JP2019037041A - Power generation control system, program, and control method - Google Patents

Abstract

To improve the response regarding control of output power.SOLUTION: A first acquisition unit (second communication unit 12) acquires the actual value of an output power P1 of a power generation system 100. A second acquisition unit 13 acquires the actual value of a reverse flow power P2 reversely flowed to a power system 104. A generation unit 21 generates a command value CMD of the output power P1. The second communication unit 12 (output unit) outputs the command value CMD to the power generation system 100. The generation unit 21 adds a feedback amount corresponding to the actual value of the reverse flow power P2 to the previous command value CMD to generate the current command value CMD. The generation unit 21 adds a feedback amount to the actual value of the output power P1 instead of the previous command value CMD based on the comparison result obtained by comparing the magnitude of the previous command value CMD and the actual value of the output power P1 to generate the current command value CMD.SELECTED DRAWING: Figure 1

Description

  The present disclosure relates to a power generation control system, a program, and a control method, and more particularly, to a power generation control system, a program, and a control method for controlling the power generation system.

  Conventionally, there has been a power conversion device that converts DC power respectively input from a distributed power source and a storage battery into AC power (see, for example, Patent Document 1). The power converter includes a first DC converter, a second DC converter, an inverter, and a control unit. The first DC converter converts the voltage of DC power input from the distributed power supply, and the second DC converter converts the voltage of DC power input from the DC power supply. The inverter converts DC power input from the first DC converter and the second DC converter into AC power. In the power converter, when a message instructing to stop the output of the distributed power supply is received from the external server, the control unit stops the operation of the first DC converter and stops the output of the distributed power supply.

JP, 2006-158434, A

  In the power conversion device of Patent Document 1, the control unit receives the message instructing to stop the output of the distributed power supply and stops the operation of the first DC converter. However, when the control of the first DC converter is delayed, the control unit The instructions from the server may not be followed.

  An object of the present disclosure is to provide a power generation control system, a program, and a control method capable of improving responsiveness related to control of output power.

  The power generation control system according to an aspect of the present disclosure includes a first acquisition unit, a second acquisition unit, a generation unit, and an output unit. The first acquisition unit acquires the actual value of the output power of the power generation system that can output the power generated in the power system. The second acquisition unit acquires an actual value of reverse flow power that is reversely flowed to the power system. The generation unit generates a command value for the output power. The output unit outputs the command value to the power generation system. The generation unit generates a current command value by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value. The generation unit adds the feedback amount to the actual value of the output power instead of the previous command value based on a comparison result of comparing the magnitude of the previous command value and the actual value of the output power. Generate the current command value.

  The power generation control system according to an aspect of the present disclosure includes a first acquisition unit, a second acquisition unit, a third acquisition unit, a generation unit, and an output unit. The first acquisition unit acquires the actual value of the output power of the power generation system capable of outputting the power generated by the load and the power system. The second acquisition unit acquires an actual value of reverse flow power that is reversely flowed to the power system. The third acquisition unit acquires an actual value of power consumption of the load. The generation unit generates a command value for the output power. The output unit outputs the command value to the power generation system. The generation unit generates a current command value by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value. When the actual value of the output power is closer to the actual value of power consumption of the load than the previous command value, the generating unit replaces the previous command value with the actual value of the output power. The current command value is generated by adding the feedback amount.

  The power generation control system according to an aspect of the present disclosure includes a first acquisition unit, a second acquisition unit, a generation unit, and an output unit. The first acquisition unit acquires the actual value of the output power of the power generation system that can output the power generated in the power system. The second acquisition unit acquires an actual value of reverse flow power that is reversely flowed to the power system. The generation unit generates a command value for the output power. The output unit outputs the command value to the power generation system. The generation unit performs reverse flow zero control for generating the command value so that the reverse flow power becomes zero. The generating unit adds the feedback amount corresponding to the actual value of the reverse power flow to the actual value of the output power when the command value is generated at a predetermined number of times from a predetermined timing in the reverse power zero control. The command value is generated. The predetermined timing is at least one of a timing for switching from an increasing period for increasing the output power to a decreasing period for decreasing the output power and a timing for switching from the decreasing period to the increasing period.

  A program according to an aspect of the present disclosure is a program for causing a computer system to operate as a power generation control system that outputs a command value of output power of the power generation system to a power generation system capable of outputting power generated by an electric power system. is there. The program according to one aspect causes a computer system to execute a first acquisition process, a second acquisition process, a generation process, and an output process. In the first acquisition process, the actual value of the output power is acquired. In the second acquisition process, the actual value of the reverse power flow that flows backward to the power system is acquired. In the generation process, a command value for the output power is generated. In the output process, the command value is output to the power generation system. In the generation process, a current command value is generated by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value. In the generation process, the feedback amount is added to the actual value of the output power instead of the previous command value based on a comparison result comparing the magnitudes of the previous command value and the actual value of the output power. Generate the current command value.

  A control method according to an aspect of the present disclosure is a control method for controlling output power of a power generation system that can output power generated by an electric power system. The control method according to one aspect includes a first acquisition process, a second acquisition process, a generation process, and an output process. In the first acquisition process, the actual value of the output power is acquired. In the second acquisition process, the actual value of the reverse power flow that flows backward to the power system is acquired. In the generation process, a command value for the output power is generated. In the output process, the command value is output to the power generation system. In the generation process, a current command value is generated by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value. In the generation process, the feedback amount is added to the actual value of the output power instead of the previous command value based on a comparison result comparing the magnitudes of the previous command value and the actual value of the output power. Generate the current command value.

  According to the present disclosure, it is possible to improve responsiveness related to control of output power.

FIG. 1 is a block diagram of an entire system including a power generation control system according to an embodiment of the present disclosure. FIG. 2 is a graph showing an example of a suppression value, a command value, and power consumption in the power generation control system same as above. FIG. 3 is a flowchart showing the operation of the above power generation control system. FIG. 4 is a graph illustrating an example of output power, a command value, and power consumption in a comparative example according to an embodiment of the present disclosure. FIG. 5 is a graph showing an example of output power, command value, and power consumption in the above power generation control system.

(1) Outline The following embodiment is only one of various embodiments of the present invention. The following embodiments can be variously modified according to the design or the like as long as the object of the present invention can be achieved.

  As shown in FIG. 1, the power generation control system 1 of the present embodiment includes a first acquisition unit (second communication unit 12), a second acquisition unit 13, a generation unit 21, and an output unit (second communication unit 12). And).

  The first acquisition unit (second communication unit 12) acquires the actual value of the output power P1 of the power generation system 100 that can output the power (output power P1) generated in the power system 104.

  The second acquisition unit 13 acquires the actual value of the reverse power flow P <b> 2 that flows backward to the power system 104.

  The generation unit 21 generates a command value CMD for the output power P1.

  The output unit (second communication unit 12) outputs the command value CMD to the power generation system 100.

  The generation unit 21 adds the feedback amount corresponding to the actual value of the reverse power flow P2 to the previous command value CMD (CMD1) to generate the current command value CMD (CMD2).

  The generation unit 21 feeds back to the actual value of the output power P1 instead of the previous command value CMD (CMD1) based on the comparison result of comparing the magnitude of the previous command value CMD (CMD1) and the actual value of the output power P1. The current command value CMD (CMD2) is generated by adding the amount. In the following description, when the current command value and the previous command value CMD are described separately, the previous command value is described as CMD1, and the current command value is described as CMD2.

  In the present embodiment, the generation unit 21 adds a feedback amount to the actual value of the output power P1 instead of the previous command value CMD1 based on the comparison result between the previous command value CMD1 and the actual value of the output power P1. The current command value CMD2 is generated. Therefore, when the previous command value CMD1 has deviated from the target value of the output power P1, and the actual value of the output power P1 is closer to the target value than the previous command value CMD1, the output power P1 becomes the target value. The time until control is shortened, and the response of control of the output power P1 can be improved.

(2) Details (2.1) Overall Configuration Hereinafter, the power generation control system according to Embodiment 1 will be described in detail with reference to the drawings.

  As shown in FIG. 1, the power generation control system 1 generates power that can output power to a load 105 installed in a facility 200 of a power consumer and a power system 104 of an electric power company (for example, a power company). Used in system 100. “Output power to the power grid 104” means that the power generated by the power generation system 100 is reversely flowed to the power grid 104 and sold. The power output from the power generation system 100 to the power system 104 is referred to as “reverse power flow power”. Note that the reverse power flow power may be referred to as “power sales power”, and the power supplied from the power system 104 to the load 105 is referred to as “power purchase power”. Here, a state where the power generation system 100 outputs generated power to the power system 104 is referred to as a power sale state, and a state where power is supplied from the power system 104 to the load 105 is referred to as a power purchase state.

  As shown in FIG. 1, the power generation system 100 includes a distributed power source 103 and a power conditioner 102. The distributed power source 103 includes at least a solar battery. The distributed power supply 103 may further include a storage battery or the like.

  The power generation system 100 is connected to the power system 104 via the distribution board 109. The distribution board 109 outputs power supplied from at least one of the power conditioner 102 and the power system 104 to the load 105.

  When the power generated by the power generation system 100 exceeds the power consumption consumed by the load 105, surplus power is generated. Surplus power is power obtained by subtracting the power consumption of the load 105 from the power generated by the power generation system 100. When the power generation system 100 outputs surplus power to the power grid 104 via the distribution board 109, a consumer who owns the power generation system 100 can sell power to the electric power company. In the present embodiment, the power generation system 100 can supply power to the power system 104 and the load 105, but the load 105 may not be connected to the power generation system 100. Power is supplied to the system 104.

  By the way, an electric power provider may request a consumer who owns the power generation system 100 to suppress the power output to the power system 104 for a specific period. The instruction to suppress the output of the power generation system 100 is referred to as “output suppression”. The power generation system 100 needs to be controlled to suppress the output of the power generation system 100 when a request for output suppression is received from an electric power company or the like. When receiving the request for “output suppression”, it is necessary to limit the output of the power generation system 100 so that at least the reverse power flow becomes zero, and the power generation control system 1 controls the output from the electric power company. In response, the output power of the power generation system 100 is controlled. The control operation of the power generation control system 1 will be described in “(3) Operation”.

  Since this embodiment pays attention to the technology regarding surplus purchase rather than so-called total purchase, the power generation system 100 will be described assuming that it is a residential power generation system as an example. In the case of surplus purchase, in addition to the control for adjusting the output power of the power generation system 100 to be equal to or less than the suppression value requested by the output suppression, it is possible to control the reverse power flow to zero. Therefore, even when there is a request for output suppression, if the power consumption of the load 105 provided in the facility 200 exceeds the output suppression suppression value, the power generation system 100 outputs the output power P1 up to the power consumption of the load 105. Can be increased. In the following embodiment, when the suppression value is 100%, there is no request for output suppression, and the power generation system 100 is in a state where the output power P1 is not limited.

  The power generation control system 1 and the power generation system 100 of the present embodiment are provided in a detached house which is an example of a customer facility 200. The power generation control system 1 is owned by a resident (customer) of a detached house, for example.

  Further, in the present embodiment, it is assumed that the control facility 2 for managing the load 105 is provided in the customer facility 200. For example, it is assumed that the control device 2 has a function as a so-called HEMS (Home Energy Management System) controller. The power generation control system 1 according to the present embodiment acquires information related to “output suppression” (hereinafter referred to as “schedule information”) from the server device 101 owned by the electric power company via the control device 2.

(2.2) Load The load 105 includes an electric device provided in the facility 200. Since a general detached house is assumed as the facility 200, the load 105 may include a plurality of electric devices provided in the facility 200. Specifically, the load 105 may correspond to any of an electric water heater, a refrigerator, an air conditioner, a washing machine, a rice cooker, an electric heater, an electric water heater for baths, and the like.

  When the power generation system 100 is a creation-saving linkage system and includes a storage battery in addition to the solar battery, the load 105 may include a storage battery. In other words, the storage battery may be considered as a load 105 that consumes negative power during discharging.

(2.3) Distribution Board The distribution board 109 outputs power supplied from at least one of the power generation system 100 and the power system 104 to the load 105.

  In addition, the distribution board 109 has a function of outputting the power of the power generation system 100 output from the power conditioner 102 to the power system 104 (reverse flow). When the distribution board 109 outputs the electric power from the power conditioner 102 to the electric power system 104, the consumer sells the electric power generated by the power generation system 100 to the electric power company.

(2.4) Server device The server device 101 is a device owned by an electric power company (for example, an electric power company). The server device 101 may be a device owned by a broker (distributor). In this case, data is relayed between the server device of the electric power company and the control device 2. The server apparatus 101 transmits schedule information to a plurality of consumers that are targets of output suppression. The schedule information is information including at least the suppression value P10. It is desirable that the schedule information further includes a target period that is a target of output suppression. The information on the target period includes the start timing of the target period and the end timing of the target period.

  The suppression value P10 is information for designating the degree of output suppression. As an example, the electric power provider may designate the suppression value P10 as a percentage (%) as a ratio to the maximum power (rated power) that the power generation system 100 can output. Specifically, for example, when the maximum power of the power generation system 100 of a certain consumer is 5 kW, if the suppression value P10 specified by the electric power company is 40%, the output power P1 of the power generation system 100 is suppressed to 2 kW. It is required to do. Further, in the present embodiment, as with the suppression value P10, the actual value of the output power P1, the command value CMD, the reverse power flow, and the power consumption of the load 105 are ratios with respect to the maximum power (rated power) that the power generation system 100 can output. As a percentage (%).

  It should be noted that the suppression value P10, the actual value of the output power P1, the command value CMD, the reverse power flow power, and the power consumption of the load 105 are merely examples (%), and are actual power values (for example, effective values). There may be. However, since the power generation system 100 installed in a plurality of consumers subject to output suppression has variations in maximum output, the suppression value P10 is a percentage (%) with respect to the maximum output, considering fairness. It is desirable to be.

  The start timing of the target period and the end timing of the target period are date information, for example. When the schedule information includes a plurality of target periods, the schedule information includes a suppression value P10 that is different for each target period. Therefore, the power generation control system 1 can adjust the output power P1 of the power generation system 100 in each of a plurality of target periods based on the schedule information.

  In addition, the timing which the server apparatus 101 transmits schedule information toward each consumer is various. For example, the server apparatus 101 transmits basic schedule information for about 400 days to the control device 2. In addition, the server apparatus 101 transmits the difference information for correcting the schedule information according to the weather condition for a shorter period of time, and the schedule information stored in the control device 2 is updated.

(2.5) Power Generation System The power generation system 100 includes the power conditioner 102 and the distributed power source 103 as described above.

  The power conditioner 102 has a wireless communication function using radio waves, for example. The power conditioner 102 can communicate with a second communication unit 12 of the power generation control system 1 described later. The power conditioner 102 is configured to receive information about a command value CMD that is a target value of the output power P <b> 1 from the second communication unit 12. In the present embodiment, the power conditioner 102 receives, from the second communication unit 12, information on the slope that changes the output power P1 in addition to the command value CMD that is the target value of the output power P1. Here, “slope information” is, for example, information on the time required to change the output power P1 from a minimum value to a maximum value (that is, from 0% to 100%) with a constant slope. This is information on the speed to change (this speed is called the control speed). Further, the power conditioner 102 may perform communication with the second communication unit 12 of the power generation control system 1 by wired communication instead of wireless communication.

  When the power conditioner 102 receives the command value CMD of the output power P1 and the control speed information from the power generation control system 1, the power conditioner 102 converts the command value CMD and the control speed to the output of the distributed power source (solar cell) 103. Output control is performed along the line. Further, the power conditioner 102 transmits information on the actual value of the current output power P1 to the second communication unit 12 at a predetermined timing from the power generation control system 1 or in response to a transmission request periodically transmitted. It is configured as follows. Further, the power conditioner 102 may be configured to periodically transmit information on the actual value of the current output power P1 to the second communication unit 12.

  The power generation system 100 may be configured to acquire information other than the command value CMD from the control device 2 or the server device 101 by, for example, wireless communication, wired communication, or the like.

(2.6) Control Device The control device 2 has a function as a HEMS controller for managing the electric device that is the load 105 as described above. The control device 2 receives various data by communicating with an external server via the Internet (public communication network), for example, and controls the load 105 based on the data. This external server may be the server device 101 of the electric utility shown in FIG. 1 or a server owned by the manufacturer of the load 105.

  The control device 2 is configured to receive schedule information by communicating with the server device 101. As described above, the control device 2 stores schedule information for about 400 days, and updates the schedule information every time it receives the schedule information difference information from the server apparatus 101.

  Moreover, the control apparatus 2 of this embodiment can communicate with the 1st communication part 11 of the electric power generation control system 1 mentioned later, for example by radio | wireless communication using an electromagnetic wave. The control device 2 may perform communication with the first communication unit 11 of the power generation control system 1 by wired communication instead of wireless communication.

  The control device 2 transmits schedule information to the power generation control system 1 at an appropriate timing at least before the start timing of the target period. For example, when receiving the schedule information from the server apparatus 101, the control device 2 may immediately transmit the schedule information to the power generation control system 1. The control device 2 may transmit the schedule information received from the server device 101 to the power generation control system 1 without processing, or may process the schedule information and transmit it to the power generation control system 1 after processing. Alternatively, the control device 2 may transmit the updated schedule information to the power generation control system 1.

  The control device 2 may include a card interface that can read data from the memory card, and may acquire schedule information recorded on the memory card from a memory card connected to the card interface. In this case, the server apparatus 101 is not an essential configuration, and can be omitted as appropriate.

(2.7) Power Generation Control System The power generation control system 1 includes a control unit 10, a first communication unit 11, a second communication unit 12 (first acquisition unit, output unit), a second acquisition unit 13, and a second 3 acquisition unit 14.

  The first communication unit 11 has a communication function for communicating with the control device 2, and acquires output suppression schedule information from the control device 2. In addition, the 1st communication part 11 may receive schedule information directly from the server apparatus 101, and the control apparatus 2 is unnecessary in that case. The power generation control system 1 may include a card interface that can read data from a memory card. The power generation control system 1 may acquire schedule information recorded on the memory card from the memory card connected to the card interface, and the server device 101 and the control device 2 are not essential components and can be omitted as appropriate. It is.

  The second communication unit 12 has a function of communicating with the power conditioner 102 of the power generation system 100. The second communication unit 12 communicates with the power conditioner 102 by a wired or wireless communication method.

  The 2nd communication part 12 as a 1st acquisition part acquires the information of the performance value of the output electric power P1 output from the power conditioner 102 from the power conditioner 102 by communicating with the power conditioner 102. FIG. Further, the second communication unit 12 as the output unit outputs the command value CMD generated by the control unit 10 to the power conditioner 102. In this embodiment, the power generation control system 1 acquires information on the actual value of the output power P1 from the power conditioner 102. However, the power generation control system 1 acquires the measurement result from the measurement circuit that measures the actual value of the output power P1. Also good. Moreover, the power generation control system 1 may include a measurement circuit that measures the actual value of the output power P1.

  The second acquisition unit 13 acquires the actual value of the reverse flow power P2 output from the power generation system 100 to the power system 104 at the connection point with the power system 104. The second acquisition unit 13 may obtain the actual value of the reverse power flow P2 by calculation based on the detection result of the current sensor CT1 that detects the current flowing through the connection point with the power system 104, or the reverse power flow. Information on the actual value of the reverse flow power P2 may be acquired from a measurement circuit that measures P2. Further, the second acquisition unit 13 may acquire information on the power consumption of the load 105 from the control device 2.

  The third acquisition unit 14 acquires the actual value of the power consumption P3 consumed by the load 105. The third acquisition unit 14 may calculate the actual value of the power consumption P3 based on the detection result of the current sensor CT2 that detects the current flowing from the distribution board 109 to the load 105, or measure the power consumption P3. The information of the actual value of the power consumption P3 may be acquired from the measurement circuit that performs the operation. Further, the third acquisition unit 14 may acquire information on the power consumption of the load 105 from the control device 2. Note that the third acquisition unit 14 is not an essential configuration, and the third acquisition unit 14 may be omitted if the actual value of the power consumption P3 consumed by the load 105 is unnecessary when generating the command value CMD. Good.

  The control unit 10 is composed of, for example, a microcomputer having a processor and a memory 22. That is, the control unit 10 is realized by a computer system having a processor and a memory 22. When the processor executes, for example, a program recorded in the memory 22, various functions of the control unit 10 (for example, functions of the generation unit 21 that generates the command value CMD) are realized by the computer system. The program may be recorded in advance in the memory 22 of the microcomputer, or may be provided by being recorded through a telecommunication line such as the Internet, or in a non-temporary recording medium such as a memory card. The memory 22 may store the latest schedule information that has been updated.

(2.8) Operation The operation of the power generation control system 1 of the present embodiment will be described.

  The power generation control system 1 generates a command value CMD for the output power P1 of the power generation system 100 based on output suppression schedule information acquired from the control device 2 every time a predetermined control cycle (for example, 1 minute) elapses. The command value CMD is output to the power generation system 100. The command value CMD is information indicating the target value of the output power P1. In this embodiment, the command value CMD is a value expressed as a percentage when the minimum value of the output power P1 is 0% and the maximum value is 100%, but the value of the output power P1 (for example, instantaneous power or The value of the amount of power per unit time) itself may be used. In the present embodiment, the power generation control system 1 outputs information on the control speed for changing the output power P1 to the power generation system 100 in addition to the command value CMD indicating the target value of the output power P1. Only the value CMD may be output to the power generation system 100. The power generation control system 1 may transmit control speed information to the power generation system 100 only when the control speed is changed, or the control speed information may be set in the power generation system 100 in advance.

  FIG. 2 is a diagram illustrating an example of an actual value of the output suppression suppression value P10, the command value CMD, and the power consumption P3 of the load 105. In FIG. 2, the actual value of the suppression value P10, the command value CMD, and the power consumption P3 is a ratio (percentage) when the minimum value of the output power P1 output from the power generation system 100 is 0% and the maximum value is 100%. It is represented by Similarly, the actual value of the output power P1 and the actual value of the reverse power flow P2 are also expressed as a percentage (percentage) when the minimum value of the output power P1 output from the power generation system 100 is 0% and the maximum value is 100%. expressed.

  Since the suppression value P10 is 100% in the target period up to time t1, the upper limit of the output power P1 of the power generation system 100 is 100%, and the output power P1 of the power generation system 100 is not suppressed. In the target period up to time t1, the generation unit 21 generates a command value CMD and a control speed that control the output power P1 of the power generation system 100 to the maximum value that can be generated by the power generation system 100. Then, the second communication unit 12 transmits the command value CMD generated by the generation unit 21 and the control speed to the power conditioner 102. Based on the command value CMD and the control speed received from the second communication unit 12, the power conditioner 102 increases the output power P1 according to the control speed so that the actual value of the output power P1 matches the command value CMD. Decrease.

  When the target period of output suppression is switched at time t1 and the suppression value P10 decreases from 100% to 0%, the generation unit 21 of the power generation control system 1 sets the target value of the output power P1 to 0% (suppression value). A command value CMD and a control speed at that time are generated. Here, the control speed when the suppression value P <b> 10 is changed is determined in advance by an electric utility or the like, and is recorded in the memory 22 of the control unit 10. When the generation unit 21 determines the command value CMD and the control speed, the second communication unit 12 outputs the command value CMD and the control speed generated by the generation unit 21 to the power generation system 100. When the power conditioner 102 of the power generation system 100 receives the command value CMD and the control speed from the second communication unit 12, the output power P1 is 100% at the designated control speed based on the received command value CMD and the control speed. From 0 to 0%. Thereby, the electric power generation system 100 can follow the control instruction | command requested | required from the electric power provider.

  The generation unit 21 determines whether or not the actual value of the output power P1 is controlled to the command value CMD based on the actual value of the output power P1 received by the second communication unit 12 every time the control cycle elapses. To do. The generation unit 21 may determine whether or not the actual value of the output power P1 of the power generation system 100 is controlled to the command value CMD using the internal timer of the control unit 50. For example, when the output power P1 of the power generation system 100 changes at a constant control speed (inclination), the generation unit 21 controls the control time required for the actual value of the current output power P1 to reach the command value CMD standard value. Is obtained in advance. And the production | generation part 21 will measure the actual value of the output electric power P1 of the electric power generation system 100, if it counts that control time passed after starting the control action which controls the actual value of the output electric power P1 to the command value CMD. Is controlled to the command value CMD. Here, the control time may be the time required for the output power P1 of the power generation system 100 to change from the minimum value (0%) to the maximum value (100%) at a constant control speed (slope).

  When the generation unit 21 determines that the actual value of the output power P1 is controlled to the command value CMD (in this case, 0% of the suppression value) at time t2, the generation period 21 (time t2) until the suppression value P10 is changed next time. At t3), the reverse flow zero control is performed to make the reverse flow power P2 zero.

  Here, the generation unit 21 performs reverse flow zero control for generating the command value CMD so as to increase the output power P1 of the power generation system 100 within a range where the reverse flow power P2 does not exceed zero, and the generation unit 21 generates The second communication unit 12 outputs the command value CMD thus generated to the power generation system 100. Thereby, the power generation control system 1 can increase the output power P1 of the power generation system 100 in a range in which the reverse flow power P2 does not exceed zero. In the reverse power flow zero control, for example, when the reverse power flow P2 is generated by increasing the output power P1 or decreasing the power consumption P3, the power generation control system 1 generates the reverse power flow P2. The reverse power flow power P2 is required to be zero within a predetermined time. This predetermined time is, for example, a time determined by an electric utility, for example, 5 minutes.

  The operation when the power generation control system 1 performs the reverse power flow zero control will be described with reference to FIGS.

  The control unit 10 of the power generation control system 1 performs a process of generating a command value CMD every time a predetermined control cycle elapses.

The control unit 10 causes the second communication unit 12 (first acquisition unit) to transmit the transmission request to the power conditioner 102 from the second communication unit 12 at a predetermined timing, so that the output power P1 from the power conditioner 102 is recorded. A first acquisition process for acquiring a value is performed (S1 in FIG. 3).
Note that the control unit 10 causes the second communication unit 12 to acquire the actual value of the output power P1 from the power conditioner 102 by causing the second communication unit 12 to periodically transmit a transmission request to the power conditioner 102. Also good. Further, the power conditioner 102 periodically transmits the actual value of the output power P1 to the power generation control system 1, and the second communication unit 12 periodically acquires the actual value of the output power P1 transmitted from the power conditioner 102. It may be configured to.

  Moreover, the control part 10 performs the 2nd acquisition process which makes the 2nd acquisition part 13 acquire the performance value of the reverse power flow P2 (S2 of FIG. 3).

  When the first and second acquisition processes are completed, the generation unit 21 of the control unit 10 performs a generation process for generating the command value CMD (S3 in FIG. 3), and the second communication unit 12 generates the generation value by the generation unit 21. An output process (S4 in FIG. 3) for outputting the command value CMD thus performed to the power conditioner 102 is performed.

  Here, the generation process performed by the generation unit 21 will be described in detail. The generation unit 21 generates the current command value CMD2 by adding the feedback amount FB1 corresponding to the actual value of the reverse flow power P2 to the command value CMD1 output previously so that the reverse flow power becomes zero. That is, the production | generation part 21 produces | generates command value CMD2 according to following formula (1).

CMD2 = CMD1 + a1 × (A1-P2) (1)
Here, A1 is a target value of the reverse flow power P2, and A1 is zero when the reverse flow zero control is performed. a1 is a feedback coefficient, which is 0.9 in the present embodiment, for example. Therefore, when the reverse flow zero control is performed, the feedback amount FB1 corresponding to the actual value of the reverse flow power P2 is (−a1 × P2). Therefore, when the actual value of the reverse flow power P2 is positive, that is, in the power sale state where power is output to the power system 104, the feedback amount FB1 is a negative value. In addition, when the actual value of the reverse flow power P2 is negative, that is, in the power purchase state in which power is supplied from the power system 104, the feedback amount FB1 is a positive value.

  In addition, when generating the command value CMD2, the generating unit 21 compares the previous command value CMD1 with the actual value of the output power P1. Then, the generation unit 21 uses the actual value of the output power P1 instead of the previous command value CMD1 based on the comparison result between the previous command value CMD1 and the actual value of the output power P1, and outputs the output power P1. The feedback value FB1 is added to the actual value to generate the current command value CMD2. In this case, the production | generation part 21 produces | generates command value CMD2 according to following formula (2).

CMD2 = P1 + a1 × (A1-P2) (1)
Specifically, if the feedback amount FB1 is negative and the actual value of the output power P1 is smaller than the previous command value CMD1, the generation unit 21 adds the feedback amount FB1 to the actual value of the output power P1 and determines the current command. The value CMD2 is generated. If the feedback amount FB1 is negative, the actual value of the reverse power flow P2 is positive (that is, the power sale state), so the negative feedback amount FB1 is changed to the actual value of the output power P1 smaller than the previous command value CMD1. As a result, the output power P1 can be reduced in a short time. Therefore, it is possible to improve the responsiveness of the control that makes the reverse flow power P2 zero.

  If the feedback amount FB1 is positive and the actual value of the output power P1 is larger than the previous command value CMD1, the generator 21 adds the feedback amount to the actual value of the output power P1 to generate the current command value CMD2. To do. If the feedback amount FB1 is positive, the actual value of the reverse flow power P2 is negative (that is, the power purchase state), so that the positive feedback amount FB1 is set to the actual value of the output power P1 that is larger than the previous command value CMD1. As a result, the output power P1 can be increased in a short time. Therefore, it is possible to improve the responsiveness of the control that makes the reverse flow power P2 zero.

  As described above, the generation unit 21 adds the feedback amount FB1 to the actual value of the output power P1 based on the comparison result between the previous command value CMD1 and the actual value of the output power P1, and obtains the current command value CMD2. Is generated. Therefore, when the previous command value CMD1 is deviated from the target value of the output power P1, and the actual value of the output power P1 is closer to the target value than the previous command value CMD1, the output power P1 becomes the target value. Time to be controlled can be shortened. Therefore, it is possible to improve the control response of the output power P1.

  Here, FIG. 4 is an explanatory diagram for explaining the reverse power flow zero control by the power generation control system of the comparative example, and an example of the relationship among the actual value of the output power P1, the actual value of the power consumption P3, and the command value CMD. Show. In the power generation control system of the comparative example, the command value CMD is generated according to the above equation (1).

  In the period from time t11 to time t13, since the actual value of the output power P1 is smaller than the actual value of the power consumption P3, the power is being purchased from the power system 104, and the actual value of the reverse flow power P2 is negative. become. Therefore, the power generation control system of the comparative example generates the command value CMD2 in accordance with the above formula (1) so that the current command value CMD2 is larger than the command value CMD2 output last time, and the generated command value CMD2 And the control speed are transmitted to the power conditioner 102. Here, since the amount of solar radiation incident on the solar cell is small during the period from time t11 to time t13, the power conditioner 102 increases the output power P1 even when the command value CMD2 for increasing the output power P1 is received. I can't. Therefore, in the period from time t11 to time t13, every time the control cycle dt elapses, a command value CMD that increases the output power P1 is generated. At time t12, the command value CMD is saturated to 100%. Yes. That is, the command value CMD is shifted from the actual target value of the output power P1.

  Thereafter, when the amount of solar radiation incident on the solar cell increases at time t13, when the output power P1 exceeds the power consumption P3, the power generation state in which the power generated by the power generation system 100 is output to the power system 104 is entered. . At this time, the power generation control system of the comparative example generates the command value CMD so as to decrease the output power P1 according to the above formula (1) in order to make the reverse flow power P2 zero. That is, the power generation control system of the comparative example generates the current command value CMD2 by adding the feedback amount to the previously output command value CMD1, and the previous command value CMD1 is saturated at 100% at time t13. It takes a long time for the command value CMD1 to decrease. Therefore, it takes a long time for the output power P1 of the power conditioner 102 to decrease, and it is not possible to perform control to make the reverse flow power P2 zero within a predetermined time T1 (for example, 5 minutes) determined by an electric power company or the like. there is a possibility.

  On the other hand, when generating the command value CMD, the generation unit 21 of the present embodiment compares the size of the previous command value CMD1 and the actual value of the output power P1. Then, the generation unit 21 uses the actual value of the output power P1 instead of the previous command value CMD1 based on the comparison result, and adds the feedback amount FB1 to the actual value of the output power P1 to generate the current command value CMD2. ing.

  FIG. 5 is an explanatory diagram illustrating the reverse power flow zero control in the power generation control system 1 of the present embodiment, and an example of the relationship between the actual value of the output power P1, the actual value of the power consumption P3, and the command value CMD. Show.

  In the period from time t21 to time t23, since the actual value of the output power P1 is smaller than the actual value of the power consumption P3, the power is being purchased from the power system 104, and the actual value of the reverse flow power P2 is negative. become. Therefore, the generation unit 21 generates the command value CMD2 according to the above equation (1) so that the current command value CMD2 is larger than the command value CMD1 output last time. Since the previous command value CMD1 is larger than the actual value of the output power P1 in the power purchase state, the generation unit 21 adds the feedback amount to the previous command value CMD1 to generate the command value CMD2. Then, the second communication unit 12 transmits the command value CMD2 generated by the generation unit 21 and the control speed to the power conditioner 102. Here, since the amount of solar radiation incident on the solar cell is small during the period from time t21 to time t23, the power conditioner 102 increases the output power P1 even when the command value CMD2 for increasing the output power P1 is received. I can't. Therefore, every time the control cycle dt elapses in the period from time t21 to time t23, the generation unit 21 generates a command value CMD that increases the output power P1, and the command value CMD is 100% at time t22. Is saturated. That is, the command value CMD is shifted from the actual target value of the output power P1.

  Thereafter, the amount of solar radiation incident on the solar cell at time t23 increases, so that the output power P1 increases. When the output power P1 exceeds the power consumption P3, the power generated by the power generation system 100 enters a power sale state that is output to the power system 104. Therefore, the generation unit 21 sets the reverse power flow P2 to zero. A command value CMD that reduces the output power P1 is generated. At time t24, since the actual value of the output power P1 is smaller than the previous command value CMD1 in the power sale state, the generation unit 21 adds the feedback amount FB1 to the actual value of the output power P1 to obtain the current command value CMD2. Generate. Therefore, compared with the case where the production | generation part 21 produces | generates this command value CMD2 by adding feedback amount FB1 to last command value CMD1, the actual value of output electric power P1 can be reduced in a short time. In the example of FIG. 5, the reverse flow power P2 can be controlled to zero at time t26, and the reverse flow zero control can be realized within a predetermined time T1 after the reverse flow power P2 is generated.

(3) Modifications The above embodiment is only one of various embodiments of the present disclosure. The above embodiment can be variously modified according to the design and the like as long as the object of the present disclosure can be achieved.

  Hereinafter, modifications of the embodiment will be listed. The modifications described below can be applied in appropriate combinations.

  Functions similar to those of the power generation control system 1 may be embodied by a control method, a computer program, or a non-transitory recording medium that records the program. The control method according to one aspect includes a first acquisition process, a second acquisition process, a generation process, and an output process. In the first acquisition process (step S1 in FIG. 3), the actual value of the output power P1 is acquired. In the second acquisition process (step S2 in FIG. 3), the actual value of the reverse power flow P2 that flows backward to the power system 104 is acquired. In the generation process (step S3 in FIG. 3), a command value CMD for the output power P1 is generated. In the output process (step S4 in FIG. 3), the command value CMD is output to the power generation system 100. In the generation process, the current command value CMD2 is generated by adding a feedback amount corresponding to the actual value of the reverse flow power P2 to the previous command value CMD1. Further, in the generation process, based on a comparison result of comparing the previous command value CMD1 and the actual value of the output power P1, a feedback amount is added to the actual value of the output power P1 instead of the previous command value CMD1. Command value CMD2 is generated. A (computer) program according to one aspect is a program for causing a computer system to execute a first acquisition process, a second acquisition process, a generation process, and an output process.

  The execution subject of the power generation control system 1 or the control method in the present disclosure includes a computer system. The computer system mainly includes a processor and a memory as hardware. When the processor executes the program recorded in the memory of the computer system, a function as an execution subject of the power generation control system 1 or the control method according to the present disclosure is realized. The program may be recorded in advance in the memory of the computer system, but may be provided through an electric communication line, or may be recorded in a recording medium such as a memory card, an optical disk, or a hard disk drive that can be read by the computer system. May be provided. A processor of a computer system includes one or more electronic circuits including a semiconductor integrated circuit (IC) or a large scale integrated circuit (LSI). The plurality of electronic circuits may be integrated on one chip, or may be distributed on the plurality of chips. The plurality of chips may be integrated into one device, or may be distributed and provided in a plurality of devices.

  Moreover, although the electric power generation control system 1 is implement | achieved by one apparatus, it is not limited to this structure. Two or more functions of at least one of the functions of the first acquisition unit (second communication unit 12), the second acquisition unit 13, the generation unit 21, and the output unit (second communication unit 12) of the power generation control system 1 are provided. It may be distributed in the system. The functions of the first acquisition unit (second communication unit 12), the second acquisition unit 13, the generation unit 21, and the output unit (second communication unit 12) are provided in a distributed manner in a plurality of devices. Also good. For example, the function of the generation unit 21 may be distributed and provided in a plurality of systems. At least some of the functions of the power generation control system 1 may be realized by, for example, cloud (cloud computing). For example, the command value CMD is generated by an external server provided outside the facility 200, and the power generation control system 1 outputs the command value CMD received from the external server to the power generation system 100. The output power P1 may be controlled. Further, the power generation system 100 may directly receive the command value CMD from an external server and control the output power P1.

  In the above embodiment, the generation unit 21 of the power generation control system 1 periodically generates the command value CMD. However, the power generation control system 1 generates a generation instruction from the outside (for example, a generation instruction from the control device 2). Upon receipt, the command value CMD may be generated. For example, when the first communication unit 11 receives information on the actual value of the reverse flow power P2 from the control device 2 as a generation instruction, the generation unit 21 performs a process of generating a command value CMD. In addition, if the first communication unit 11 cannot receive a generation instruction from the control device 2, the generation unit 21 counts the control cycle by the internal timer of the control unit 10 and generates a command value CMD every time the control cycle elapses. The processing to be performed may be performed.

  Further, when the actual value of the output power P1 is closer to the power consumption P3 of the load 103 than the previous command value CMD1 in the reverse power flow zero control, the generation unit 21 sets the feedback amount FB1 to the actual value of the output power P1. In addition, the current command value CMD2 may be generated.

  That is, the generation unit 21 generates the command value CMD2 starting from the command value CMD1 output last time and the actual value of the output power P1 that is closer to the actual value of the power consumption P3 acquired by the third acquisition unit 14. May be. That is, when the actual value of the output power P1 is closer to the power consumption P3 of the load 103 than the previous command value CMD1, the generation unit 21 replaces the previous command value CMD1 with the actual value of the output power P1 instead of the previous command value CMD1. The current command value CMD2 is generated by adding FB1.

  In this way, the generation unit 21 adds the feedback amount corresponding to the actual value of the reverse power flow P2 to the one closer to the actual value of the power consumption P3 among the actual value of the output power P1 and the command value CMD1 output last time. The value CMD2 is generated. Therefore, the actual value of the output power P1 is compared to the case where the command value CMD2 is generated starting from the one where the difference between the actual value of the output power P1 and the command value CMD1 output last time is larger than the actual value of the power consumption P3. Becomes a time until the actual value of the power consumption P3 is controlled. Therefore, the time until the reverse flow power P2 is controlled to zero can be shortened.

  In addition, the generation unit 21 periodically generates the command value CMD in the reverse power flow zero control. When the command value CMD2 is generated at a predetermined number of times from a predetermined timing, the generation unit 21 generates a reverse power flow to the actual value of the output power P1. The command value CMD2 may be generated by adding the feedback amount FB1 corresponding to the actual value of the power P2. Here, the predetermined timing refers to the timing of switching from the increase period (power purchase state) for increasing the output power P1 to the decrease period (power sale state) for decreasing the output power P1, and the increase from the decrease period (power sale state). It is at least one of the timing of switching to the period (power purchase state). Further, the predetermined number of times is the number of times the command value CMD2 is generated from a predetermined timing, and is about 1 to several times. For example, the command value CMD2 may be generated immediately after a predetermined timing, or the command value CMD2 may be generated for the second to third times from the predetermined timing.

  Here, during the increase period or decrease period of the output power P1, the actual value of the output power P1 cannot follow the command value CMD, and there may be a deviation between the command value CMD and the actual target value of the output power P1. . In such a case, when the generation unit 21 generates the command value CMD2 by adding the feedback amount FB1 to the actual value of the output power P1, the generation unit 21 generates the command value CMD2 by adding the feedback amount FB1 to the previous command value CMD1. As compared with the above, the target value of the output power P1 can be controlled in a short time.

  In the present embodiment, the power generation control system 1 controls the output power (P1) of one power generation system 100. However, the facility 200 is provided with a plurality of power generation systems 100, and the power generation control system 1 includes a plurality of power generation systems 100. The output power P1 of the system 100 may be controlled.

  In this case, the production | generation part 21 produces | generates command value CMD by the calculation method similar to the said embodiment and modification in each of the some electric power generation system 100. FIG. For example, when the feedback amount is negative (the actual value of the reverse power flow P2 is positive), the generation unit 21 performs the actual output power P1 if the actual output value P1 is smaller than the previous command value CMD1 in each power generation system 100. The current command value CMD2 is generated by adding the feedback amount to the value. When the feedback amount is positive (the actual value of the reverse power flow P2 is negative), the generation unit 21 outputs the output power P1 if the actual value of the output power P1 is larger than the previous command value CMD1 in the target power generation system 100. The command value CMD2 for this time is generated by adding the feedback amount to the actual value.

  When the command value CMD2 of the plurality of power generation systems 100 is generated by the generation unit 21, the second communication unit 12 as an output unit outputs two of the plurality of command values CMD to the plurality of power generation systems 100, respectively. Thus, the plurality of power generation systems 100 can control the output power P2 according to the command value CMD2 generated for each power generation system 100.

  The generation unit 21 feeds back the actual value of the output power P1 to the actual value of the output power P1 when the actual value of the output power P1 is closer to the actual value of the power consumption P3 of the load 105 than the previous command value in the target power generation system 100. The command value CMD2 of this time may be generated by adding the amount.

  Thereby, the optimal command value CMD is output to each of the plurality of power generation systems 100, and the output power P1 of the plurality of power generation systems 100 can be controlled.

  When the power generation control system 1 controls the output power P1 of the plurality of power generation systems 100, the generation unit 21 may generate a command value CMD that is common to the plurality of power generation systems 100.

  The generation unit 21 obtains an average value of the actual values of the output power P1 in the plurality of power generation systems as a representative value of the output power P1 based on the actual values of the output power P1 in the plurality of power generation systems. The representative value is not limited to the average value, and may be the maximum value, the minimum value, the median value, or the like of the output power P1 in a plurality of power generation systems.

  And the production | generation part 21 produces | generates command value CMD with the calculation method similar to the said embodiment and modification using the representative value of output electric power P1. For example, when the feedback amount is negative (the actual value of the reverse power flow P2 is positive), the generation unit 21 determines the output power P1 if the representative value of the output power P1 is smaller than the previous command value CMD1 in the target power generation system 100. The current command value CMD2 is generated by adding the feedback amount to the representative value. Further, when the feedback amount is positive (the actual value of the reverse power flow P2 is negative), the generator 21 outputs the output power P1 if the representative value of the output power P1 is larger than the previous command value CMD1 in the target power generation system 100. The command value CMD2 for this time is generated by adding the feedback amount to the representative value.

  When the command value CMD2 of the plurality of power generation systems 100 is generated by the generation unit 21, the second communication unit 12 as an output unit outputs two of the plurality of command values CMD to the plurality of power generation systems 100, respectively. Thus, the plurality of power generation systems 100 can control the output power P2 according to the command value CMD2 generated for each power generation system 100.

  The generation unit 21 feeds back the representative value of the output power P1 to the representative value of the output power P1 when the representative value of the output power P1 is closer to the actual value of the power consumption P3 of the load 105 than the previous command value in the target power generation system 100. The command value CMD2 of this time may be generated by adding the amount.

  Thereby, the command value CMD common to the plurality of power generation systems 100 can be output, and the output power P1 of the plurality of power generation systems 100 can be controlled. Moreover, since the production | generation part 21 produces | generates the command value CMD common to the several electric power generation system 100 using the representative value of output electric power P1, the load which calculates the command value CMD in the production | generation part 21 can be reduced.

(Summary)
As explained above, the power generation control system (1) of the first aspect includes the first acquisition unit (12), the second acquisition unit (13), the generation unit (21), and the output unit (12). Is provided. A 1st acquisition part (12) acquires the track record value of the output electric power (P1) of the electric power generation system (100) which can output the electric power generated to the electric power grid | system (104). A 2nd acquisition part (13) acquires the track record value of the reverse power flow (P2) reverse-flowed by an electric power grid | system (104). A production | generation part (21) produces | generates the command value (CMD) of output electric power (P1). The output unit (12) outputs a command value (CMD) to the power generation system (100). The generation unit (21) generates a current command value (CMD2) by adding a feedback amount corresponding to the actual value of the reverse flow power (P2) to the previous command value (CMD1). The generation unit (21) replaces the previous command value (CMD1) with the output power (P1) based on the comparison result comparing the previous command value (CMD1) and the actual value of the output power (P1). A feedback amount is added to the actual value to generate the current command value (CMD2).

  According to this aspect, based on the comparison result between the previous command value (CMD1) and the actual value of the output power (P1), feedback to the actual value of the output power (P1) instead of the previous command value (CMD1). The current command value (CMD2) can be generated by adding the amount. Therefore, when the previous command value (CMD1) deviates from the target value of the output power (P1), the actual value of the output power (P1) is closer to the target value than the previous command value (CMD1). The time until the output power (P1) is controlled to the target value can be shortened. Therefore, it is possible to improve the responsiveness related to the control of the output power (P1).

  In the power generation control system (1) of the second aspect, in the first aspect, the generation unit (21) sets the feedback amount to a negative value when the actual value of the reverse power flow (P2) is positive, and the reverse power flow When the actual value of power (P2) is negative, the feedback amount is set to a positive value.

  According to this aspect, the generation unit (21) can generate a command value (CMD) that makes the reverse flow power (P2) zero.

  In the power generation control system (1) of the third aspect, in the second aspect, when the feedback amount is a negative value and the actual value of the output power (P1) is smaller than the previous command value (CMD1), it is generated. The unit (21) generates the current command value (CMD2) by adding a feedback amount to the actual value of the output power (P1) instead of the previous command value (CMD1).

  According to this aspect, when the actual value of the reverse flow power (P2) is positive (power sale state), it is possible to improve the responsiveness of the reverse flow zero control that makes the reverse flow power (P2) zero. .

  In the power generation control system (1) of the fourth aspect, in the second or third aspect, the feedback amount is a positive value, and the actual value of the output power (P1) is larger than the previous command value (CMD1). In this case, the generation unit (21) generates the current command value (CMD2) by adding the feedback amount to the actual value of the output power (P1) instead of the previous command value (CMD1).

  According to this aspect, when the actual value of the reverse power flow (P2) is negative (in the power purchase state), it is possible to improve the responsiveness of the reverse power zero control that makes the reverse power flow (P2) zero. . Therefore, the output power (P1) of the power generation system (100) can be increased.

  The power generation control system (1) of the fifth aspect includes a first acquisition unit (12), a second acquisition unit (13), a third acquisition unit (14), a generation unit (21), and an output unit ( 12). A 1st acquisition part (12) acquires the track record value of the output electric power (P1) of the electric power generation system (100) which can output the electric power generated to the load (105) and the electric power grid | system (104). A 2nd acquisition part (13) acquires the track record value of the reverse power flow (P2) reverse-flowed by an electric power grid | system (104). The third acquisition unit (14) acquires the actual value of the power consumption (P3) of the load (105). A production | generation part (21) produces | generates the command value (CMD) of output electric power (P1). The output unit (12) outputs a command value (CMD) to the power generation system (100). The generation unit (21) generates a current command value (CMD2) by adding a feedback amount corresponding to the actual value of the reverse flow power (P2) to the previous command value (CMD1). When the previous command value (CMD1) is closer to the actual value of the power consumption (P3) of the load (105) than the actual value of the output power (P1), the generation unit (21) Instead of CMD1), a feedback amount is added to the actual value of output power (P1) to generate the current command value (CMD2).

  According to this aspect, the current command value (CMD2) is obtained by adding the feedback amount to the one closer to the actual value of power consumption (P3) out of the actual value of output power (P1) and the previous command value (CMD1). Can be generated. Therefore, when the actual value of the output power (P1) is brought close to the actual value of the power consumption (P3) in order to make the reverse flow power (P2) zero, the actual value of the output power (P1) is reduced to the power consumption ( The time until control to the actual value of P3) can be shortened. Therefore, it is possible to improve the responsiveness of the reverse flow zero control that makes the reverse flow power (P2) zero.

  In the power generation control system (1) of the sixth aspect, in any one of the first to fifth aspects, there are a plurality of power generation systems (100). A production | generation part (21) produces | generates command value (CMD) about each of several electric power generation system (100). The output unit (12) outputs a plurality of command values (CMD) generated by the generation unit (21) corresponding to the plurality of power generation systems (100) to the plurality of power generation systems (100), respectively.

  According to this aspect, the output power (P1) of each of the plurality of power generation systems (100) can be controlled.

  In the power generation control system (1) of the seventh aspect, in any one of the first to fifth aspects, there are a plurality of power generation systems (100). A production | generation part (21) calculates | requires the representative value of output electric power (P1) based on the actual value of the output electric power (P1) in a some electric power generation system (100). The generation unit (21) generates a command value (CMD) common to the plurality of power generation systems (100) using the representative value of the output power (P1) as the actual value of the output power (P1). The output unit (12) outputs the common command value (CMD) generated by the generation unit (21) to the plurality of power generation systems (100).

  According to this aspect, since the generation unit (21) generates the command value (CMD) common to the plurality of power generation systems (100) using the representative value, the calculation load in the generation unit (21) can be reduced. .

  The power generation control system (1) of the eighth aspect includes a first acquisition unit (12), a second acquisition unit (13), a generation unit (21), and an output unit (12). A 1st acquisition part (12) acquires the track record value of the output electric power (P1) of the electric power generation system (100) which can output the electric power generated to the electric power grid | system (104). A 2nd acquisition part (13) acquires the track record value of the reverse power flow (P2) reverse-flowed by an electric power grid | system (104). A production | generation part (21) produces | generates the command value (CMD) of output electric power (P1). The output unit (12) outputs a command value (CMD) to the power generation system (100). The generation unit (21) performs reverse flow zero control for generating a command value (CMD) so that the reverse flow power (P2) becomes zero. When generating the command value (CMD) at a predetermined number of times from a predetermined timing in the reverse power flow zero control, the generation unit (21) converts the actual value of the reverse power flow (P2) into the actual value of the output power (P1). A command value (CMD) is generated by adding a feedback amount according to. The predetermined timing is at least one of a timing for switching from an increasing period for increasing the output power (P1) to a decreasing period for decreasing the output power (P1) and a timing for switching from the decreasing period to the increasing period.

  According to this aspect, when outputting the command value (CMD) at a predetermined number of times from a predetermined timing, the generation unit (21) adds the feedback amount to the actual value of the output power (P1) and adds the current command value ( CMD2) can be generated. Therefore, when the previous command value (CMD1) deviates from the target value of the output power (P1), the actual value of the output power (P1) is closer to the target value than the previous command value (CMD1). The time until the output power (P1) is controlled to the target value can be shortened. Therefore, it is possible to improve the control response of the output power (P1).

  The program according to the ninth aspect is a program for causing a computer system to operate as the power generation control system (1). The power generation control system (1) outputs a command value (CMD) of the output power (P1) of the power generation system (100) to the power generation system (100) that can output the power generated by the power system (104). The program according to one aspect causes a computer system to execute a first acquisition process, a second acquisition process, a generation process, and an output process. In the first acquisition process, the actual value of the output power (P1) is acquired. In the second acquisition process, the actual value of the reverse flow power (P2) that flows backward to the power system (104) is acquired. In the generation process, a command value (CMD) of the output power (P1) is generated. In the output process, the command value (CMD) is output to the power generation system (100). In the generation process, the current command value (CMD2) is generated by adding a feedback amount corresponding to the actual value of the reverse flow power (P2) to the previous command value (CMD1). In the generation process, the actual value of the output power (P1) is replaced with the previous command value (CMD1) based on the comparison result of comparing the previous command value (CMD1) and the actual value of the output power (P1). The command value (CMD2) for this time is generated by adding the feedback amount.

  According to this aspect, based on the comparison result between the previous command value (CMD1) and the actual value of the output power (P1), feedback to the actual value of the output power (P1) instead of the previous command value (CMD1). The current command value (CMD2) can be generated by adding the amount. Therefore, when the previous command value (CMD1) deviates from the target value of the output power (P1), the actual value of the output power (P1) is closer to the target value than the previous command value (CMD1). The time until the output power (P1) is controlled to the target value can be shortened. Therefore, it is possible to improve the control response of the output power (P1).

  The control method according to the tenth aspect is a control method for controlling the output power (P1) of the power generation system (100) capable of outputting the power generated by the power system (104). The control method according to one aspect includes a first acquisition process, a second acquisition process, a generation process, and an output process. In the first acquisition process, the actual value of the output power (P1) is acquired. In the second acquisition process, the actual value of the reverse flow power (P2) that flows backward to the power system (104) is acquired. In the generation process, a command value (CMD) of the output power (P1) is generated. In the output process, the command value (CMD) is output to the power generation system (100). In the generation process, the current command value (CMD2) is generated by adding a feedback amount corresponding to the actual value of the reverse flow power (P2) to the previous command value (CMD1). In the generation process, the actual value of the output power (P1) is replaced with the previous command value (CMD1) based on the comparison result of comparing the previous command value (CMD1) and the actual value of the output power (P1). The command value (CMD2) for this time is generated by adding the feedback amount.

  According to this aspect, based on the comparison result between the previous command value (CMD1) and the actual value of the output power (P1), feedback to the actual value of the output power (P1) instead of the previous command value (CMD1). The current command value (CMD2) can be generated by adding the amount. Therefore, when the previous command value (CMD1) deviates from the target value of the output power (P1), the actual value of the output power (P1) is closer to the target value than the previous command value (CMD1). The time until the output power (P1) is controlled to the target value can be shortened. Therefore, it is possible to improve the control response of the output power (P1).

  About the structure which concerns on a 2nd-4th aspect, it is not an essential structure for the electric power generation control system which concerns on a 1st aspect, and can be abbreviate | omitted suitably. The configurations according to the sixth to seventh aspects are not essential to the power generation control system according to the first to fifth aspects, and can be omitted as appropriate.

DESCRIPTION OF SYMBOLS 1 Power generation control system 2 Control apparatus 10 Control part 11 1st communication part 12 2nd communication part (1st acquisition part, output part)
13 Second Acquisition Unit 14 Third Acquisition Unit 21 Generation Unit 100 Power Generation System 101 Server Device 102 Power Conditioner 103 Distributed Power Supply 104 Power System 105 Load

Claims (10)

A first acquisition unit that acquires the actual value of the output power of the power generation system capable of outputting the power generated in the power system;
A second acquisition unit for acquiring actual values of reverse flow power flowing backward to the power system;
A generator for generating a command value of the output power;
An output unit for outputting the command value to the power generation system,
The generation unit generates a current command value by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value,
The generation unit adds the feedback amount to the actual value of the output power instead of the previous command value based on a comparison result of comparing the magnitude of the previous command value and the actual value of the output power. Power generation control system that generates the current command value. The generation unit sets the feedback amount to a negative value when the actual value of the reverse flow power is positive, and sets the feedback amount to a positive value when the actual value of the reverse flow power is negative. The power generation control system described in 1. When the feedback amount is a negative value and the actual output power value is smaller than the previous command value, the generation unit replaces the feedback amount with the actual output power value instead of the previous command value. The power generation control system according to claim 2, wherein the current command value is generated. When the feedback amount is a positive value and the actual value of the output power is larger than the previous command value, the generation unit replaces the feedback amount with the actual value of the output power instead of the previous command value. The power generation control system according to claim 2, wherein the current command value is generated. A first acquisition unit that acquires the actual value of the output power of the power generation system capable of outputting the power generated in the load and the power system;
A second acquisition unit for acquiring actual values of reverse flow power flowing backward to the power system;
A third acquisition unit that acquires the actual value of the power consumption of the load;
A generator for generating a command value of the output power;
An output unit for outputting the command value to the power generation system,
The generation unit generates a current command value by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value,
When the actual value of the output power is closer to the actual value of power consumption of the load than the previous command value, the generating unit replaces the previous command value with the actual value of the output power. A power generation control system that adds the feedback amount and generates the current command value. There are a plurality of the power generation systems,
The generation unit generates the command value for each of the plurality of power generation systems,
The power generation according to any one of claims 1 to 5, wherein the output unit outputs the plurality of command values generated by the generation unit corresponding to the plurality of power generation systems, to the plurality of power generation systems, respectively. Control system. There are a plurality of the power generation systems,
The generation unit obtains a representative value of the output power based on the actual value of the output power in the plurality of power generation systems,
The generating unit generates the command value common to the plurality of power generation systems, using a representative value of the output power as the actual value of the output power,
The power generation control system according to claim 1, wherein the output unit outputs the common command value generated by the generation unit to the plurality of power generation systems. A first acquisition unit that acquires the actual value of the output power of the power generation system capable of outputting the power generated in the power system;
A second acquisition unit for acquiring actual values of reverse flow power flowing backward to the power system;
A generator for generating a command value of the output power;
An output unit for outputting the command value to the power generation system,
The generation unit performs a reverse flow zero control for generating the command value so that the reverse flow power becomes zero,
The generating unit adds the feedback amount corresponding to the actual value of the reverse power flow to the actual value of the output power when the command value is generated at a predetermined number of times from a predetermined timing in the reverse power zero control. Generating the command value;
The power generation control system, wherein the predetermined timing is at least one of a timing of switching from an increasing period in which the output power is increased to a decreasing period in which the output power is decreased, and a timing of switching from the decreasing period to the increasing period. A program for operating a computer system as a power generation control system that outputs a command value of output power of the power generation system to a power generation system capable of outputting power generated in a power system,
Computer system,
A first acquisition process for acquiring the actual value of the output power;
A second acquisition process for acquiring the actual value of the reverse flow power flowing backward to the power system;
Generation processing for generating a command value of the output power;
An output process for outputting the command value to the power generation system; and
In the generation process, the current command value is generated by adding a feedback amount corresponding to the actual value of the reverse power flow to the previous command value,
In the generation process, the feedback amount is added to the actual value of the output power instead of the previous command value based on a comparison result comparing the magnitude of the previous command value and the actual value of the output power. Program that generates the current command value. A control method for controlling output power of a power generation system capable of outputting power generated by an electric power system,
A first acquisition process for acquiring the actual value of the output power;
A second acquisition process for acquiring the actual value of the reverse flow power flowing backward to the power system;
Generation processing for generating a command value of the output power;
Output processing for outputting the command value to the power generation system,
In the generation process, the current command value is generated by adding a feedback amount corresponding to the actual value of the reverse flow power to the previous command value,
In the generation process, the feedback amount is added to the actual value of the output power instead of the previous command value based on a comparison result comparing the magnitudes of the previous command value and the actual value of the output power. Control method for generating the current command value.

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