t2. Nevertheless, since the surplus power is actually increased to P2, it can be seen that the increased surplus power would have been sold.

More specifically, since charging is performed with the electric power P1 at this time, ΔP2 is calculated by setting ΔP2 = P2-P1. Since the surplus power is increasing, ΔP2 becomes a positive value. At this time, the system input / output power sensor 330 shows a positive value of P2-P1. Is shown as a positive value. This is because, of the surplus power P2, P1 is used for charging the storage battery 220, and the differential power P2-P1 is output (that is, sold) to the distribution system 4.

Then, it is considered that the electric energy W2 obtained by ΔP2 × Δt / 2 is sold to the distribution system 4, and the electric energy W1 is added to the electric energy sold 132 during charging (step S17). In this example, since the power selling power amount 132 is W1 before the processing of t2 is performed, the power selling power amount 132 is the sum of W1 and W2. The electric energy W2 is represented by the area of a triangle with a reference numeral W2 in FIG.

After that, the power conditioner 210 is controlled to charge the storage battery 220 for a certain period of time (that is, Δt) using the current surplus power as charging power (step S19). In this example, the current surplus power P2 is used as the charging power, and charging is performed until t3.

Next, at t3, the process from step S13 is performed again. At this point, the surplus power decreases from P2 to P3 between t2 and t3. Therefore, the process from step S13 performed this time is different from the content of the process performed in t1 and t2 described above, and the electric energy W is calculated and the calculated W is added to the electric energy purchased 131 during charging. ..

Specifically, it is calculated that the surplus power is P3 at t3 (step S13). Next, it is calculated that P3 is less than P2 (Yes in step S14 and S15, No in step S16).

In this case, since the storage battery 220 was charged based on the value of the surplus power at the time of the previous t, the charging power is insufficient for the decrease in the surplus power. Therefore, it can be seen that the shortfall was purchased to make up for this shortfall. In this example, since the surplus power is P2 at the time of t2, the storage battery 220 is charged with P2 until t3. Nevertheless, since the surplus power is actually reduced to P3, it can be seen that the reduced surplus power would have been purchased.

More specifically, since charging is performed with the electric power P2 at this time, ΔP3 is calculated by setting ΔP3 = P3-P2. Since the surplus power is decreasing, ΔP3 becomes a negative value. At this time, the system input / output power sensor 330 shows a negative value of P3-P2. This is because all of the surplus power P3 is used to charge the storage battery 220, and the differential power P3-P2 is input from the distribution system 4 (that is, power purchase) as a shortage for charging the storage battery 220. ).

Since ΔP3 is a negative value, the electric energy W3 obtained by | ΔP3 | × Δt / 2 using the absolute value of ΔP3 is regarded as having been purchased from the distribution system 4, and the electric energy purchased during charging. The electric energy W1 is added to 131 (step S17). In this example, since the electric energy purchased 131 is zero before the processing of t3 is performed, the electric energy purchased 131 is W3. The electric energy W3 is represented by the area of a triangle with a reference numeral W3 in FIG.

After that, the power conditioner 210 is controlled to charge the storage battery 220 for a certain period of time (that is, Δt) using the current surplus power as charging power (step S19). In this example, the current surplus power P3 is used as the charging power, and charging is performed until t4.

Next, at t4, the process from step S13 is performed again. In this respect, the surplus power is from P3 to P4 between t3 and t4, but the power values of P3 and P4 are the same. That is, the surplus power has not changed. Therefore, the processing from step S13 performed this time is different from the contents of the processing performed in t1 and t2 and the processing performed in t3 described above, and the electric energy W is zero. Therefore, the process of adding to the amount of power sold 132 during charging and the process of adding to the amount of power purchased 131 during charging are omitted.

Specifically, it is calculated that the surplus power is P4 at t4 (step S13). Next, when P3 is subtracted from P4, ΔP is zero, so that the system input / output power between t3 and t4 has not changed. Next, since the result is No in step S15, the process proceeds to step S19 without performing the processes of steps S17 and S18. This is because, as long as the grid input / output power between t3 and t4 has not changed, it can be considered that neither the selling power during charging nor the buying power during charging has occurred. Assuming that ΔP is completely zero, if there are almost no cases where it is determined as No in step S15, the reference is loosened, and when ΔP is almost zero, it is determined as No in step S15. You may try to do it. That is, when there is almost no difference between P4 and P3 and both surplus powers are substantially the same, it may be determined as No in step S15.

Even if the electric energy W4 is obtained by ΔP4 × Δt / 2, the electric energy W4 is zero and this value is not used, so it is not necessary to obtain the electric energy W4. The electric energy W4 cannot be represented as an area in FIG.

Then, in step S19, the power conditioner 210 is controlled to charge the storage battery 220 for a certain period of time (that is, Δt) using the current surplus power as charging power. In this example, the current surplus power P4 is used as the charging power, and charging is performed up to t5 (not shown after t5 in FIG. 5).

Then, after t5, the processes from step S13 to step S20 are repeated every time Δt elapses. As a result, if there is a difference between the surplus power and the charging power, the amount of power bought and sold is calculated and added to the amount of power purchased 131 during charging or the amount of power sold 132 during charging.

Then, in the process of repeating the above processing, if the surplus power becomes zero or less (Yes in step S20), charging is stopped (step S21), and the standby is performed until the surplus power is generated again (in step S11). No). Then, if the surplus power is generated again (Yes in step S11), the processing after step S12 is performed again. For example, if surplus power is generated during the daytime when sunlight is irradiated, the processes from step S13 to step S20 are repeated every time Δt elapses during the daytime, and charging is stopped during the nighttime. The standby is repeated (Yes in step S20, No in step S21 and step S11), and the processing after step S12 is performed again in the daytime of the next day, which is repeated every day until the power sale implementation date is reached.

By the process described above, the power value of the surplus power is acquired at regular time intervals until the power sale implementation date is reached, and the grid responds to the change between this surplus power and the surplus power acquired during the previous process. Changes in input / output power can be calculated. Then, it is possible to record the amount of power purchased during charging and the amount of power sold during charging according to the calculated change in the grid input / output power. Further, when neither the purchase nor the sale of power occurs during charging, only charging can be continued without performing such recording.

Next, the processing when the power sale implementation date is reached will be described. When the date and time of the calendar clock 140 becomes equal to the power sale execution date 136 in the process of repeating the above-mentioned processing (Yes in step S12). The transition to step S31 shown in FIG.

In step S31, with reference to the supplementary information storage unit 130, the accumulated power purchase amount and power sale amount are obtained from the charging power purchase amount 131, the charging power sale amount 132, and the electricity rate table 135, respectively. (S31). The charge for the electricity purchased during charging is obtained by integrating the value obtained by converting the amount of electricity purchased 131 during charging into the unit electricity amount and the electricity purchase charge per unit electricity amount included in the electricity rate table 135. Similarly, the charge for the electricity sold during charging is obtained by integrating the value obtained by converting the amount of electricity sold 132 during charging into the unit electric energy and the electricity selling charge per unit electric energy included in the electricity rate table 135. ..

Next, it is determined which of the power purchase charge during charging and the power sale charge during charging, which is calculated in this way, is higher (step S32). If the electricity selling charge during charging is higher (No in step S32), there is no need to make up for it. Therefore, the process proceeds to step S38 without performing steps S32 to S37, and the amount of electricity purchased during charging 131. It is initialized by setting both the amount of power sold during charging and the amount of power sold 132 during charging to zero. Then, the process proceeds to step S13 of FIG. 3 and the processes after step S13 are performed.
On the other hand, if the power purchase charge during charging is higher (No in step S32), it is necessary to make up for it, so the process proceeds to step S33.

In step S33, the target electric energy Ws for selling the difference is calculated. Specifically, the target electric energy Ws for selling electricity is obtained by (purchasing charge during charging-selling charge during charging) / electricity selling charge per unit electric energy. The obtained power sale target electric energy Ws is stored in the supplementary information storage unit 130 as the power sale target electric energy 133 for the difference. If the previously obtained power sale target electric energy Ws is stored, the power sale target electric energy Ws obtained this time is overwritten. Further, the power sales amount 134 for the difference is initialized by setting it to zero (step S34).

Then, the surplus power is sold to the distribution system 4 without charging the storage battery 220 with the surplus power (step S35). In this case, the amount of surplus electricity is equal to the amount of electricity sold to make up for the difference.

Then, when the sale of power for a certain period of time (that is, Δt) in step S35 is completed, the amount of power sold is added to the amount of power sold 134 for the difference stored in the supplementary information storage unit 130. (Step S36). Then, it is determined whether or not the power selling power amount 134 for the difference after the addition reaches the power selling target power amount Ws stored as the power selling target power amount 133 for the difference in the compensation information storage unit 130. (Step S37). If the target power amount Ws for selling power has not been reached, the process returns to step S35 and the power is sold again for a certain period of time (that is, Δt). In this way, if the power selling power amount 134 for the difference reaches the power selling target power amount Ws, the power selling continues, and if the power selling power amount 134 for the difference reaches the power selling target power amount Ws, Stop selling electricity and proceed to step S38. Then, both are initialized by setting both the power purchase power amount 131 during charging and the power sale power amount 132 during charging to zero. Then, the process proceeds to step S13 of FIG. 3 to start charging the storage battery 220 of the surplus power.
In the case where the storage battery 220 is charged even after the power is purchased even though the surplus power is generated by the process described with reference to FIG. 4, the power purchase generated during the charging is performed. It has the effect of making it possible to sell electricity in order to cover the charges. Then, if the compensation is completed, the storage battery 220 will be charged instead of selling more power, so it is important to prioritize the use of green power rather than the economic effect. It also has the effect of achieving the original purpose of the green mode of doing. In addition, these processes can be automatically executed without the intervention of the customer.

Further, although the above-described embodiment is a preferred embodiment of the present invention, the scope of the present invention is not limited to the above-described embodiment, and various modifications have been made without departing from the gist of the present invention. It can be implemented in the form.

For example, in the above-described embodiment, the photovoltaic power generation device 3 generates photovoltaic power generation, and the green power generated by the photovoltaic power generation is supplied to the storage battery system 1, but instead of the photovoltaic power generation or In addition to such photovoltaic power generation, green power generated by another power generation method may be supplied to the storage battery system 1. For example, a wind power generation device may be installed so that the green power generated by the wind power generation device is supplied to the storage battery system 1.

Further, in the case of photovoltaic power generation, since power generation is not normally performed at night, the result is Yes in step S20 at least once a day, and then the determination in step S12 is performed in the daytime of the next day. Therefore, it is possible that the transition to step S31 does not occur even though the power sale implementation date has come.

However, in the case of wind power generation, for example, since power can be generated even at night, surplus power is continuously generated even at night, and the processes of steps S13 to S20 continue for a plurality of days continuously. there is a possibility. In particular, when the consumer is absent on a trip or the like, the load power is reduced, so that the processes of steps S13 to S20 may continue for a plurality of days in a row. In such a case, it may not be Yes in step S20 for several days, and the determination in step S12 may not be carried out. Therefore, in the case of wind power generation or the like, if No in step S20, it is preferable to make a transition to step S12 instead of transitioning to step S13 and perform the determination of step S12 every time. As a result, it is possible to prevent the transition to step S31 even though the power sale implementation date has come.

Further, as another modification, the idea that power sale or purchase occurs due to the delay time in which the system follows the fluctuation of the surplus power value may be applied to steps S35 to S37. For example, it is conceivable to calculate the amount of power sold assuming that the surplus power P10 starts selling power at a certain time point t10 in step S35 and that the surplus power P10 always sells power during Δt in step S36. Be done. However, in reality, it is assumed that the surplus power decreases during Δt, and at the time of Δ11, there is only P11 in which the surplus power is less than P10. In this case, assuming that the surplus power does not change during Δt in step S36 and the surplus power P10 is always sold, an error occurs if the amount of sold power is calculated. Therefore, it is preferable to apply the above-mentioned idea to step S36, obtain ΔP11 by P11-P10, and regard the electric energy calculated by ΔP11 × Δt / 2 as the electric energy sold.

Each of the devices included in the above storage battery system can be realized by hardware, software, or a combination thereof. In addition, the compensation method performed by each device included in the above storage battery system can also be realized by hardware, software, or a combination thereof. Here, what is realized by software means that it is realized by a computer reading and executing a program.

Programs can be stored and supplied to a computer using various types of non-transitory computer readable media. Non-temporary computer-readable media include various types of tangible storage media. Examples of non-temporary computer-readable media include magnetic recording media (eg, flexible disks, magnetic tapes, hard disk drives), magneto-optical recording media (eg, magneto-optical disks), CD-ROMs (Read Only Memory), CD- It includes R, CD-R / W, and semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (random access memory)). The program may also be supplied to the computer by various types of transient computer readable media. Examples of temporary computer-readable media include electrical, optical, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire and an optical fiber, or a wireless communication path.

Some or all of the above embodiments may also be described, but not limited to:

(Appendix 1) For a system that supplies power supplied from the distribution system and the power generation device to the load, and stores surplus power that exceeds the power supplied to the load and is supplied from the power generation device. It is a power storage control device that controls
The electricity storage is performed for a predetermined time at the power value of the surplus power at the first time point, and based on the power value of the surplus power at the second time point when the predetermined time elapses from the first time point, the said It is determined whether or not the power has been purchased from the distribution system for the storage of electricity performed during the predetermined time, and if it is determined that the power has been purchased, the charge generated by the power purchase is compensated. Control means for selling power to the distribution system,
A storage control device characterized by being equipped with.

(Appendix 2) The control means is
By setting the second time point as the new first time point and setting the time point when the predetermined time has elapsed from the new first time point as the new second time point, the charge to be compensated is charged. The calculation is repeated, and based on the surplus power at each of the second time points in the repeating process, whether or not the surplus power not used for the storage performed during the predetermined time is sold to the distribution system. Also judge
The surplus power that was not used for the storage performed during the predetermined time was sold to the distribution system from the charge generated by purchasing the power from the distribution system for the storage performed during the predetermined time. The storage control device according to Appendix 1, wherein the charge generated as a result is deducted, and the deducted charge is subject to the compensation.

(Appendix 3) When the power value of the surplus power at the second time point is higher than the power value of the surplus power at the first time point, the control means stores the electricity stored during the predetermined time. The power storage control device according to Appendix 1 or 2, wherein it is determined that the power has been purchased from the power distribution system.

(Appendix 4) When the power value of the surplus power at the second time point is lower than the power value of the surplus power at the first time point, the control means stores the electricity stored during the predetermined time. Therefore, it is determined that the power has been sold from the distribution system.
When the power value of the surplus power at the first time point and the power value of the surplus power at the second time point are the same, the control means is the distribution system for storing electricity performed during the predetermined time. The power storage control device according to any one of Supplementary note 1 to 3, wherein it is determined that both the power purchase and the power sale from the power source are not performed.

(Appendix 5) The control means subtracts the power value of the surplus power at the first time point from the power value of the surplus power at the second time point, and the subtracted value or the absolute value of the subtracted value. The value obtained by dividing any of the values by 2 and multiplying the value by the predetermined time is the amount of power purchased from the distribution system for the storage performed during the predetermined time or the value during the predetermined time. The storage control device according to any one of Supplementary note 1 to 4, which is regarded as the amount of electric power sold to the distribution system.

(Appendix 6) When the surplus power is generated, the control means cancels the storage of the surplus power and sells the surplus power to the distribution system based on the charge generated. The power storage control device according to any one of Supplementary note 1 to 5, wherein the compensation is performed.

(Appendix 7) The control means is
By setting the second time point as the new first time point and setting the time point when the predetermined time has elapsed from the new first time point as the new second time point, the fee to be compensated is charged. Repeat the calculation,
The storage control device according to any one of Supplementary note 1 to 6, wherein when a predetermined date is reached, the compensation is performed for the total charge of the charges calculated by the repetition.

(Appendix 8) The control means refers to a charge table for calculating the charge generated by purchasing power and the charge generated by selling power, and the compensation is based on the charge calculated by using the information described in the charge table. The storage control device according to any one of Supplementary note 1 to 7, wherein the storage control device is characterized by performing the above.

(Appendix 9) A storage battery system including the power storage control device according to any one of Supplementary notes 1 to 8, the power generation device, and a storage battery.
The power generation device is a solar power generation device that generates solar power.
The power storage control device supplies the power obtained by the photovoltaic power generation to the load, and stores the surplus power, which is the power supplied in excess of the power supplied to the load, in the storage battery. Characterized storage battery system.

(Appendix 10) For a system that supplies electric power supplied from the distribution system and the power generation device to the load and stores surplus electric power that exceeds the electric power supplied to the load and is supplied from the power generation device. It is a power storage control program for operating a computer as a power storage control device for control.
The electricity storage is performed for a predetermined time at the power value of the surplus power at the first time point, and based on the power value of the surplus power at the second time point when the predetermined time elapses from the first time point, the said It is determined whether or not the power has been purchased from the distribution system for the storage of electricity performed during the predetermined time, and if it is determined that the power has been purchased, the charge generated by the power purchase is compensated. Control means for selling power to the distribution system,
A power storage control program characterized in that the computer functions as a power storage control device.

(Appendix 11) A storage battery that charges the power supplied from the distribution system and the power generated by the photovoltaic power generation device and supplies power to the load.
A mode in which the power generated by the photovoltaic power generation device can be supplied to the load and the surplus power generated by the photovoltaic power generation device is sold, or the surplus power generated by the photovoltaic power generation device. An electricity storage subsystem having a power conditioner capable of operating in a mode of charging the battery with electric power,
A power generation sensor that measures the amount of power generated by the photovoltaic power generation, and
A load power sensor that measures the power consumed by the load, and
A system input / output power sensor that measures the power supplied from the distribution system and the power output to the distribution system.
In a storage battery system having a system controller that collects power information obtained from each of the three power sensors at regular intervals and controls the power storage subsystem based on the collected power information, the solar power generation device Among the supplied electric power, it has a means for charging the storage battery with surplus electric power that cannot be consumed by the load.
When the system power input / output amount generated by the time difference that the system controller follows the fluctuation of the surplus power value is accumulated and the difference between the power purchase power charge and the power sale power charge becomes a loss, a part of the surplus power is equivalent to the difference. A charging control method for a storage battery system of solar power, which is characterized by reducing economic loss by allocating it to selling electricity.

1 Storage battery system 2 Load 3 Solar power generation device 4 Distribution system 100 System controller 110 Power sensor measurement value acquisition unit 120 Control unit 130 Compensation information storage unit 140 Calendar clock 200 Storage battery subsystem 210 Power conditioner 220 Storage battery 310 Power generation power sensor 320 Load power sensor 330 system input / output power sensor

Claims (9)

Supplies power supplied from the power distribution system and the power generation unit to the load, when said load exceeds the power supply is surplus power which is supplied from the power generating device, performs power storage of a predetermined amount , A power storage control device that controls a system that sells surplus power to the distribution system with respect to the predetermined amount of surplus power, or purchases power from the distribution system that is insufficient for the predetermined amount of surplus power. hand,
The charge reservoir Te power value of surplus power of the first time is performed for a predetermined time, the electric power value of the surplus power in the first time point, the second is the time at which also has passed the predetermined time than the first time point based on the difference between the power value of surplus power of the time, to calculate the power before Symbol purchased power and the power sale has been made,
In predetermined timing, the power purchase and the power sale calculates the power price for performed, the control hand stage performing pre Symbol power selling to compensate the price of power the electricity purchase was made
Charge reservoir controller Ru comprising a. The control means
By setting the second time point as a new first time point and setting the time point at which the predetermined time has elapsed from the new first time point point as the new second time point, the power purchase and the sale electrostatic repeatedly calculates the power made, in the repeating processes, based on the difference between the power value of surplus power of each of said first point in time, the power value of the surplus power of each of said second time point, calculating a power pre SL purchased power and the power sale has been made,
Calculated in the predetermined timing, the rates of the previous SL purchased electricity has been performed power, subtracts the price of power the power sale is made, it shall be the subject of Hama complement the price after the deduction
Power storage control apparatus according to請Motomeko 1. It said control means, than said power value of surplus power of the first time point, when the power value of the surplus power of the second time point is not low, you determined before Symbol purchased power is performed
Power storage control apparatus according to請Motomeko 1 or 2. It said control means, than said power value of surplus power of the first time point, when the power value of the surplus power of the second time point is not high, it is determined that the pre-Symbol power selling is performed,
Wherein when the power value of the surplus power of the first time the surplus power of the power value and the second time point is equal, have been made also both before Symbol purchased power and the power sale It determined that there is no
Power storage control apparatus according to any one of請Motomeko 1 to 3. Wherein, the second from the power value of surplus power surplus power of the first time point in time by subtracting the power value, one of the absolute value of the subtraction value or subtraction value 2 in the value obtained by dividing a value obtained by multiplying the predetermined time, the power purchase amount of power we row or to all the amount of power that the power selling is crack line
Power storage control apparatus according to any one of請Motomeko 1 to 4. Wherein, when surplus power is generated by charges incurred by it canceled to make a charge reservoir that by the said excess power to sell electricity to the excess power to the front SL distribution system, the intends line the compensation of charge of the power electricity purchase has been made
Power storage control apparatus according to any one of請Motomeko 1 to 5. Wherein, rates of power the electricity purchase was made, and electric power sales refers to the fee table for calculating the power price for performed was calculated by using the information described in該料gold table It intends rows compensation rates in the electric power the electricity purchase was made on the basis of the rates
Power storage control apparatus according to any one of請Motomeko 1 to 6. A storage battery system including the power storage control device according to any one of claims 1 to 7 , the power generation device, and a storage battery.
The power generation device is a solar power generation device that generates solar power.
Said power storage control apparatus, the electric power obtained by the solar power generation causes delivered to the load, when there is surplus power which is supplied by more than the power supplied to the load, the plant to the battery A storage battery system that stores a fixed amount of electricity. Supplies power supplied from the power distribution system and the power generation unit to the load, when said load exceeds the power supply is surplus power which is supplied from the power generating device, performs power storage of a predetermined amount A computer as a power storage control device that controls a system that sells surplus power to the distribution system with respect to the predetermined amount of surplus power, or purchases power from the distribution system that is insufficient for the predetermined amount of surplus power. It is a power storage control program to make
The charge reservoir Te power value of surplus power of the first time is performed for a predetermined time, the electric power value of the surplus power in the first time point, the second is the time at which also has passed the predetermined time than the first time point based on the difference between the power value of surplus power of the time, to calculate the power before Symbol purchased power and the power sale has been made,
In predetermined timing, the power purchase and the power sale calculates the power price for performed, the control hand stage performing pre Symbol power selling to compensate the price of power the electricity purchase was made
Charge reservoir control program Ru makes the computer function as the power storage control apparatus comprising a.

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