JP2014187799A - Power supply system, control apparatus, control method, and control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system, control apparatus, control method, and control program devised from the economical point view of power consumers.SOLUTION: The power supply system includes: a power generator; a storage battery that charges generation power generated by the power generator; a calculation section that calculates each of a first profit acquired by a generating source of the generation power when charging of the storage battery is off and a second profit acquired by the generating source when charging of the storage battery is on; and a control section that sets charging of the storage battery on or off, based on a comparison of the first profit and the second profit which have been calculated to each other.

Description

  The present invention relates to a power supply system, a control device, a control method, and a control program.

  In recent years, in order to cope with global warming, etc., the use of solar power generation using sunlight has been promoted to general power consumers. On the power consumer side, solar power generation using solar power generation has been promoted. Photovoltaic generators are installed as distributed power sources.

  According to the Electricity Business Law, when the standard voltage is 100V, it is determined that the specified voltage of 95V to 107V is maintained at the place where electricity is supplied. For this reason, the electric power consumer who owns a solar power generation device is operating for maintaining a specified voltage. For example, a power consumer may use a power conditioner (PCS: Power Conditioning Subsystem) that converts the generated power of a solar power generation device from direct current to alternating current and outputs it, thereby deviating from a specified voltage by the generated power. In this case, the output suppression function is operated to suppress the output of the generated power. Moreover, in order to suppress the amount of suppression of the output of generated electric power, the electric power consumer stores a part of the generated electric power in the storage battery, and takes out the electric power from the storage battery and consumes it as necessary.

JP-A-6-133472 JP 2004-63930 A JP 2004-88949 A

When a part of the generated power is stored in the storage battery, the stored power is used for consumption and cannot be sold. Moreover, at present, the price at which a power consumer sells power to a power company is set higher than the price at which the power consumer purchases power from the power company. For this reason, depending on the magnitude relationship between the amount of generated power and the amount of power consumed by the power consumer, the power consumer may suffer an economic loss.

  An object of one aspect of the present invention is to provide a power supply system, a control device, a control method, and a control program in consideration of economics on the power consumer side.

According to one aspect of the invention, a power generation device, a storage battery that charges the generated power generated by the power generation device, and a first benefit that a generation source of the generated power is obtained when charging of the storage battery is off, , Based on a comparison between the calculated first profit and the second profit, respectively, a calculation unit that calculates the second profit obtained by the generator when the storage battery is charged There is provided a power supply system including a control unit that sets charging of a storage battery to ON or OFF.

  According to one embodiment, it is possible to provide a power supply system, a control device, a control method, and a control program in consideration of economics on the power consumer side.

FIG. 1 is a diagram illustrating an example of a power supply system. FIG. 2 is a diagram illustrating an example of a hardware configuration of the control device. FIG. 3 is a flowchart illustrating an example of a control method by the control device. FIG. 4 is a diagram illustrating an example of the initial setting information. FIG. 5 is a diagram illustrating an example of the relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, on = 0. FIG. 6 is a flowchart showing an example of a method for determining on / off of charging of the storage battery in S111. FIG. 7 is a diagram illustrating an example of a calculation method of profit X when the storage battery is off and profit Y when the storage battery is on in S204. FIG. 8 is a diagram illustrating an example of a relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, off = Ps, on. FIG. 9 is a diagram illustrating an example of the relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, off ≠ Ps, on. FIG. 10 is a flowchart showing an example of a method for determining on / off of charging of the storage battery in S113. FIG. 11 is a diagram illustrating an example of a method for calculating profit X when charging of the storage battery is off and profit Y when it is on in S303. FIG. 12 is a modification of the flowchart showing the control method by the control device.

  Hereinafter, embodiments of the present invention will be specifically described with reference to FIGS. 1 to 11.

  FIG. 1 is a diagram illustrating an example of a power supply system. As illustrated in FIG. 1, the power supply system includes a power provider system 101 that is a power system owned by a power provider, and a home system 102 that is a power system owned by a power consumer.

  The electric power company system 101 includes a system power source 2, a power sale meter 3, and a power purchase meter 4, as shown in a one-dot chain line. On the other hand, the home system 102 includes a distribution board 5, a power conditioner 6, an outlet 7, an electric device 8, a solar power generation device 9, a control device 10, and a storage battery 20. Hereinafter, the power conditioner 6 is referred to as PCS6. In addition, although the continuous line in FIG. 1 has shown the electrical connection form, and the dotted line has shown the connection form by communication using a wire or radio | wireless, a connection form is not limited to a present Example. For example, the control device 10 may be incorporated into any of the PCS 6, the solar power generation device 9, or the storage battery 20.

The power company transmits power from the system power supply 2 using the distribution line 1 and supplies power to the distribution board 5 owned by the power consumer via the power sale meter 3 and the power purchase meter 4. The current used for power transmission is, for example, an alternating current having a frequency of 50 Hz or 60 Hz and a voltage of 100 V or 200 V. The distribution board 5 distributes the electric power supplied from the electric power company to the electrical equipment 8 in the house via the outlet 7. When a power consumer installs the solar power generation device 9 as a private power generation device, the solar power generation device 9 is electrically connected to the distribution board 5 via the PCS 6 as shown in FIG. Then, the electric power generated by the solar power generation device 9 is distributed to the electric device 8 via the distribution board 5.
On the other hand, the amount of power supplied from the system power supply 2 changes according to the amount of power generated by the solar power generation device 9 (power generation amount) and the amount of power consumed by the power consumer.
For example, assuming that the amount of generated power is Pg, the amount of power consumed by the electrical device 8 is Lc, and the amount of power (charged power amount) charged by the storage battery 20 is Pa, the amount of power P supplied from the power provider system 101 side is , P = (Lc + Pa) −Pg.
When the amount of power Lc + Pa consumed by the power consumer is less than the amount of generated power Pg, Pg> Lc + Pa, and the power consumed by the electric device 8 may be all covered by the power generated by the solar power generation device 9. it can. Then, the remainder obtained by subtracting the sum of Lc and Pa from Pg, that is, surplus power corresponding to Ps = Pg− (Lc + Pa) is output to the power utility grid 101 via the distribution board 5. At this time, the power sale meter 3 measures Ps as the amount of power, and the power consumer sells the power amount Ps to the power company. That is, at the time of power sale, electric power corresponding to the amount of electric power sold Ps is sent from the in-home system 102 toward the electric power company system 101.
And an electric power consumer does not receive the supply of the electric power from the electric power provider system | strain 101 at the time of power sale.

  On the other hand, the power supply system can also receive a shortage of the amount of power supplied from the solar power generation device 9 with respect to the amount of power consumed by the electrical device 8 from the grid power supply 2 of the power company. For example, when the amount of electric power Lc + Pa consumed by the electric power consumer is larger than the amount of electric power Pg generated by the solar power generation device 9, Pg <Lc + Pa, and the electric power consumed by the electric device 8 is the solar power generation device 9 Is not able to cover everything with the power generated. Therefore, the electric power consumer is supplied with the remainder obtained by subtracting Pg from Lc + Pa, that is, the shortage of Pb = (Lc + Pa) −Pg, from the power provider system 101 side. When the insufficient power amount Pb is supplied from the system power source 2 of the power provider system 101 to the electrical equipment 8 of the in-home system 102, the power purchase meter 4 provided in the power consumption measuring device measures Pb as the amount of power. Is done. The power consumer purchases this amount of power Pb from the power company.

  Hereinafter, details of each part of the power supply system will be described.

  The power sale meter 3 is a watt-hour meter for measuring and integrating the power sold by the power consumer to the power company. The power sale meter 3 is connected between the system power supply 2 and the power purchase meter 4, and as described above, the power consumed by the electric device 8 from the generated power amount Pg supplied from the solar power generation device 9. The amount of electric power sold Ps obtained by subtracting the amount Lc and the amount of charging power Pa charged by the storage battery 20 can be measured. The power sale meter 3 is used for electric power purchase and sale transactions between electric power companies and electric power consumers.

  The power purchase meter 4 is a watt-hour meter for measuring and integrating the amount of power supplied from the system power supply 2 to the electrical equipment 8, that is, the power purchased by the power consumer from the power company. The power purchase meter 4 is connected between the power sale meter 3 and the distribution board 5, and as described above, the amount of power obtained by subtracting the amount of generated power Pg from the amount of power Lc + Pa consumed by the power consumer. Can be measured. The power purchase meter 4 is used for the electric power trading transaction between the electric power company and the electric power consumer in the same manner as the electric power sale meter 3.

  The distribution board 5 is a power distributor for distributing and supplying power for each room, which is installed in the home of a power consumer. The distribution board 5 is electrically connected to the electrical device 8 by the distribution line 1d. The electric power supplied from the power company to the distribution board 5 is distributed to each electrical device 8 via the distribution line 1d.

  The PCS 6 is a device that converts generated electric power from direct current to alternating current so that the generated electric power can be used in an environment such as a home when a power consumer uses a solar power generation system. Further, the PCS 6 can suppress the output of the generated power by operating the output suppression function when there is a possibility of deviating from the specified voltage due to the generated power output from the solar power generation device 9. The output suppression method differs depending on the PCS model. For example, there are a model in which the output is completely cut off to zero, and a model in which the output amount is reduced to the extent that the output is not completely cut off. Hereinafter, suppression of the output of generated power is referred to as output suppression.

  The solar power generation device 9 is a solar cell in which a plurality of cells are juxtaposed in an aligned state in the vertical and horizontal directions and electrically connected to each other, and has, for example, a panel shape. The solar power generation device 9 outputs the DC power generated by the irradiation of sunlight to the PCS 6. Moreover, the solar power generation device 9 can also output to the storage battery 20 in order to store the generated power.

  The storage battery 20 is a battery for storing a part of the power generated by the solar power generation device 9. The generated power output from the solar power generation device 9 is guided to the storage battery 20 by a distribution line branched from the distribution line 1 connecting the PCS 6 and the solar power generation device 9. A power consumer can efficiently consume generated power by storing the generated power as charging power during the day and using the stored charging power at night. The installation of the storage battery 20 has an economic advantage because it can reduce the power purchased from the power company by using the charging power stored in the storage battery 20.

  The control device 10 can control on / off of charging of the storage battery 20. The control device 10 is connected to the power sale meter 3, the power purchase meter 4, the PCS 6, and the storage battery 20 so as to communicate with each other. Hereinafter, the hardware configuration of the control device 10 will be described.

  FIG. 2 is a diagram illustrating an example of a hardware configuration of the control device 10. As shown in FIG. 2, the control device 10 includes a CPU (Central Processing Unit) 81, a ROM (Read Only Memory) 82, a RAM (Random Access Memory) 83, a storage device 84, a network interface 85, and a portable storage medium. A drive 86 and the like are provided.

  Each component of the control device 10 is connected to the bus 87. The storage device 84 is, for example, an HDD (Hard Disk Drive). In the control device 10, a processor such as the CPU 81 executes a program stored in the ROM 82 or the storage device 84 or a program read by the portable storage medium drive 86 from the portable storage medium 88. Function is realized.

  Next, the function of each part constituting the control device 10 will be described with reference to FIG. 1 again.

  As illustrated in FIG. 1, the control device 10 includes a first storage unit 31, a second storage unit 32, an initial setting unit 33, a power information acquisition unit 34, a power generation information acquisition unit 35, and a power storage information acquisition unit. 36, a calculation unit 37, a determination unit 38, and a control execution unit 39.

  The first storage unit 31 corresponds to, for example, the ROM 82, the storage device 84, the portable storage medium drive 86 or the portable storage medium 88 shown in FIG. 2, and stores a control program for controlling on / off of charging of the storage battery 20. be able to.

  The second storage unit 32 corresponds to, for example, the ROM 82, the RAM 83, the storage device 84, the portable storage medium drive 86 or the portable storage medium 88 shown in FIG. 2, and is a database for storing various information used in the processing of the present invention. (DB; Data Base). For example, the second storage unit 32 can store various information acquired by the initial setting unit 33, the power information acquisition unit 34, the power generation information acquisition unit 35, and the power storage information acquisition unit 36. The second storage unit 32 can also store the result calculated by the calculation unit 37.

  In addition, the 1st memory | storage part 31 and the 2nd memory | storage part 32 may respectively have two or more in the control apparatus 10, and may be comprised by the same memory.

  The initial setting unit 33 sets initial setting information used for processing of the control device 10. The initial setting information includes, for example, power selling unit price information, power purchasing unit price information, standby time information, and control end time information. The initial setting unit 33 stores the set information in the second storage unit 32.

  The power information acquisition unit 34 receives information on the amount of sold power Ps that the power consumer sells to the power company from the power sale meter 3, and stores the received information in the second storage unit 32. In addition, the power information acquisition unit 34 receives information on the amount of purchased power Pb purchased by the power consumer from the power company from the power purchase meter 4 and stores the received information in the second storage unit 32. The power information acquisition unit 34 is realized by a processor such as the CPU 81 or MPU (Micro Processing Unit) in FIG.

  The power generation information acquisition unit 35 receives information indicating whether or not power generation control is performed in the PCS 6 from the PCS 6, and stores the received information in the second storage unit 32.

  The storage information acquisition unit 36 receives information on the amount of charging power Pa charged by the storage battery 20 from the storage battery 20 and stores the received information in the second storage unit 32.

  The calculation unit 37 obtains a profit that can be obtained by an electric power consumer by selling electric power to an electric power company for each of when the charging of the storage battery 20 is turned on and when the charging is turned off, and electric power by charging the storage battery 20 Calculate the profits that consumers can get.

  Based on the information on the amount of power acquired by the power information acquisition unit 34 and the above-described information on each profit calculated by the calculation unit 37, the determination unit 38 stores the information on the storage battery 20. It is determined whether charging is controlled to be on or off.

  The control execution unit 39 executes control for switching on / off charging of the storage battery 20 based on the determination result of the determination unit 38. The control execution unit 39 transmits an instruction signal for switching on / off of charging of the storage battery 20 to the storage battery 20 via the network 40. The storage battery 20 is provided with a control circuit that performs control for switching on / off of charging, and charging is turned on / off by driving the control circuit in accordance with an instruction signal.

  The initial setting unit 33, the power information acquisition unit 34, the power generation information acquisition unit 35, the power storage information acquisition unit 36, the calculation unit 37, the determination unit 38, and the control execution unit 39 are, for example, the CPU 81 or MPU (Micro Processing Unit) in FIG. And the like.

  Next, the control method of the storage battery 20 by the control apparatus 10 in the embodiment of the present invention will be described.

  FIG. 3 is a flowchart illustrating an example of a control method by the control device 10. In the flowchart, “Yes” indicates positive, and “No” indicates negative.

  First, the initial setting unit 33 sets initial setting information (S101). In S101, the initial setting unit 33 receives, from the input device such as a keyboard, mouse, or touch panel as initial setting information, information on the power selling unit price, information on the unit price of power purchase, and “predetermined time” (standby time) in S102. And information such as the time to end the processing in S105.

  FIG. 4 is a diagram illustrating an example of initial setting information stored in the second storage unit 32. When the power purchase unit price is different between daytime and nighttime, as shown in FIG. 4, the unit price can be set for each daytime and nighttime period. Further, the initial setting information can be updated as needed. When the initial setting information is stored in the second storage unit 32, the process of S101 is completed.

  Subsequently, the control execution unit 39 determines whether or not the current time is the timing for controlling the storage battery 20 based on the standby time information stored as the initial setting information in the second storage unit 32 (S102). . When it is determined that the current time is not the timing for controlling the storage battery 20 (No in S102), the control execution unit 39 executes the process of S102 again. On the other hand, when it determines with the present time being the timing which controls the storage battery 20 (S102 affirmation), the control execution part 39 turns off the charge of the storage battery 20 (S103).

  Subsequently, the determination unit 38 determines whether output suppression is occurring in the PCS 6 (S104). Specifically, the power generation information acquisition unit 35 transmits a signal requesting information indicating whether output suppression is occurring in the PCS 6. The PCS 6 that has received the signal transmits a response signal including information indicating whether output suppression is occurring in the PCS 6 to the power generation information acquisition unit 35. Subsequently, the power generation information acquisition unit 35 outputs the received response signal to the determination unit 38. If the information included in the received response signal does not indicate that output suppression is occurring in the PCS 6, the determination unit 38 determines negative in S104, and proceeds to S105.

  In S105, the determination unit 38 determines whether to end the process. Specifically, the determination unit 38 refers to the end time information stored in the second storage unit 32 and determines whether or not the current time is the end time. When it determines with complete | finishing a process (S105 affirmation), the control apparatus 10 complete | finishes a series of processes for controlling the storage battery 20. FIG. On the other hand, when it is not determined to end the process (No at S105), the process returns to S102, and the control device 10 executes the processes subsequent to S102 again.

  On the other hand, in S104, when the information included in the received response signal indicates that output suppression is occurring in PCS 6, it is determined as S104 affirmative, and the process proceeds to S106.

  In S <b> 106, the power information acquisition unit 34 acquires, from the power sale meter 3, information on the power sale power Ps, off that the power consumer sells to the power company. Specifically, the power information acquisition unit 34 transmits a signal requesting information on the power sale power Ps, off to the power sale meter 3. The power sale meter 3 that has received the signal measures the power sale power Ps, off, and transmits a response signal including information on the measurement result to the power information acquisition unit 34. The power information acquisition unit 34 stores the received power selling power Ps, off information in the second storage unit 32. Through the above processing, the power information acquisition unit 34 can acquire information on the power sale power Ps, off from the power sale meter 3.

  After the process of S106, the control execution unit 39 turns on the charging of the storage battery 20 (S107).

  Subsequently, the power information acquisition unit 34 acquires, from the power sale meter 3, information on the power sale power Ps, on that the power consumer sells to the power company (S108). As a method of acquiring the information on the power sale power Ps, on from the power sale meter 3, the same method as the process performed in S106 can be used.

  After the process of S108, the determination unit 38 determines whether or not Ps, on = 0 (S109). Hereinafter, an example of a case where Ps, on = 0 will be described.

  FIG. 5 is a diagram illustrating an example of the relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, on = 0. A one-dot chain line in FIG. 5 indicates the maximum amount of power generated by the solar power generation device 9. In addition, an arrow pointing downward in FIG. 5 indicates output suppression by the PCS 6.

  FIG. 5A shows a case where charging of the storage battery 20 is turned off. As shown in FIG. 5A, when output suppression by the PCS 6 is performed, the amount of generated power output from the PCS 6 becomes lower than the maximum amount of power generated by the solar power generation device 9 (the level of the one-dot chain line). . The example of Fig.5 (a) is an example in case an electric power consumer's power consumption amount is lower than an electric power generation amount, and an electric power consumer uses electric power Ps, off equivalent to a difference as electric power sales electric power company. Can sell electricity.

  On the other hand, FIG. 5B shows a case where charging of the storage battery 20 is turned on. When charging of the storage battery 20 is turned on, a power consumer can store a part of the generated power amount of the solar power generation device 9 in the storage battery 20. The example of FIG. 5B is an example in which the sum of the power consumption of the power consumer, that is, the power consumption of the electric device 8 and the power charged in the storage battery 20 exceeds the maximum amount of generated power. is there. In the case of FIG. 5, since the electric power corresponding to the difference between the two is insufficient, the electric power amount Pb, on corresponding to the shortage is purchased from the electric power company. Therefore, in the case of FIG. 5B, the amount of electric power sold is 0 (Ps, on = 0) although the storage battery 20 is charged, that is, the amount of electric power purchased is 0 or more. It means that.

  Returning to S109 in FIG. 3, if it is determined that Ps, on = 0 (Yes in S109), the process proceeds to S111.

  When it is determined in S109 that Ps, on = 0, whether the charging of the storage battery 20 is turned off or the charging of the storage battery 20 is turned on depends on the case. Different. Therefore, in S111, the control device 10 calculates the profits obtained when the storage battery charging is on and off, respectively, and turns on or off the charging of the storage battery 20 based on the comparison between the calculated profits. .

  FIG. 6 is a flowchart showing an example of a method for determining on / off of charging of the storage battery 20 in S111. In the flowchart, “Yes” indicates positive, and “No” indicates negative.

  First, the power information acquisition unit 34 acquires information on the purchased power Pb, on that the power consumer purchases from the power company from the power purchase meter 4 (S201). Specifically, the power information acquisition unit 34 transmits a signal requesting information on the purchased power amount Pb to the power purchase meter 4. The power purchase meter 4 that has received the signal measures the amount of purchased power Pb, on and transmits a response signal including information on the measurement result to the power information acquisition unit 34. The power information acquisition unit 34 stores the received information on the purchased power amount Pb, on in the second storage unit 32. Through the above processing, the power information acquisition unit 34 can acquire information on the purchased power amount Pb, on from the power purchase meter 4.

  Then, the electrical storage information acquisition part 36 acquires the information of charge electric energy Pa from the storage battery 20 (S202). Specifically, the power storage information acquisition unit 36 transmits a signal requesting the storage battery 20 for information on the charge power amount Pa. The storage battery 20 that has received the signal transmits a response signal including information on the charge energy Pa to the storage information acquisition unit 36. The power storage information acquisition unit 36 stores the received information on the charged power Pa in the second storage unit 32. Through the above processing, the power storage information acquisition unit 36 can acquire information on the charge power amount Pa from the storage battery 20. The storage information acquisition unit 36 may acquire actual numerical data of the charging power, or data on the amount of charge in a predetermined time period statistically calculated by the storage battery, such as an average value of the most recent predetermined time period, for example. You may get By acquiring the charge amount data in a predetermined time zone that is statistically calculated by the storage battery, it is possible to avoid suddenly changing the charge data, so that the accuracy of the calculation result of the calculation unit 37 is improved. Can be achieved.

  Subsequently, the calculation unit 37 reads out information on the power unit price and information on the charging power Pa from the second storage unit 32 (S203). The information on the power unit price is information set in S101 in FIG. 3, and the information on the charging power Pa is information acquired in S106 and S108 in FIG.

  Subsequently, the calculation unit 37 calculates the profit X when the storage battery 20 is off and the profit Y when it is on (S204). Profit X and profit Y are, for example, profits per unit time. Each of profit X and profit Y can be calculated by summing the profit per unit time due to the power sale power and the profit per unit time due to charging of the storage battery.

  Here, when the charging of the storage battery 20 is off, the sold power amount Ps, off is 20 [kW], when the storage battery 20 is charged, the purchased power amount Pb, on is 10 [kW], and the charging power of the storage battery 20 Assuming that the amount Pa is 50 [kW], an example of calculating profit X and profit Y will be described. Note that the information shown in FIG. 4 is used for the power unit price.

  FIG. 7 is a diagram illustrating an example of a calculation method of profit X when charging of the storage battery 20 is off and profit Y when it is on in S204.

  When charging of the storage battery 20 is off, the profit from the sold power is generated according to the above assumption. Therefore, the profit per unit time by buying and selling electric power is 20 [kWh] × 42 [yen / kWh] = 840 [using the information Ps, off of the electric power sales amount and the information of the electric power selling unit price in FIG. Yen] is calculated. In addition, since the storage battery 20 is not charged, the profit per unit time by charging the storage battery 20 is 0 [yen]. Therefore, the profit X is calculated as 840 [yen] +0 [yen] = 840 [yen] by calculating the total profit.

  On the other hand, when the charging of the storage battery 20 is on, according to the above-mentioned assumption, a loss due to power purchase has occurred for the power consumer. Therefore, the profit per unit time by buying and selling electric power is −10 [kWh] × 28.18 using the information Pb, on of the electric power purchase amount and the information of the electric power purchase unit price (daytime time zone) in FIG. [Yen / kWh] = − 281.8 [yen] is calculated. Here, a negative value means that a loss has occurred.

  Subsequently, the profit per unit time by charging the storage battery 20 is calculated. When the charging of the storage battery 20 is on, the storage battery 20 is charged. Since the electric power consumer can consume the stored electric power with the electric device 8, it is not necessary to purchase electric power corresponding to the electric power. That is, the power purchase price in the case where an amount of power equivalent to the amount of power obtained by charging is purchased from a power company can be regarded as a profit for the power consumer. For this reason, the profit per unit time due to the charging of the storage battery 20 is 50 [kWh] × 11. 5 using the information on the charging power amount of the storage battery 20 and the information on the power purchase unit price (night time zone) in FIG. It is calculated as 82 [yen / kWh] = 591 [yen]. Here, the information on the power purchase unit price (night time zone) is used because the power purchase unit price (night time zone) is cheaper than the power purchase unit price (day time zone). Therefore, the profit Y is calculated as 591 [yen] −281.8 [yen] = 309.2 [yen] by calculating the total profit.

  As described above, the calculation unit 37 can calculate the profit X and the profit Y, respectively.

  Subsequently, the determination unit 38 determines the profit X <profit Y in order to determine which is more profitable for the electric power consumer when the storage battery 20 is turned off and when the storage battery 20 is turned on. It is determined whether or not (S205). If it is not determined that the profit X <the profit Y, that is, if it is determined that the profit X ≧ the profit Y (No in S205), it is more profitable for the power consumer to turn off the storage battery 20 charging. And the control execution unit 39 turns off the charging of the storage battery 20 (S206). In the example of FIG. 7, since 840 [yen]> 309.2 [yen], it is determined that S205 is negative. When the process of S206 ends, the process of S111 ends. After the process of S111, the process returns to S102, and the control device 10 executes the processes after S102 again.

  On the other hand, when it is determined that profit X <profit Y (Yes in S205), it is determined that it is more profitable for the power consumer to turn on the charging of the storage battery 20, and the control execution unit 39 charges the storage battery 20. Is turned on (S207). When the process of S207 ends, the process of S111 ends. After the process of S111, the process returns to S102, and the control device 10 executes the processes after S102 again.

  Returning to S109 in FIG. 3, if it is not determined that Ps, on = 0 (No in S109), the process proceeds to S110.

  In S110, the determination unit 38 determines whether or not Ps, off = Ps, on. Hereinafter, an example of a case where Ps, off = Ps, on will be described.

  FIG. 8 is a diagram illustrating an example of a relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, off = Ps, on.

  FIG. 8A shows a case where charging of the storage battery 20 is turned off. In the example of FIG. 8A, the power consumption of the power consumer is smaller than the example of FIG. Therefore, since the possibility of deviating from the specified voltage due to the output of the generated power is further increased, the output suppression amount by the PCS 6 is larger than the example of FIG. However, since the amount of power consumed by the electric appliance 8 of the electric power consumer is still smaller than the amount of electric power generated by the solar power generation device 9, the electric power consumer sells the electric power Ps, off corresponding to the difference as electric power for sale. can do.

  On the other hand, the graph of FIG.8 (b) has shown the case where charge of the storage battery 20 is turned ON. When charging of the storage battery 20 is turned on, a part of the generated power amount of the solar power generation device 9 is stored in the storage battery 20. For this reason, the total amount of the power consumption Lc by the electric appliance 8 of the power consumer and the power Pa charged in the storage battery 20 is higher than when the storage battery 20 is turned off. Along with this, the output suppression amount by the PCS 6 is relaxed, and the power generation amount of the solar power generation device 9 increases. However, since the amount of power consumed by the electric appliance 8 of the power consumer is still smaller than the amount of power generated by the solar power generation device 9, the power consumer sells the power amount Ps, on corresponding to the difference. You can sell electricity.

  When the power sale power amount Ps, off when charging of the storage battery 20 is turned off and the power sale power amount Ps, on when charging of the storage battery 20 is turned on, Ps, off = Ps, on is To establish.

  Returning to S110 of FIG. 3, if it is determined that Ps, off = Ps, on (Yes in S110), the process proceeds to S112.

  If it is determined in S110 that Ps, off = Ps, on, the power sale power itself is the same regardless of whether the storage battery 20 is charged or not, but when the storage battery 20 is turned on, Charging is in progress. Since the electric power consumer can consume the stored electric power with the electric device 8, it is not necessary to purchase the electric power corresponding to the electric power. As a result, when the charging of the storage battery 20 is turned on, the profit is increased for the power consumer. Therefore, the control execution unit 39 turns on the charging of the storage battery 20 in S112. After the process of S112, the process returns to S102, and the control device 10 executes the processes after S102 again.

  On the other hand, when it is not determined that Ps, off = Ps, on (No in S110), the process proceeds to S113. Hereinafter, an example of a case where Ps, off = Ps, on is not satisfied will be described.

  FIG. 9 is a diagram illustrating an example of the relationship between the amount of photovoltaic power generation and the amount of power consumption when Ps, off ≠ Ps, on.

  FIG. 9A shows a case where charging of the storage battery 20 is turned off. In the example of FIG. 9A, similarly to the examples of FIGS. 5 and 8, the output suppression by the PCS 6 is performed, and the amount of generated power output from the PCS 6 is the maximum amount of generated power by the solar power generation device 9. Is lower than. However, since the amount of power consumed by the electric appliance 8 of the electric power consumer is smaller than the amount of electric power generated by the solar power generation device 9, the electric power consumer sells electric power Ps, off corresponding to the difference as electric power for sale. be able to.

  On the other hand, the graph of FIG.9 (b) has shown the case where charge of the storage battery 20 is turned ON. When charging of the storage battery 20 is turned on, as in the case of FIG. 8, the total amount of power consumed by the electric consumer 8 of the electric power consumer and the amount of power charged in the storage battery 20 turns off the charging of the storage battery 20. Rise than if you did. In the example of FIG. 9B, since the amount of power charged in the storage battery 20 is larger than that in the example of FIG. 8B, output suppression by the PCS 6 is stopped, and the generated power amount of the solar power generation device 9 is the maximum amount. It has risen to the level of. However, since the amount of power consumed by the electric appliance 8 of the power consumer is still smaller than the amount of power generated by the solar power generation device 9, the power consumer sells the power amount Ps, on corresponding to the difference. You can sell electricity.

  Ps, off ≠ Ps, on is established when the amount of power sold when the storage battery 20 is turned off is different from the amount of power sold when the storage battery 20 is turned on. In the example of FIG. 9B, since Ps, off> Ps, on, it is determined that Ps, off ≠ Ps, on.

  Returning again to FIG. If it is not determined in S110 that Ps, off = Ps, on, whether the charging of the storage battery 20 is turned off or the charging of the storage battery 20 is turned on, which is more profitable for the power consumer Depends on the case. Therefore, in S113, the control device 10 calculates the profits obtained when the storage battery charging is on and off, respectively, and turns on or off the charging of the storage battery 20 based on the comparison between the calculated profits. .

  FIG. 10 is a flowchart illustrating an example of a method for determining on / off of charging of the storage battery 20 in S113. In the flowchart, “Yes” indicates positive, and “No” indicates negative.

  First, the power storage information acquisition unit 36 acquires information on the charging power Pa from the storage battery 20 (S301). As a method for acquiring the information on the charging power Pa, a method substantially similar to the processing performed in S202 of FIG. 6 can be used.

  Subsequently, the calculation unit 37 reads out information on the power unit price and information on the charging power Pa from the second storage unit 32 (S302). The process performed in S302 is substantially the same as the process performed in S203.

  Subsequently, the calculation unit 37 calculates the profit X when the storage battery 20 is off and the profit Y when the battery 20 is on (S303).

  Here, the amount of electric power sold when the charging of the storage battery 20 is off is 20 [kW], the amount of electric power sold when the charging of the storage battery 20 is on is 17 [kW], and the amount of electric power sold by the storage battery 20 is 50 [kW]. An example of calculating profit X and profit Y will be described. Note that the information shown in FIG. 4 is used for the power unit price.

  FIG. 11 is a diagram illustrating an example of a method for calculating profit X when charging of the storage battery is off and profit Y when it is on in S303.

  When charging of the storage battery 20 is off, the profit from the sold power is generated according to the above assumption. Therefore, the profit per unit time by buying and selling electric power is calculated as 20 [kWh] × 42 [yen / kWh] = 840 [yen] using the information on the amount of electric power sold and the information on the unit price of electric power sale. In addition, since the storage battery 20 is not charged, the profit per unit time by charging the storage battery 20 is 0 [yen]. Therefore, the profit X is calculated as 840 [yen] +0 [yen] = 840 [yen] by calculating the total profit.

  On the other hand, when charging of the storage battery 20 is on, a profit from the power sale power is generated according to the above assumption. Therefore, the profit per unit time by buying and selling power is calculated as 17 [kWh] × 42 [yen / kWh] = 714 [yen] using the information on the amount of power sold and the information on the unit price of power sale.

  Subsequently, the profit per unit time by charging the storage battery 20 is calculated. When charging of the storage battery 20 is on, as already described, the stored electric power is consumed by the electric device 8, so that it is not necessary to purchase power corresponding to the electric power. For this reason, the profit per unit time due to the charging of the storage battery 20 is 50 [kWh] × 11.82 [yen] using information on the amount of electric power charged in the storage battery 20 and information on the unit price of power purchase (night time zone) / KWh] = 591 [yen]. Therefore, the profit Y is calculated as 714 [yen] +591 [yen] = 1305 [yen] by calculating the total profit.

  As described above, the calculation unit 37 can calculate the profit X and the profit Y, respectively.

  Subsequently, the determination unit 38 determines which of the profits is greater for the electric power consumer when the charging of the storage battery 20 is turned off and when the charging of the storage battery 20 is turned on. It is determined whether or not (S304). When it is determined that profit X> profit Y (Yes in S304), it is determined that it is more profitable for the power consumer to turn off the charging of the storage battery 20, and the control execution unit 39 turns off the charging of the storage battery 20 (S305). When the process of S305 ends, the process of S113 ends. After the process of S113, the process returns to S102, and the control device 10 executes the processes after S102 again.

  On the other hand, when it is determined that the profit X> the profit Y is not satisfied (No in S304), it is determined that it is more profitable for the power consumer to turn on the charging of the storage battery 20, and the control execution unit 39 charges the storage battery 20. Is turned on (S306). In the example of FIG. 10, since 840 [yen] <1,305 [yen], it is determined that S304 is negative. When the process of S306 ends, the process of S113 ends. After the process of S113, the process returns to S102, and the control device 10 executes the processes after S102 again.

As described above, the control by the control device 10 can be executed.
Thus, according to the embodiment of the present invention, the first advantage that the generation source of the generated power is obtained when the charging of the storage battery 20 is off, and the generation source is obtained when the charging of the storage battery 20 is on. Each of the second profits is calculated, and charging of the storage battery 20 is set on or off based on the comparison between the calculated first profit and second profit. According to this method, since the operation of the storage battery 20 can be controlled by a method that is more profitable for the electric power consumer, it is possible to construct an electric power supply system that takes into account the economics of the electric power consumer.
(Modification)
Hereinafter, modifications of the embodiment of the present invention will be described.
In the flowchart shown in FIG. 3, in S104, the determination unit 38 determines whether output suppression is occurring in the PCS 6, but the process in S104 may be omitted.

  FIG. 12 is a modified example of the flowchart showing the control method by the control device 10. In the modification shown in FIG. 12, the process of S104 in FIG. 3 is omitted, and the process of S106 is executed after the process of S103. In addition, the process for determining whether to end the process in S105 is executed after the process in S111, S112, or S113. According to the modification shown in FIG. 12, even in a situation where the output suppression by the PCS 6 does not occur, it becomes possible for the power consumer to use the generated power economically.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to specific embodiments, and various modifications and changes can be made. For example, in the example illustrated in FIG. 4, the standby time information used for the process of S102 is illustrated as an example of the initial setting information. However, for example, the time at which the process of S103 is started or after the process of S103 ends. The elapsed time information can be set instead of the standby time and used for the processing of S102.

Moreover, in the said embodiment, although the solar power generation device 9 was demonstrated to the example as a private power generation apparatus installed in an electric power consumer, the control apparatus 10 is not restricted to the solar power generation device 9, but manpower power generation, a fuel cell Alternatively, the control of the storage battery 20 can be executed even when other private power generation equipment such as a co-generator is installed.
Further, the control method described in the present embodiment can execute a control program prepared in advance on a computer such as a personal computer or a workstation. The control program is recorded on a computer-readable recording medium such as a nonvolatile memory such as a flash memory, and is executed by being read from the recording medium by the computer. As a recording medium for storing the control program, a hard disk, a flexible disk, a CD-ROM (Compact Disc-Read Only Memory), an MO (Magneto Optical disk), a DVD (Digital Versatile Disk), a DVD-ROM (DVD-Read). Only memory), DVD-RAM (DVD-Random Access Memory), BD (Blue-ray Disc), etc. can also be used. Further, the control program can be distributed via a network such as the Internet.

  The calculation of profit described in this embodiment can also be executed by simulation using the above-described computer.

1: Distribution line 2: System power supply 3: Electricity sales meter 4: Electricity purchase meter 5: Distribution board 6: Power conditioner (PCS)
7: Outlet 8: Electrical device 9: Solar power generation device 10: Control device 20: Storage battery 31: First storage unit 32: Second storage unit 33: Initial setting unit 34: Power information acquisition unit 35: Power generation information acquisition unit 36 : Power storage information acquisition unit 37: Calculation unit 38: Determination unit 39: Control execution unit 40: Network 81: CPU
82: ROM
83: RAM
84: Storage device 85: Network interface 86: Portable storage medium drive 87: Bus 88: Portable storage medium 101: Power company system 102: Home system

Claims (11)

A power generator,
A storage battery for charging generated power generated by the power generation device;
Calculation units that respectively calculate a first profit from which the generated power is generated when charging of the storage battery is off and a second profit from which the generation is obtained when charging of the storage battery is on. When,
A control unit that sets charging of the storage battery to ON or OFF based on the comparison between the calculated first profit and the second profit;
A power supply system comprising: A power generation information acquisition unit that acquires information on whether or not the output of the generated power is suppressed;
The said control part sets charging of the said storage battery to ON or OFF, when the said electric power generation information acquisition part acquires the information which shows that the output of the said generated electric power is suppressed. The power supply system described. A power information acquisition unit that acquires information on the amount of power of the difference between the generated power and the power consumption consumed by the generation source;
The power supply system according to claim 1, wherein the calculation unit calculates the first profit and the second profit based on the power amount of the difference. It further has a power storage information acquisition unit that acquires information on the amount of charged power indicating the amount of power charged in the storage battery,
The said calculation part calculates the said 1st profit and the said 2nd profit based on the information of the electric energy of the said difference, and the information of the said charging electric energy, The Claim 2 or 3 characterized by the above-mentioned. Power supply system. The power supply system according to any one of claims 2 to 4, wherein the first profit corresponds to a power selling price when the amount of power corresponding to the difference amount of power is sold. . The second benefit is that when the power consumed by the generator is smaller than the amount of generated power, the generator sells power when the generator sells an amount of power corresponding to the difference power. The power supply system according to any one of claims 2 to 5, wherein the power supply system corresponds to a power price. The second profit is a price when the amount of power consumed by the generation source is larger than the amount of power of the generated power when the amount of power corresponding to the amount of charged power is purchased. The power consumption price corresponds to a value obtained by subtracting a second power purchase price that is a price when the power amount corresponding to the difference power amount is purchased from the power purchase price. The power supply system according to Item 1.   The power supply system according to any one of claims 4 to 7, wherein the information on the amount of charging power is information on a charging amount in a predetermined time period statistically calculated by the storage battery. A control device for controlling a storage battery for charging generated power generated by a power generation device,
A calculation unit for calculating a profit obtained from the generation source of the generated power when charging of the storage battery is off and a profit obtained from the generation source when charging of the storage battery is on, respectively;
Based on the calculated comparison of profits, a control unit that sets charging of the storage battery to on or off;
Control device. A control method executed by a control device that controls a storage battery that charges generated power generated by a power generation device,
Calculating a first profit from which the generator of the generated power is obtained when charging of the storage battery is off and a second profit from which the generator is obtained when charging of the storage battery is on;
A control method, wherein charging of the storage battery is set to on or off based on a comparison between the calculated first profit and the second profit. To the control device that controls the storage battery that charges the power generated by the power generation device,
A process of calculating a first profit from which the generator of the generated power is obtained when charging of the storage battery is off and a second profit from which the generator is obtained when charging of the storage battery is on; ,
Based on the comparison between the calculated first profit and the second profit, a process of setting charging of the storage battery to on or off;
A control program to execute.

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