JP2023062375A - Power management device, program, power management method, and self-consignment system - Google Patents

Abstract

To provide a power management device, a program, a power management method, and a self-consignment system to minimize occurrence of imbalance by using both adjustment of the amount of power generation using a secondary battery and a load installation capable of converting electrical energy into thermal energy in self-consignment.SOLUTION: A power generation control unit may be capable of controlling a secondary battery such that a planned value and an actual value of the amount of power generated by a power generation installation match in one unit time. A demand control unit may be capable of controlling a specific load installation such that a planned value and an actual value of a demand amount of a load installation match in one unit time. The demand control unit may control the demand amount by the load installation over a plurality of unit times after one unit time when the secondary battery is controlled in one unit time. The power generation control unit may control the amount of power generated by the power generation installation over the plurality of unit times when the demand amount by the load installation is controlled over the plurality of unit times.SELECTED DRAWING: Figure 4

Description

The present invention relates to a power management device, a program, a power management method, and a self-consignment system.

Self-consumption by photovoltaic power generation is often used for corporate environmental activities. Self-consignment is attracting attention as the next means of self-consumption. Self-consignment is a power transmission service that utilizes a power system maintained, operated, and managed by an electric power company to transmit electricity generated by a business operator's power generation facility to a business operator's load facility at another location. Patent Literature 1 and Patent Literature 2 disclose techniques related to self-consignment.

In self-consignment, the rule of simultaneous equality of planned values must be observed. Simultaneous equality of planned values is a rule that predicts the planned value of power generation and the planned value of demand for electric power for each unit time, and matches the actual supply and demand with the planned value so that there is no deviation.

A business operator prepares a power management device for power generation, which manages the amount of power generated by the power generation equipment installed by the business operator, and a power management device for demand, which manages the demand amount of the load equipment of the business operator. It manages electric power in consignment. However, it is not easy to adjust the amount demanded by the load equipment of the business operator when managing it separately from the power generation amount. There is a limit.

Load equipment capable of converting electrical energy into thermal energy, such as a chiller or a heat pump, may be used to adjust the demand. However, loads such as chillers and heat pumps take longer than a unit time to convert energy greater than a given amount. Therefore, load facilities such as chillers and heat pumps are unsuitable as adjustment power for adjusting the demand while observing the rule of simultaneous equality of planned values in one unit of time.

On the other hand, a secondary battery may be used to adjust the power generation amount. By using a secondary battery, it is possible to adjust the power generation amount in one unit time. However, secondary batteries have a finite amount of discharge, and if a sufficient amount of discharge is to be secured for adjusting the amount of power generation, a large-capacity secondary battery is required, resulting in a high cost.

Therefore, the cost of the entire facility is reduced by adjusting the electrical energy between two or more facilities with different times from inputting electrical energy to the energy conversion device to drawing out the energy.

The adjustment takes advantage of the differences in the time to draw energy, which does not necessarily compare in the amount of energy stored in installations with energy converters. However, in order to increase the utilization efficiency of facilities, there is a general tendency that the shorter the time until energy is drawn out, the smaller the amount of energy that can be stored.

In order to adjust the electrical energy between facilities, for example, consider between a facility with a short time before drawing energy and a facility with a long time before drawing energy. Equipment that takes a short time to extract energy is, for example, a secondary battery that converts electrical energy into chemical energy and then converts it back into electrical energy for use. Equipment that takes a long time before drawing energy is, for example, a specific load equipment that converts electrical energy into thermal energy and uses it as it is as thermal energy. Assuming that both the secondary battery and the specific load equipment are equipment capable of inputting 100 kWh of electric energy, the electric energy is adjusted between the former and the latter. If the conversion loss is ignored, the former inputs and draws out 100 kWh of electrical energy within 1 hour, and the latter inputs 100 kWh of electrical energy in 1 hour and takes 12 hours to draw out as heat energy after 1 hour.

One of the purposes for which the latter draws out over 12 hours is to suppress energy costs as running costs. For example, instead of using thermal energy at high electrical energy costs during the daytime, thermal energy is stored in a short time at night at low electrical energy costs, and the stored thermal energy is used during the daytime.

If a business operator fails to follow the rule of simultaneous and equal planned values when carrying out self-consignment, it will receive a penalty according to the amount of imbalance, which is the difference between the actual supply and demand and the planned values. Reducing the amount of imbalance enables further suppression of running costs.

JP 2019-97627 A Japanese Patent Application Laid-Open No. 2021-87278

In self-consignment, it is desirable to provide a technique that minimizes the occurrence of imbalance by using a combination of power generation adjustment using a secondary battery and load equipment capable of converting electrical energy into thermal energy.

According to a first aspect of the invention, a power management device is provided. The power management device may use the power system of the power company to manage power in self-consignment, in which electricity generated by the power generation equipment of the business operator is transmitted to the load equipment of the business operator at another location. The power management device may include a power generation control unit that controls the amount of power generated by a power generation facility that includes a secondary battery. The power management device includes a demand control unit that controls the amount of demand by load equipment including specific load equipment that can convert electrical energy greater than a predetermined amount into thermal energy over a period of time longer than one unit time and extract the heat energy. good. The power generation control unit may be capable of controlling the secondary battery such that the planned value and the actual value of the amount of power generated by the power generation facility match in one unit time. The demand control unit may be capable of controlling the specific load facility such that the planned value and the actual value of the demand amount of the load facility match in one unit time. The demand control unit may control the demand amount by the load facility over a plurality of unit times after the one unit time when the secondary battery is controlled in one unit time. The power generation control unit may control the amount of power generated by the power generation equipment over a plurality of unit times when the demand amount by the load equipment is controlled over a plurality of unit times.

According to a second aspect of the invention, a program is provided. The program uses the power system of the electric power company to operate the computer as a power management device that manages power in self-consignment that transmits electricity generated by the power generation equipment of the business operator to the load equipment of the business operator at another location. you can make it work. The program may cause the computer to function as a power generation control section that controls power generation equipment including the secondary battery. The program may cause the computer to function as a demand control unit that controls load equipment including specific load equipment that can convert electrical energy greater than a predetermined amount into thermal energy over a period of time longer than one unit time. The power generation control unit may be capable of controlling the secondary battery such that the planned value and the actual value of the amount of power generated by the power generation facility match in one unit time. The demand control unit may be capable of controlling the specific load facility such that the planned value and the actual value of the demand amount of the load facility match in one unit time. The demand control unit may control the specific load facility over a plurality of unit times after the one unit time when the secondary battery is controlled in one unit time. The power generation control unit may control the amount of power generated by the power generation equipment over a plurality of unit times when the demand amount by the load equipment is controlled over a plurality of unit times.

According to a third aspect of the invention, a power management method is provided. The power management method may use the power company's power system to manage power in self-consignment in which electricity generated by the operator's power generation facility is transmitted to the operator's load facility at another location. A power management method may include controlling a power generation facility that includes a secondary battery. The power management method may include controlling a load facility, including a specific load facility, capable of converting and extracting electrical energy greater than a predetermined amount into thermal energy over a period of time longer than one unit time. The power management method may be capable of controlling the secondary battery such that the planned value and the actual value of the amount of power generated by the power generation facility match in one unit time. The power management method may be capable of controlling the specific load facility such that the planned value and the actual value of the demand amount by the load facility match in one unit time. The power management method may control the specific load facility over a plurality of unit times after one unit time when the secondary battery is controlled in one unit time. The power management method may control the amount of power generated by the power generation facility over a plurality of unit times when the demand amount by the load facility is controlled over a plurality of unit times.

According to a fourth aspect of the invention, a self-consignment system is provided. The self-consignment system may utilize the power company's power grid to transmit electricity generated by the operator's power generation facility to the operator's load facility at another location. The self-consignment system may comprise a power manager that manages power in the self-consignment. The power management device may include a power generation control unit that controls power generation equipment including a secondary battery. The power management apparatus may include a demand control unit that controls load facilities including specific load facilities that can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time. The power generation control unit may be capable of controlling the secondary battery such that the planned value and the actual value of the amount of power generated by the power generation facility match in one unit time. The demand control unit may be capable of controlling the specific load facility such that the planned value and the actual value of the demand amount of the load facility match in one unit time. The demand control unit may control the specific load facility over a plurality of unit times after the one unit time when the secondary battery is controlled in one unit time. The power generation control unit may control the amount of power generated by the power generation equipment over a plurality of unit times when the demand amount by the load equipment is controlled over a plurality of unit times.

It should be noted that the above summary of the invention does not list all the necessary features of the invention. Subcombinations of these feature groups can also be inventions.

An example self-consignment system 100 is shown schematically. An example of the functional configuration of the power management device 130 is shown schematically. An example of data stored in the data storage unit 137 is schematically shown. An example of the flow of processing by the power management device 130 is schematically shown. An example of information stored in the data storage unit 137 when the secondary battery 111B is discharged in one unit time is schematically shown. An example of information stored in the data storage unit 137 when the planned value is updated in response to discharging of the secondary battery 111B in one unit time is schematically shown. An example of information stored in the data storage unit 137 when the amount of power demanded by the chiller 121B is reduced is schematically shown. An example of information stored in the data storage unit 137 when the secondary battery 111B is charged in one unit time is schematically shown. An example of information stored in the data storage unit 137 when the planned value is updated corresponding to the charging of the secondary battery 111B in one unit time is schematically shown. An example of information stored in the data storage unit 137 when the amount of power demanded by the chiller 121B is increased is schematically shown.

Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. Also, not all combinations of features described in the embodiments are essential for the solution of the invention.

FIG. 1 schematically illustrates an example self-consignment system 100 . The self-consignment system 100 is a system that uses a power system 200 maintained, operated, and managed by an electric power company to transmit electricity generated by a business operator's power generation equipment to a business operator's load equipment at another location. The self-consignment system 100 includes various facilities provided at a business operator's power generation site 110 , various facilities provided at a business operator's demand site 120 , and a power management device 130 .

The power management device 130 can be realized by a computer hardware configuration or by a server configuration on a communication network using cloud computing technology.

A power generation site 110 of an operator is provided with a photovoltaic power generation facility 111A, a secondary battery 111B, a power conditioner 112 and a transformer 113 . The photovoltaic power generation equipment 111A and the secondary battery 111B are examples of the "company's power generation equipment" in the present invention. Also, the photovoltaic power generation facility 111A is an example of "another power generation facility different from the secondary battery" in the present invention.

111 A of photovoltaic power generation facilities are apparatuses comprised in order to convert solar energy into an electrical energy by a photovoltaic effect, and to supply the electric power suitable for load. The photovoltaic power generation facility 111A is electrically connected to the power conditioner 112 . Electric energy output from the photovoltaic power generation facility 111 is sent to the power conditioner 112 .

The secondary battery 111B is a battery that can be charged and used repeatedly. Secondary battery 111B is electrically connected to power conditioner 112 . Also, the secondary battery 111B is connected for communication with the power conditioner 112 . The secondary battery 111B operates in one of charge mode, discharge mode, and normal mode according to a control signal transmitted from the power conditioner 112 . The charge mode is an operation mode for charging the secondary battery 111B. Charging is to give electrical energy to the secondary battery 111B from the outside and store it in the form of chemical energy. The discharge mode is an operation mode for discharging the secondary battery 111B. Discharging is to flow a current from the secondary battery 111B to an external circuit. The normal mode is an operation mode in which the secondary battery 111B is neither charged nor discharged.

The power conditioner 112 is a device having a function of converting the output of the photovoltaic power generation facility 111A into predetermined power. The power conditioner 112 is composed of part or all of a master control and monitoring device, a DC conditioner, an inverter, a DC-DC interface, an AC-AC interface, an AC system interface, and the like. The power conditioner 112 is electrically connected to the solar power generation equipment 111A and the secondary battery 111B. The power conditioner 112 inputs the DC power output from the photovoltaic power generation facility 111A, converts it to AC power, and outputs the AC power to the transformer 113 when the secondary battery 111B does not operate due to the charging mode. In addition, when the secondary battery 111B operates in the charging mode, the power conditioner 112 receives the DC power output from the photovoltaic power generation facility 111 and outputs the DC power to the secondary battery 111B. Further, when the secondary battery 111B operates in the discharge mode, the power conditioner 112 receives the DC power discharged from the secondary battery 111B, converts it into AC power, and outputs the AC power to the transformer 113 .

Also, the power conditioner 112 is connected for communication with the secondary battery 111B. Also, the power conditioner 112 is communicatively connected to the power management device 130 via a WAN (Wide Area Network). A WAN is a communication network that connects geographically separated points. The power conditioner 112 transmits to the power management device 130 measurement data indicating the actual amount of power generation at the power generation site 110 . The actual value of the amount of power generation at the power generation site 110 includes the actual value of the amount of power generated by the photovoltaic power generation equipment 111A and the actual value of the amount of charge/discharge of the secondary battery 111B. The power conditioner 112 also receives control data for controlling the amount of power generation at the power generation site 110 from the power management device 130 . The power conditioner 112 also transmits a control signal for controlling the operation mode of the secondary battery 111B to the secondary battery 111B.

The transformer 113 is equipment that transforms AC power and interconnects it to the power system 200 . Transformer 113 is electrically connected to power conditioner 112 and power system 200 . Transformer 113 steps up the AC power output from power conditioner 112 and transmits the power to power system 200 .

A demand place 120 of the business is provided with a specific load facility 121A, a chiller 121B, a power conditioner 122 and a transformer 123. The specific load facility 121A and the chiller 121B are examples of the "business operator's load facility" in the present invention. Moreover, the chiller 121B is an example of the "specific load equipment" in this invention.

The transformer 123 is equipment that transforms AC power and interconnects it to the power system 200 . Transformer 123 is electrically connected to power conditioner 122 . Transformer 123 receives power transmitted through power system 200 and outputs the power to power conditioner 122 .

The power conditioner 122 is a device having a function of converting the output of the transformer 123 into predetermined power. The power conditioner 122 is composed of part or all of a master control and monitoring device, a DC conditioner, an inverter, a DC-DC interface, an AC-AC interface, an AC system interface, and the like. Power conditioner 122 is electrically connected to transformer 123, specific load equipment 121A and chiller 121B. The power conditioner 122 receives power output from the transformer 123 and outputs power to the specific load facility 121A and the chiller 121B.

Also, the power conditioner 122 is communicatively connected to the power management device 130 via the WAN. The power conditioner 122 transmits to the power management device 130 measurement data indicating the actual value of the amount of power demanded at the place of demand 120 . The actual amount of power demanded at the demand location 120 includes the actual amount of power demanded by the specific load facility 121A and the actual amount of power demanded by the chiller 121B. The power conditioner 122 also receives control data for controlling the amount of power demanded at the place of demand 120 from the power management device 130 .

121 A of specific load facilities are load facilities which consume an electrical energy, and are facilities required in order for an enterpriser to perform business activity. 121 A of specific load facilities are electrically connected with the power conditioner 122. FIG. 121 A of specific load facilities operate|move by the electric power output from the power conditioner 122. FIG.

The chiller 121B is a device that circulates water controlled to a constant temperature to cool or regulate the temperature of the heat source. Chiller 121 is electrically connected to power conditioner 122 . Chiller 121B operates with power output from power conditioner 122 . Chiller 121B is used to adjust the demand at demand location 120 . Here, a company that carries out self-consignment must observe the rule of simultaneous and equal planned values. Simultaneous equality of planned values is a rule that predicts the planned value of power generation and the planned value of demand for electric power for each unit time, and matches the actual supply and demand with the planned value so that there is no deviation. The chiller 121B can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time. In other words, the chiller 121B cannot convert more than a predetermined amount of electrical energy into thermal energy in one unit of time. Therefore, the chiller 121B can adjust the amount of power demand greater than the predetermined amount over a period of time longer than one unit time. In other words, the chiller 121B cannot adjust the power demand greater than the predetermined amount in one unit of time.

The power management device 130 is a device that manages power in self-consignment. The power management device 130 is communicatively connected to the power conditioners 112 and 122 via a WAN. The power management device 130 receives from the power conditioner 112 measurement data indicating the actual amount of power generation at the power generation site 110 . Also, the power management device 130 transmits control data for controlling the amount of power generation at the power generation site 110 to the power conditioner 112 . Also, the power management device 130 receives from the power conditioner 122 measurement data indicating the actual value of the demand for power at the place of demand 120 . The power management device 130 also transmits control data for controlling the amount of power demanded at the place of demand 120 to the power conditioner 122 .

FIG. 2 schematically shows an example of the functional configuration of the power management device 130. As shown in FIG. The power management device 130 includes a measurement data reception unit 131 , a power generation planning unit 132 , a demand planning unit 133 , a power generation control unit 134 , a demand control unit 135 , a control data transmission unit 136 and a data storage unit 137 .

The measurement data reception unit 131 is a software module that receives measurement data. The measurement data receiving unit 131 receives from the power conditioner 112 measurement data indicating the actual amount of power generation at the power generation site 110 . The measurement data receiving unit 131 also receives measurement data indicating the actual value of the amount of power demanded at the place of demand 120 from the power conditioner 122 .

The power generation planning unit 132 is a software module that calculates a planned value for the amount of power generated by the photovoltaic power generation facility 111A and the secondary battery 111B in one unit time, which is a unit for predicting the same planned value. The power generation planning unit 132 calculates the planned value of the amount of power generation for each of the plurality of unit times when the planned value of the demand for each of the plurality of unit times is calculated.

The demand planning unit 133 is a software module that calculates the planned value of the demand amount by the specific load facility 121A and the chiller 121B in one unit time, which is the unit of prediction of the planned value and the same amount simultaneously. When the secondary battery 111B is controlled in one unit time, the demand planning unit 133 calculates a planned demand amount in each of a plurality of unit times after the one unit time.

The power generation control unit 134 is a software module that controls the amount of power generated by the photovoltaic power generation equipment 111A and the secondary battery 111B. The power generation control unit 134 controls the secondary power generation control unit 134 so that the planned value and the actual value of the power generation amount of the solar power generation equipment 111A and the secondary battery 111B match in one unit time, which is a prediction unit of the planned value simultaneous same amount. Battery 111B can be controlled. The power generation control unit 134 controls the amount of power generated by the photovoltaic power generation equipment 111A and the secondary battery 111B over a plurality of unit times when the demand amount by the specific load equipment 121A and the chiller 121B is controlled over a plurality of unit times. to control. Further, the power generation control unit 134 performs control to discharge the secondary battery 111B when the actual value of the amount of power generated by the photovoltaic power generation facility 111A is smaller than the planned value in one unit time. Then, when the demand amount by the chiller 121B decreases over a plurality of unit times, the power generation control unit 134 performs control to charge the secondary battery 111B over the plurality of unit times. In addition, the power generation control unit 134 performs control to charge the secondary battery 111B when the actual value of the amount of power generated by the photovoltaic power generation facility 111A in one unit time is greater than the planned value. Then, when the demand amount by the chiller 121B increases over a plurality of unit times, the power generation control unit 134 controls to discharge the secondary battery 111B over the plurality of unit times. In addition, the power generation control unit 134 controls the secondary battery 111B so that the planned value of the amount of power generation calculated by the power generation planning unit 132 and the actual value of the amount of power generation match in one unit time.

The power generation control unit 134 performs feedback control when controlling the power generation amount of the power generation equipment over a plurality of unit times when the demand amount by the load equipment is controlled over a plurality of unit times. Therefore, the power generation control unit 134 prevents the power generation amount controlled in one unit time from exceeding the demand amount controlled in that one unit time so as not to diverge control.

The demand control unit 135 is a software module that controls the demand by the specific load equipment 121A and the chiller 121B. The demand control unit 135 can control the chiller 121B so that the planned value and the actual value of the demand amount by the specific load equipment 121A and the chiller 121B match in one unit time that is the unit of prediction of the simultaneous same amount of planned value. is. Then, when the secondary battery 111B is controlled in one unit time, the demand control unit 135 controls the demand amount by the specific load facility 121A and the chiller 121B over a plurality of unit times after the one unit time. to control. Further, when the secondary battery 111B is discharged in one unit time, the demand control unit 135 performs control to reduce the demand amount by the chiller 121B over a plurality of unit times after the one unit time. . Further, when the secondary battery 111B is charged in one unit time, the demand control unit 135 controls to increase the demand amount by the chiller 121B over a plurality of unit times after the one unit time. . In addition, the demand control unit 135 controls the chiller 121B so that the planned value of the demand amount calculated by the demand planning unit 133 and the actual value of the demand amount match each other in one unit time.

The control data transmission unit 136 is a software module that transmits control data. The control data transmission unit 136 transmits control data for controlling the amount of power generation at the power generation site 110 to the power conditioner 112 . Also, the control data transmission unit 136 transmits control data for controlling the amount of power demanded at the place of demand 120 to the power conditioner 122 .

The data storage unit 137 is a database that stores information for managing power in self-consignment. The data storage unit 137 stores data created and managed in a certain format so that the measurement data receiving unit 131, the power generation planning unit 132, the demand planning unit 133, the power generation control unit 134, and the demand control unit 135 can easily share and use the data. is a set of The data storage unit 137 is a collection of data created and managed in a fixed format so that it can be easily processed and reused depending on the application.

FIG. 3 schematically shows an example of data stored in the data storage unit 137. As shown in FIG. In the data storage unit 137, for example, data associated with information on the start time, end time, planned power generation amount (kWh), actual power generation amount (kWh), planned demand amount (kWh), and actual demand amount (kWh) is stored.

The start time information is information indicating the start time of one unit time, which is the prediction unit of the planned value simultaneous quantity. The end time information is information indicating the end time of one unit time starting at the start time indicated by the start time information. In the example shown in FIG. 3, for example, it indicates that the end time of one unit time starting at the start time "9:00" is "9:30".

The information of the planned power generation amount (kWh) is information indicating the planned value of the power generation amount in one unit time, which is the prediction unit of the simultaneous planned power generation amount. In the example shown in FIG. 3, for example, the planned power generation amount in one unit time from the start time "9:00" to the end time "9:30" is "100 (kWh)".

The information on the actual power generation amount (kWh) is information indicating the actual value of the power generation amount in one unit time, which is the prediction unit of the planned value simultaneous same amount. The information on the actual amount of power generation (kWh) includes information indicating the actual amount of power generated by the photovoltaic power generation facility 111A and information indicating the actual amount of charging/discharging of the secondary battery 111B. In the example shown in FIG. 3, for example, the actual amount of power generated by the photovoltaic power generation equipment 111A in one unit time from the start time “9:00” to the end time “9:30” is “100 (kWh)”. indicates that there is Further, in the example shown in FIG. 3, for example, the charge/discharge amount of the secondary battery 111B in one unit time from the start time “9:00” to the end time “9:30” is “0 (kWh)”. indicates that

The information on the planned demand amount (kWh) is information indicating the planned value of the demand amount in one unit time, which is the unit of prediction of the simultaneous and identical planned value. In the example shown in FIG. 3, for example, the planned demand amount in one unit time from the start time "9:00" to the end time "9:30" is "100 (kWh)".

The information on the actual demand amount (kWh) is information indicating the actual value of the demand amount in one unit time, which is the unit of prediction of the planned simultaneous same amount. Information on the actual demand amount (kWh) includes information indicating the actual value of the demand amount by the specific load equipment 121A and information indicating the actual value of the demand amount by the chiller 121B. In the example shown in FIG. 3, for example, the actual demand amount by the specific load facility 121A in one unit time from the start time "9:00" to the end time "9:30" is "50 (kWh)". indicates that Further, in the example shown in FIG. 3, for example, the actual demand amount by the chiller 121B in one unit time from the start time "9:00" to the end time "9:30" is "50 (kWh)". indicates that

FIG. 4 schematically shows an example of the flow of processing by the power management device 130. As shown in FIG. It is assumed that the start state in this example is a state in which self-consignment is started in one unit time from the start time "9:00" to the end time "9:30". Also, the start state in this example is assumed to be a state in which the planned power generation amount and planned demand amount for each unit time are set to "100 (kWh)".

Power generation control unit 134 of power management device 130 generates control data for controlling the amount of power generation in the unit time before the start time of the unit time, and sends the control data to control data transmission unit 136 . Upon receiving the control data for controlling the power generation amount, the control data transmission unit 136 of the power management device 130 transmits the control data to the power conditioner 112 . At the start time of the unit time, the power conditioner 112 controls the charge/discharge amount of the secondary battery 111B so that the actual value of the power generation amount and the planned value of the power generation amount indicated by the control data match.

For example, when the actual value of the amount of power generated by the photovoltaic power generation equipment 111A matches the planned value, the power conditioner 112 transmits a control signal for operating the secondary battery 111B in the normal mode to the secondary battery 111B. do.

For example, when the actual value of the amount of power generated by the photovoltaic power generation equipment 111A is smaller than the planned value, the power conditioner 112 transmits a control signal for operating the secondary battery 111B in the discharge mode to the secondary battery 111B. . At this time, the power conditioner 112 controls to discharge the secondary battery 111B so that the discharge amount of the secondary battery 111B and the difference between the actual value and the planned value of the amount of power generated by the photovoltaic power generation equipment 111A match. Send a signal.

For example, when the actual value of the amount of power generated by the photovoltaic power generation equipment 111A is larger than the planned value, the power conditioner 112 transmits a control signal for operating the secondary battery 111B in the charge mode to the secondary battery 111B. . At this time, the power conditioner 112 outputs electric power to the secondary battery 111B so that the amount of power output to the secondary battery 111B and the difference between the actual value and the planned value of the amount of power generated by the photovoltaic power generation equipment 111A match. to output When power conditioner 112 finishes outputting power to secondary battery 111B, power conditioner 112 transmits to secondary battery 111B a control signal for operating secondary battery 111B in the normal mode.

Then, at the end time of the unit time, the power conditioner 112 transmits to the power management device 130 measurement data indicating the actual value of the amount of power generated per unit time at the power generation location 110 .

Upon receiving the measurement data indicating the actual value of the power generation amount, the measurement data reception unit 131 of the power management device 130 stores the information indicated by the measurement data in the data storage unit 137 . When the secondary battery 111B is discharged in one unit time, the data storage unit 137 stores information as shown in FIG. When the secondary battery 111B is charged in one unit time, the data storage unit 137 stores information as shown in FIG.

FIG. 5 schematically shows an example of information stored in the data storage unit 137 when the secondary battery 111B is discharged in one unit time. In the example shown in FIG. 5, the actual amount of power generated by the photovoltaic power generation facility 111A in one unit time from the start time "9:00" to the end time "9:30" is "80 (kWh)". there is Further, in the example shown in FIG. 5, for example, the actual power generation amount of the secondary battery 111B in one unit time from the start time “9:00” to the end time “9:30” is “20 (kWh)”. It has become. The secondary battery 111B is used for both power generation and demand, and a positive number indicates power generation by discharging, and a negative number indicates that it is used for demand by charging.

FIG. 8 schematically shows an example of information stored in the data storage unit 137 when the secondary battery 111B is charged in one unit time. In the example shown in FIG. 8, the actual amount of power generated by the photovoltaic power generation facility 111A in one unit time from the start time "9:00" to the end time "9:30" is "120 (kWh)". there is Further, in the example shown in FIG. 8, for example, the power generation amount of the secondary battery 111B in one unit time from the start time "9:00" to the end time "9:30" is "-20 (kWh)". It has become. In other words, the power generation amount is a negative number, indicating that the secondary battery 111B has been charged.

On the other hand, the demand control unit 135 of the power management apparatus 130 generates control data for controlling the demand amount in the unit time before the start time of the unit time, and transmits the control data to the control data transmission unit 136. send. Upon receiving the control data for controlling the demand, the control data transmission unit 136 of the power management device 130 transmits the control data to the power conditioner 122 . At the start time of the unit time, the power conditioner 122 controls the demand amount by the chiller 121B so that the actual demand amount and the planned demand amount indicated by the control data match.

For example, when the planned demand amount indicated by the control data and the planned demand amount in the start state match, the power conditioner 122 does not change the amount of electric power output to the chiller 121B in the target unit time.

For example, when the planned demand amount indicated by the control data is smaller than the planned demand amount in the starting state, the power conditioner 122 reduces the amount of electric power output to the chiller 121B in the target unit time. At this time, the power conditioner 122 reduces the amount of power output to the chiller 121B by the amount of power that matches the difference between the planned demand amount indicated by the control data and the planned demand amount in the start state.

For example, when the planned demand amount indicated by the control data is larger than the planned demand amount in the starting state, the power conditioner 122 increases the amount of electric power output to the chiller 121B in the target unit time. At this time, the power conditioner 122 increases the amount of power output to the chiller 121B by the amount of power that matches the difference between the planned demand indicated by the control data and the planned demand in the start state.

Then, at the end time of the unit time, the power conditioner 122 transmits to the power management device 130 measurement data indicating the actual value of the amount demanded per unit time at the demand location 120 .

The measurement data receiving unit 131 stores the information indicated by the measurement data in the data storage unit 137 when receiving the measurement data indicating the actual value of the demand amount. When the amount demanded by the chiller 121B does not change, information as shown in FIGS. 5 and 8 is stored in the data storage unit 137. FIG. In the example shown in FIGS. 5 and 8, the actual demand amount by the specific load facility 121A in one unit time from the start time "9:00" to the end time "9:30" is "50 (kWh)". It's becoming Further, in the examples shown in FIGS. 5 and 8, the actual demand amount by the chiller 121B in one unit time from the start time “9:00” to the end time “9:30” is “50 (kWh)”. It's becoming

The measurement data receiving unit 131 stores the information indicated by the measurement data in the data storage unit 137 when receiving the measurement data indicating the actual value of the demand amount.

When the data storage unit 137 stores the information on the actual value of the power generation amount, the demand planning unit 133 of the power management device 130 determines whether the secondary battery 111B has been charged/discharged (step S101). For example, the demand planning unit 133 determines that the secondary battery 111B has been charged/discharged when the actual value of the charge/discharge amount of the secondary battery 111B included in the measurement data is not zero.

If the secondary battery 111B is being charged/discharged (step S101; YES), the demand planning unit 133 determines whether the secondary battery 111B has been discharged (step S102). For example, the demand planning unit 133 determines that the secondary battery 111B has been discharged when the actual value of the charge/discharge amount of the secondary battery 111B included in the measurement data is greater than zero.

When the secondary battery 111B is being discharged (step S102; YES), the demand planning unit 133 calculates the number of frames per unit time required to reduce the demand amount by the chiller 121B (step S103). Here, when the secondary battery 111B is discharged in one unit time, the remaining capacity of the secondary battery 111B is reduced by the amount corresponding to the amount of discharge. When the remaining capacity of the secondary battery 111B is reduced, there is a possibility that the required power cannot be discharged when the actual value of the amount of power generated by the photovoltaic power generation equipment 111A is smaller than the planned value. Therefore, the power generation planning unit 132 of the power management device 130 changes the planned value of the power generation amount by the charge amount so as to charge the secondary battery 111B after the unit time of discharging. . On the other hand, the demand planning unit 133 makes a change to decrease the planned value of demand. As described above, the specific load facility 121A is a facility necessary for business operators to conduct business activities. Therefore, the demand amount by the specific load equipment 121A cannot be reduced unnecessarily just because the planned value of the demand amount is reduced. Therefore, the demand amount at the demand place 120 is adjusted according to the decrease in the planned value of the demand amount by reducing the power supply to the chiller 121B. As described above, the chiller 121B can adjust a power demand greater than a predetermined amount over a period of time longer than one unit time. Therefore, the demand planning unit 133 calculates the number of frames per unit time required to reduce the amount of demand by the chiller 121B corresponding to the amount of charge of the secondary battery 111B. In this example, the demand planning unit 133 calculates the number of frames per unit time required to reduce the demand amount of the chiller 121B by 20 (kWh) corresponding to the charge amount of 20 (kWh). Here, it is assumed that the chiller 121B can adjust the power demand of 8 (kWh) over 1 (hour). In that case, the demand planning unit 133 calculates 20/8=5 frames for the number of frames per unit time required to reduce the demand amount by the chiller 121B by 20 (kWh).

Next, the demand planning unit 133 calculates a plan value for reducing the amount of demand for power in the unit time of the required number of frames calculated in step S103 (step S104). For example, the demand planning unit 133 averages the amount of demand to be reduced in each unit time for the required number of frames counted from the unit time two frames after the unit time in which the secondary battery 111B was discharged. Calculate the planned value to reduce to In this case, the demand planning unit 133 targets the unit time of 5 frames counting from the unit time from the start time "10:00" to the end time "10:30". Then, the demand planning unit 133 calculates 20/5=4 (kWh) for the amount of demand to be reduced in each unit time of the five frames. Then, the demand planning unit 133 calculates the planned demand for each unit time of the five frames as 100-4=96 (kWh).

Then, the demand planning unit 133 updates the data stored in the data storage unit 137 with the planned demand amount calculated in step S104 (step S105). When the planned value of demand is updated in response to discharging of the secondary battery 111B in one unit time, the data storage unit 137 stores information as shown in FIG.

FIG. 6 schematically shows an example of information stored in the data storage unit 137 when the planned value is updated in response to discharging the secondary battery 111B in one unit time. In the example shown in FIG. 6, the planned demand amount is 96 (kWh) in the unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30".

When the planned value of the demand amount is updated, the power generation planning unit 132 of the power management device 130 calculates the planned value of the power generation amount corresponding to the demand amount at each unit time when the demand amount decreases (step S106). For example, the power generation planning unit 132 sets the planned power generation amount in each unit time when the demand amount decreases to the same value as the planned demand amount in each unit time updated in step S105. In this example, the power generation planning unit 132 sets the planned power generation amount for each unit time of 5 frames counting from the unit time from the start time "10:00" to the end time "10:30" to 96 (kWh). .

Then, the power generation planning unit 132 updates the data stored in the data storage unit 137 with the planned power generation amount calculated in step S106 (step S107), and ends the processing shown in FIG. When the planned power generation amount is updated in response to the decrease in the planned demand amount, information as shown in FIG. 6 is stored in the data storage unit 137 .

When the planned power generation amount is updated, the power generation control unit 134 generates control data indicating the updated planned power generation amount before the updated start time of the unit time, and transmits the control data to the control data transmission unit. Send to 136. Upon receiving the control data indicating the updated planned power generation amount, the control data transmission unit 136 transmits the control data to the power conditioner 112 . At the start time of the unit time when the planned power generation amount is updated, the power conditioner 112 charges the secondary battery 111B so that the actual power generation amount coincides with the planned power generation amount indicated by the control data. control the amount.

Then, at the end time of the unit time, the power conditioner 112 transmits to the power management device 130 measurement data indicating the actual value of the amount of power generated per unit time at the power generation location 110 .

When the measurement data receiving unit 131 receives the measurement data indicating the actual value of the power generation amount, the measurement data receiving unit 131 stores information indicated by the measurement data in the data storage unit 137 . When the secondary battery 111B is charged over a plurality of unit times, the data storage unit 137 stores information as shown in FIG.

FIG. 7 schematically shows an example of information stored in the data storage unit 137 when the secondary battery 111B is charged over a plurality of unit times. In the example shown in FIG. 7, the actual value of the charge amount of the secondary battery 111B in each unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30" is "4". (kWh)”.

On the other hand, the demand control unit 135 generates control data indicating the updated planned demand amount before the updated start time of the unit time, and sends the control data to the control data transmission unit 136 . Upon receiving the control data indicating the updated planned demand amount, the control data transmission unit 136 transmits the control data to the power conditioner 122 . At the start time of the unit time when the planned demand amount is updated, the power conditioner 122 reduces the demand amount by the chiller 121B so that the actual value of the demand amount and the planned value of the demand amount indicated by the control data match. Control. In this example, the power conditioner 122 reduces the amount of power output to the chiller 121B in order to reduce the amount demanded by the chiller 121B.

Then, at the end time of the unit time, the power conditioner 122 transmits to the power management device 130 measurement data indicating the actual value of the amount demanded per unit time at the demand location 120 .

The measurement data receiving unit 131 stores the information indicated by the measurement data in the data storage unit 137 when receiving the measurement data indicating the actual value of the demand amount. When the demand amount by the chiller 121B is reduced over a plurality of unit times, the data storage unit 137 stores information as shown in FIG. In the example shown in FIG. 7, the actual demand amount by the chiller 121B in each unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30" is "46 (kWh)". It has become.

When the secondary battery 111B is being charged in step S102 (step S102; NO), the demand planning unit 133 calculates the number of frames per unit time required to increase the demand amount by the chiller 121B (step S108). Here, when the secondary battery 111B is charged in one unit time, the remaining capacity of the secondary battery 111B increases by the amount corresponding to the amount of charge. When the remaining capacity of the secondary battery 111B is increased, there is a possibility that the required power cannot be charged when the actual value of the amount of power generated by the photovoltaic power generation facility 111A is larger than the planned value. Therefore, the power generation planning unit 132 of the power management device 130 changes the planned power generation amount by the discharge amount so that the secondary battery 111B can be discharged after the charging unit time. Become. On the other hand, the demand planning unit 133 makes a change to increase the planned value of the demand amount. As described above, the specific load equipment 121A is equipment necessary for business operators to conduct business activities. Therefore, the demand amount by the specific load equipment 121A cannot be increased unnecessarily just because the planned value of the demand amount is increased. Therefore, the demand amount at the demand place 120 is adjusted according to the increase in the planned value of the demand amount by increasing the power supply to the chiller 121B. As described above, the chiller 121B can adjust a power demand greater than a predetermined amount over a period of time longer than one unit time. Therefore, the demand planning unit 133 calculates the number of frames per unit time required to increase the amount of demand by the chiller 121B corresponding to the amount of discharge of the secondary battery 111B. In this example, the demand planning unit 133 calculates the number of frames per unit time required to increase the demand amount of the chiller 121B by 20 (kWh) corresponding to the discharge amount of 20 (kWh). Here, it is assumed that the chiller 121B can adjust the power demand of 8 (kWh) over 1 (hour). In that case, the demand planning unit 133 calculates 20/8=5 frames for the number of frames per unit time required to increase the demand amount by the chiller 121B by 20 (kWh).

Next, the demand planning unit 133 calculates a planned value for increasing the power demand amount in the unit time of the required number of frames calculated in step S108 (step S109). For example, the demand planning unit 133 averages the amount of demand to be increased in each unit time by the required number of frames counted from the unit time two frames after the unit time in which the secondary battery 111B was charged. Calculate the planned value to increase to In this case, the demand planning unit 133 targets the unit time of 5 frames counting from the unit time from the start time "10:00" to the end time "10:30". Then, the demand planning unit 133 calculates 20/5=4 (kWh) for the amount of demand to be increased in each unit time of the five frames. Then, the demand planning unit 133 calculates the planned demand for each unit time of the five frames as 100+4=104 (kWh).

Then, the demand planning unit 133 updates the data stored in the data storage unit 137 with the planned demand amount calculated in step S109 (step S110). When the planned value of demand is updated in response to charging of the secondary battery 111B in one unit time, the data storage unit 137 stores information as shown in FIG.

FIG. 9 schematically shows an example of information stored in the data storage unit 137 when the planned value is updated in response to charging the secondary battery 111B in one unit time. In the example shown in FIG. 9, the planned demand amount is 104 (kWh) in the unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30".

When the planned demand amount is updated, the power generation planning unit 132 of the power management device 130 calculates a planned value for the amount of power generation corresponding to the demand amount at each unit time when the demand amount increases (step S111). For example, the power generation planning unit 132 sets the planned power generation amount in each unit time when the demand amount increases to the same value as the planned demand amount in each unit time updated in step S110. In this example, the power generation planning unit 132 sets the planned power generation amount at each unit time of 5 frames counting from the unit time from the start time "10:00" to the end time "10:30" to be 104 (kWh). .

Then, the power generation planning unit 132 updates the data stored in the data storage unit 137 with the planned power generation amount calculated in step S111 (step S112), and ends the processing shown in FIG. When the planned power generation amount is updated in response to an increase in the planned demand amount, the data storage unit 137 stores information as shown in FIG.

When the planned power generation amount is updated, the power generation control unit 134 generates control data indicating the updated planned power generation amount before the updated start time of the unit time, and transmits the control data to the control data transmission unit. Send to 136. Upon receiving the control data indicating the updated planned power generation amount, the control data transmission unit 136 transmits the control data to the power conditioner 112 . At the start time of the unit time when the planned power generation amount is updated, the power conditioner 112 discharges the secondary battery 111B so that the actual power generation amount coincides with the planned power generation amount indicated by the control data. control the amount.

Then, at the end time of the unit time, the power conditioner 112 transmits to the power management device 130 measurement data indicating the actual value of the amount of power generated per unit time at the power generation location 110 .

When the measurement data receiving unit 131 receives the measurement data indicating the actual value of the power generation amount, the measurement data receiving unit 131 stores information indicated by the measurement data in the data storage unit 137 . When the secondary battery 111B is discharged over a plurality of unit times, the data storage unit 137 stores information as shown in FIG.

FIG. 10 schematically shows an example of information stored in the data storage unit 137 when the secondary battery 111B is discharged over a plurality of unit times. In the example shown in FIG. 10, the actual value of the discharge amount of the secondary battery 111B in each unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30" is "4". (kWh)”.

On the other hand, the demand control unit 135 generates control data indicating the updated planned demand amount before the updated start time of the unit time, and sends the control data to the control data transmission unit 136 . Upon receiving the control data indicating the updated planned demand amount, the control data transmission unit 136 transmits the control data to the power conditioner 122 . At the start time of the unit time when the planned demand amount is updated, the power conditioner 122 reduces the demand amount by the chiller 121B so that the actual value of the demand amount and the planned value of the demand amount indicated by the control data match. Control. In this example, the power conditioner 122 increases the amount of electric power output to the chiller 121B in order to increase the amount demanded by the chiller 121B.

Then, at the end time of the unit time, the power conditioner 122 transmits to the power management device 130 measurement data indicating the actual value of the amount demanded per unit time at the demand location 120 .

The measurement data receiving unit 131 stores the information indicated by the measurement data in the data storage unit 137 when receiving the measurement data indicating the actual value of the demand amount. When the demand amount by the chiller 121B is increased over a plurality of unit times, the data storage unit 137 stores information as shown in FIG. In the example shown in FIG. 10, the actual demand amount by the chiller 121B in each unit time of 5 frames counted from the unit time from the start time "10:00" to the end time "10:30" is "54 (kWh)". It has become.

As described above, the present invention has been described using the embodiments, but the technical scope of the present invention is not limited to the scope described in the above embodiments. It is obvious to those skilled in the art that various modifications or improvements can be made to the above embodiments. It is clear from the description of the scope of claims that forms with such modifications or improvements can also be included in the technical scope of the present invention.

In the above embodiment, the photovoltaic power generation facility 111A is described as an example of "another power generation facility different from the secondary battery". However, "another power generation facility different from the secondary battery" is not limited to the photovoltaic power generation facility 111A. It is desirable that the "other power generation equipment different from the secondary battery" be power generation equipment that uses renewable energy. For example, the above embodiment can employ wind power generation equipment, biomass power generation equipment, hydraulic power generation equipment, geothermal power generation equipment, and solar thermal power generation equipment instead of or in addition to the solar power generation equipment 111A. .

The said embodiment mentioned the chiller 121B as an example as a "specific load installation", and demonstrated it. However, the "specific load facility" is not limited to the chiller 121B as long as it can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time. For example, the above embodiment can employ a heat pump, hydrogen generation equipment, ethanol generation equipment, or ammonia generation equipment in place of or in addition to the chiller 121B.

In the above embodiment, the configuration in which the power conditioner 112 and the power management device 130 are connected for communication via a WAN has been described as an example. However, the communication network for communication connection between power conditioner 112 and power management device 130 is not limited to WAN. For example, the power conditioner 112 and the power management device 130 may be communicatively connected via power line communication. Power line communication is a technology that uses power lines as communication lines. Also, for example, the power conditioner 112 and the power management device 130 may be connected for communication via a LAN (Local Area Network). A LAN is a network in which computers, communication devices, information devices, and the like within a limited range are connected by cables or radio waves to enable mutual data communication.

In the above embodiment, the configuration in which the power conditioner 122 and the power management device 130 are connected for communication via a WAN has been described as an example. However, the communication network for communication connection between power conditioner 122 and power management device 130 is not limited to WAN. For example, the power conditioner 122 and the power management device 130 may be communicatively connected via power line communication. Also, for example, the power conditioner 122 and the power management device 130 may be connected for communication via a LAN.

In the above embodiment, the power generation site 110 has one power conditioner 112 as an example. However, the number of power conditioners 112 is not limited to one. For example, there may be a power conditioner 112 for the photovoltaic power generation facility 111A and a power conditioner 112 for the secondary battery 111B, and a plurality of power conditioners 112 may be connected to the transformer 113. Alternatively, instead of connecting the AC power generation facility to the power conditioner 112, the AC power generation facility may be directly connected to the transformer 113 as it is.

In the above embodiment, a configuration in which one power conditioner 122 is provided in the demand location 120 has been described as an example. However, the number of power conditioners 122 is not limited to one. For example, there may be a power conditioner 112 for the specific load equipment 121A and a power conditioner 112 for the chiller 121B, and a plurality of power conditioners 122 may be connected to the transformer 123. Alternatively, instead of connecting the AC demand equipment to the power conditioner 122, the AC demand equipment may be directly connected to the transformer 123 as it is.

The execution order of each processing such as actions, procedures, steps, and stages in the devices, systems, programs, and methods shown in the claims, the specification, and the drawings is particularly "before", "before", etc. not explicitly stated. It should be noted that the execution order of each process can be realized in any order as long as the output of the previous process is not used in the subsequent process. Regarding the operation flow in the claims, the specification, and the drawings, even if the description is made using "first," "next," etc. for convenience, it means that it is essential to carry out in this order. not a thing

100 self-consignment system, 110 power generation site, 111A photovoltaic power generation facility, 111B secondary battery, 112 power conditioner, 113 transformer, 120 demand site, 121A specific load facility, 121B chiller, 122 power conditioner, 123 transformer, 130 power management device, 131 measurement data receiver, 132 power generation planning unit, 133 demand planning unit, 134 power generation control unit, 135 demand control unit, 136 control data transmission unit, 137 management information storage unit, 200 power system

Claims (8)

A power management device that manages power in self-consignment for transmitting electricity generated by a power generation facility of a business operator to a load facility of the business operator at another location using a power system of an electric power company,
a power generation control unit that controls the amount of power generated by the power generation equipment including a secondary battery;
a demand control unit that controls the demand amount by the load equipment including a specific load equipment that can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time and extract it,
The power generation control unit is capable of controlling the secondary battery such that a planned value and an actual value of the amount of power generated by the power generation equipment match in one unit time,
The demand control unit
In one unit time, the specific load facility can be controlled so that the planned value and the actual value of the demand amount by the load facility match,
When the secondary battery is controlled in one unit time, controlling the demand amount by the load equipment over a plurality of unit times after the one unit time,
A power management apparatus, wherein the power generation control unit controls the power generation amount of the power generation equipment over a plurality of unit times when the demand amount of the load equipment is controlled over a plurality of unit times. The power generation control unit controls to discharge the secondary battery when the actual value of the amount of power generated by another power generation facility different from the secondary battery is smaller than the planned value in one unit time,
When the secondary battery is discharged in one unit time, the demand control unit performs control to reduce the demand amount by the specific load facility over a plurality of unit times after the one unit time. ,
2. The power generation control unit according to claim 1, wherein when the demand amount by the specific load facility decreases over a plurality of unit times, the secondary battery is controlled to be charged over the plurality of unit times. Power management device. The power generation control unit controls to charge the secondary battery when the actual value of the amount of power generated by another power generation facility different from the secondary battery is larger than the planned value in one unit time,
When the secondary battery is charged in one unit time, the demand control unit controls to increase the demand amount by the specific load facility over a plurality of unit times after the one unit time. ,
2. The power generation control unit controls to discharge the secondary battery over a plurality of unit times when the demand amount by the specific load facility increases over a plurality of unit times. 3. The power management device according to 2. a power generation planning unit that calculates a planned value for the amount of power generated by the power generation equipment in one unit time;
a demand planning unit that calculates a planned value of the demand amount by the load equipment in one unit time,
The power generation control unit controls the secondary battery so that the planned value of the amount of power generation calculated by the power generation planning unit and the actual value of the amount of power generation match in one unit time,
2. From claim 1, wherein the demand control unit controls the specific load facility so that the planned value of the demand calculated by the demand planning unit and the actual value of the demand match in one unit time. 4. The power management device according to any one of claims 3. The demand planning unit, when the secondary battery is controlled in one unit time, calculates a planned demand amount in each of a plurality of unit times after the one unit time,
5. The power management according to claim 4, wherein the power generation planning unit calculates a planned power generation amount for each of the plurality of unit times when the planned demand amount for each of the plurality of unit times is calculated. Device. The computer is made to function as a power management device that manages power in self-consignment in which the electricity generated by the generator equipment of the business operator is transmitted to the load equipment of the business operator at another location using the power system of the electric power company. a program,
a power generation control unit that controls the power generation equipment including a secondary battery;
causing the computer to function as a demand control unit that controls the load equipment including a specific load equipment that can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time,
The power generation control unit is capable of controlling the secondary battery such that a planned value and an actual value of the amount of power generated by the power generation equipment match in one unit time,
The demand control unit
In one unit time, the specific load facility can be controlled so that the planned value and the actual value of the demand amount by the load facility match,
When the secondary battery is controlled in one unit time, controlling the demand amount by the load equipment over a plurality of unit times after the one unit time,
A program, wherein the power generation control unit controls the power generation amount of the power generation equipment over a plurality of unit times when the demand amount of the load equipment is controlled over a plurality of unit times. A power management method for managing power in self-consignment in which electricity generated by a power generation facility of a business operator is transmitted to a load facility of the business operator at another location using a power system of an electric power company,
controlling the power generation equipment including a secondary battery;
controlling the load facility including a specific load facility that can convert electrical energy greater than a predetermined amount into thermal energy over a period of time longer than one unit time,
In one unit time, the secondary battery can be controlled so that the planned value and the actual value of the amount of power generated by the power generation equipment match,
In one unit time, the specific load facility can be controlled so that the planned value and the actual value of the demand amount by the load facility match,
When the secondary battery is controlled in one unit time, controlling the demand amount by the load equipment over a plurality of unit times after the one unit time,
A power management method, wherein when the demand amount by the load facility is controlled over a plurality of unit times, the power generation amount by the power generation facility is controlled over the plurality of unit times. A self-consignment system that uses the power system of an electric power company to transmit electricity generated by a power generation facility of a business operator to a load facility of the business operator at another location,
Equipped with a power management device that manages power in self-consignment,
The power management device
a power generation control unit that controls the power generation equipment including a secondary battery;
A demand control unit that controls the load equipment including a specific load equipment that can convert electrical energy larger than a predetermined amount into thermal energy over a period of time longer than one unit time and extract it,
The power generation control unit is capable of controlling the secondary battery so that a planned value and an actual value of the amount of power generated by the power generation equipment match in one unit time,
The demand control unit
In one unit time, the specific load facility can be controlled so that the planned value and the actual value of the demand amount by the load facility match,
When the secondary battery is controlled in one unit time, controlling the demand amount by the load equipment over a plurality of unit times after the one unit time,
The self-consignment system, wherein the power generation control unit controls the power generation amount of the power generation equipment over a plurality of unit times when the demand amount of the load equipment is controlled over a plurality of unit times.

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