JP6750472B2 - Information processing apparatus, information processing system, information processing program, and information processing method - Google Patents

Description

The present invention relates to an information processing device, an information processing system, an information processing program, and an information processing method.

In recent solar power generation, when the amount of power generation exceeds demand, the output of surplus power is suppressed and discarded, but when there is consumption (load), surplus power may be used. There is a purchase system.

Therefore, conventionally, in order to effectively utilize the generated electric power, the amount of power generated by sunlight and the amount of load are periodically measured, and when the amount of power generation exceeds the amount of load, the power storage means A technique is known in which a charge amount is controlled to increase a load amount and surplus power is stored.

JP, 2008-154334, A JP, 2013-99156, A

In the above-mentioned conventional technique, the load amount and the output amount of generated electric power are controlled based on the result at the time of measurement, so that it is not possible to follow the changes in the load amount and the generated amount until the next control time.

Further, for example, even when predicting a change in the amount of power generation or the amount of load until the next control point to control the amount of load and the amount of output, consider the operating characteristics of the PCS (Power Conditioning System) that suppresses the output of power. If this is not done, the power generated may not be effectively consumed because the power is discarded or extra power is purchased.

In one aspect, the present invention is directed to consuming the power generated by photovoltaics.

According to one aspect, information including an output control device that outputs electric power generated by solar power generation to a load, and an information processing device that notifies the output control device of a target value of the output amount of the electric power In the processing system, the information processing device generates operation characteristic information of the output control device that indicates a change in the output amount according to a change in the target value, and stores it in a storage unit. An output amount control unit that determines a target value to be notified at the time based on the predicted value of the power generation amount of the electric power and the load amount of the load after a lapse of a predetermined time from a certain time, and the operation characteristic information, and A load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information.

Each of the above-described units may be a computer-readable storage medium that stores a method for causing a computer to execute the above-described units as a procedure and a program.

It is possible to consume the electric power generated by solar power generation.

It is a figure explaining the solar power generation control system of 1st embodiment. It is a figure explaining operation of the solar power generation system of a first embodiment. It is a figure which shows an example of the hardware constitutions of the information processing apparatus contained in the solar power generation system of 1st embodiment. It is a figure explaining the function of the information processing apparatus of 1st embodiment. It is a figure explaining the operation characteristic table of 1st embodiment. It is a figure which shows an example of the operation characteristic database of 1st embodiment. It is a figure which shows an example of the history database of 1st embodiment. 3 is a flowchart illustrating an operation of the information processing device according to the first embodiment. 6 is a flowchart illustrating a process of an operation characteristic generation unit according to the first embodiment. It is a flow chart explaining processing of an output amount control part of a first embodiment. It is a flow chart explaining processing of a load adjusting part of a first embodiment. It is a 1st figure explaining the adjustment of the output amount and load amount in a 1st comparative example. It is a 2nd figure explaining adjustment of the output amount and load amount in a 1st comparative example. It is a 3rd figure explaining the adjustment of the output amount and load amount in a 1st comparative example. It is a 1st figure explaining the adjustment of the output amount and load amount in a 2nd comparative example. It is a 2nd figure explaining adjustment of the output amount and load amount in a 2nd comparative example. It is a 3rd figure explaining adjustment of the output amount and load amount in a 2nd comparative example. It is a 4th figure explaining adjustment of the amount of output and the amount of load in a 2nd comparative example. It is a 1st figure explaining the effect of 1st embodiment. It is a 2nd figure explaining the effect of 1st embodiment. It is a 3rd figure explaining the effect of 1st embodiment. It is a 4th figure explaining the effect of 1st embodiment. It is a figure explaining the function of the information processor of a second embodiment. It is a figure explaining operation characteristic information of a second embodiment. 9 is a flowchart illustrating an operation of the information processing device according to the second embodiment. It is a figure explaining the process of the timing determination part of 2nd embodiment.

(First embodiment)
The first embodiment will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a photovoltaic power generation control system according to the first embodiment.

The photovoltaic power generation control system 100 of this embodiment includes a server 200 and a photovoltaic power generation system 300 that performs photovoltaic power generation. In addition, in the example of FIG. 1, the solar power generation control system 100 includes one solar power generation system 300, but the number is not limited to this. The solar power generation control system 100 may include a plurality of solar power generation systems 300.

The server 200 of the present embodiment notifies the photovoltaic power generation system 300 of an output amount instruction value indicating the amount of electric power output by the photovoltaic power generation system 300.

The output amount of the present embodiment indicates the amount of electric power output from the solar power generation system 300 and supplied to the load. Further, the output amount instruction value of the present embodiment is a value indicating the ratio of the amount of electric power that can be output to the rated output amount of the solar power generation system 300, and is a value notified from the server 200. The rated output amount of the solar power generation system 300 is determined by the specifications of the solar power generation device described later.

For example, in the present embodiment, when the output amount instruction value is 40%, 40% of the rated output amount of the photovoltaic power generation system 300 is output and supplied to the load.

The server 200 of the present embodiment may be installed, for example, in each region, and determines the output amount instruction value according to the weather of the region, the situation of power consumption in the region, and the like, and outputs it to the photovoltaic power generation system 300. Notice.

The solar power generation system 300 includes a solar power generation device 310, a PCS (Power Conditioning System) 320, an information processing device 330, and a storage battery 340.

The solar power generation device 310 is a device that generates power by sunlight, and is, for example, a solar power generation panel or the like. In the following description, the amount of electric power generated by the solar power generation device 310 is referred to as the amount of power generation. The amount of power generation changes depending on, for example, the weather and the amount of sunlight.

The PCS 320 is an output control device that converts the DC power generated by the solar power generation device 310 into AC power and outputs the AC power to the load 350. Further, the PCS 320 of the present embodiment outputs the output amount based on the target value notified from the information processing device 330 to the load 350.

The target value of the present embodiment is a target value of the output amount control value, and is a value designated by the information processing device 330. In addition, the output amount control value of the present embodiment is a ratio of the output amount to the rated output amount of the solar power generation device 310. Details of how to obtain the target value of the output amount control value will be described later.

The information processing device 330 collects the operating characteristic information indicating the operating characteristic of the PCS 320 to generate the operating characteristic database 331, obtains the target value of the output amount control value based on the operating characteristic information, and outputs the output of the photovoltaic power generation system 300. Control power and load.

More specifically, when the information processing device 330 according to the present embodiment acquires the output amount instruction value from the server 200, the information processing device 330 next calculates the output amount instruction value based on the past load amount of the load 350 and the power generation amount of the solar power generation device 310. The predicted value of the load amount and the predicted value of the power generation amount at the time of performing the control are obtained. Then, the information processing device 330 obtains the target value of the output amount control value based on the predicted value of the load amount and the predicted value of the power generation amount, and the operation characteristic information of the PCS 320, and notifies the PCS 320 of the output amount, To control.

Further, the information processing apparatus 330 of the present embodiment adjusts the charge amount (charge speed) of the storage battery 340 according to the change in the output amount based on the predicted value of the load amount and the operation characteristic information of the PCS 320. , Control the amount of load.

When receiving the output amount instruction value from the server 200, the information processing device 330 of the present embodiment controls the above-described output amount and load amount for each predetermined period.

As described above, in this embodiment, the output amount instruction value is received, and the prediction result of the load amount and the power generation amount at the time of performing the next control and the operation characteristic information of the PCS 320 are output from the solar power generation device 310. The output amount of the output power (output amount control value) and the load amount of the photovoltaic power generation system 300 are controlled.

Therefore, according to the present embodiment, it is possible to appropriately control the output amount and the load amount of the electric power generated by the photovoltaic power generation, and to effectively use the generated electric power. In other words, according to this embodiment, it is possible to consume the electric power generated by solar power generation.

Further, in the example of FIG. 1, the solar power generation system 300 includes the information processing device 330, the PCS 320, the solar power generation device 310, and the storage battery 340, but the present invention is not limited to this. The solar power generation system 300 may include an information processing system including the PCS 320 and the information processing device 330.

Next, the operation of the photovoltaic power generation system 300 will be described with reference to FIG. FIG. 2 is a diagram illustrating the operation of the solar power generation system according to the first embodiment.

FIG. 2 shows an example in which a house provided with the solar power generation device 310 is used as a load 350. In general, the purchase of surplus power in solar power, power of self-consumption amount consumed by the load P _L of the load 350 is not limited.

Therefore, in the solar power generation system 300, in addition to the control for adjusting the amount of power generated by the solar power generation device 310 to be the value indicated by the output amount instruction value (0 to 100%), the reverse power flow at the linkage point C is The control is performed so that it becomes zero.

In other words, in the present embodiment, when the output amount instruction value is set, control for adjusting the output amount control value and the load amount is performed so that the difference between the power generation amount and the output amount becomes zero.

The control of purchasing the surplus power described above is not limited to the case where the load 350 is a house, for example. Regarding the control of purchasing the surplus power, the same control is performed regardless of the connection voltage at the link point, the link category, the installed capacity, and the like.

Specifically, in the solar power generation system 300, when the reverse power flow value at the linkage point C is P _R and the output amount value from the solar power generation is P _G , when P _R >0, , The output amount P _G is reduced to the output upper limit value. The output upper limit value indicates the output amount determined by the output amount instruction value. For example, when the output amount instruction value is 40%, the output upper limit value is 40% of the rated output amount of the photovoltaic power generation system 300.

Further, in the solar power generation system 300, when P _R ≦0, the output amount P _G supplied to the load is increased until P _R =0.

In the solar power generation system 300 of the present embodiment, the control to bring the reverse power flow close to 0 as described above suppresses the discard of surplus power and the occurrence of unnecessary power purchase.

Below, the photovoltaic power generation system 300 of this embodiment is further demonstrated. FIG. 3 is a diagram illustrating an example of a hardware configuration of an information processing device included in the solar power generation system according to the first embodiment.

The information processing device 330 of the present embodiment includes an input device 31, an output device 32, a drive device 33, an auxiliary storage device 34, a memory device 35, an arithmetic processing device 36, and an interface device 37, which are mutually connected by a bus B. Including.

The input device 31 inputs various kinds of information. The output device 32 outputs various information. The interface device 37 includes a modem, a LAN card, etc., and is used to connect to a network.

The information processing program is at least a part of various programs that control the information processing device 330. The information processing program is provided, for example, by distributing the storage medium 38 or downloading from the network. The storage medium 38 in which the information processing program is recorded is a storage medium such as a CD-ROM, a flexible disk or a magneto-optical disk which records information optically, electrically or magnetically, or information such as a ROM or a flash memory. It is possible to use various types of storage media such as a semiconductor memory that electrically records the data.

Further, when the storage medium 38 recording the information processing program is set in the drive device 33, the information processing program is installed in the auxiliary storage device 34 from the storage medium 38 via the drive device 33. The information processing program downloaded from the network is installed in the auxiliary storage device 34 via the interface device 37.

The auxiliary storage device 34 stores the installed information processing program and also stores necessary files, data, and the like. The memory device 35 reads and stores the information processing program from the auxiliary storage device 34 when the computer is started. Then, the arithmetic processing unit 36 realizes various processes as described later according to the information processing program stored in the memory unit 35.

FIG. 4 is a diagram illustrating the functions of the information processing apparatus according to the first embodiment.

Here, prior to the description of the function of the information processing device 330, the PCS 320 of this embodiment will be described.

The PCS 320 of the present embodiment measures the amount of power generation in the solar power generation device 310 when converting the DC power generated by the solar power generation device 310 into AC power. Further, the PCS 320 measures an output amount when supplying electric power to the load 350. Therefore, the PCS 320 can calculate the actual output amount control value from the ratio between the measured output amount and the output rating of the solar power generation device 310.

Upon receiving the notification of the target value of the output amount control value from the information processing device 330, the PCS 320 controls the output amount so that the ratio of the output amount to the output rating of the solar power generation device 310 becomes the target value. In other words, when the target value of the output amount control value is notified from the information processing device 330, the PCS 320 controls the output amount so that the output amount control value calculated from the actual measurement value approaches the target value.

The information processing device 330 of this embodiment is, for example, a HEMS (Home Energy Management System). Each unit of the information processing device 330 described below is realized by the arithmetic processing device 36 reading and executing a program stored in the memory device 35 or the like.

The information processing device 330 of the present embodiment includes an operation characteristic database 331, a history database 332, a data collection unit 333, an operation characteristic generation unit 334, a prediction unit 335, an output amount control unit 336, and a load amount adjustment unit 337.

The operation characteristic database 331 stores operation characteristic information indicating the operation characteristic of the PCS 320. The history database 332 stores the past load amount and the power generation amount by the solar power generation device 310.

The load amount in the present embodiment is a value measured by the smart meter 400 connected to the solar power generation system 300. In this embodiment, the load amount is given by the following expression (1).

Load amount=power supplied to load 350-power generation amount+power of storage battery 340 (1)
Details of each database of this embodiment will be described later.

The data collection unit 333 of this embodiment collects data for generating the history database 332. Specifically, the data collection unit 333 periodically collects the load amount measured by the smart meter 400 and the power generation amount measured by the PCS 320, associates the load amount with the power generation amount, and stores the history database. It is stored in 332. At this time, the load amount and the power generation amount are stored in association with the information indicating the date and time when they were collected.

Further, the data collection unit 333 of the present embodiment collects the output amount control value when the operation characteristic generation unit 334 generates the operation characteristic information.

In the present embodiment, the process of calculating the output amount control value may be performed by the PCS 320. In this case, the data collection unit 333 may collect the output amount control value calculated from the PCS 320. Further, in the present embodiment, the process of calculating the output amount control value may be performed by the data collection unit 333. In this case, the data collection unit 333 may collect the rated output of the solar power generation device 310 and the measured value of the output amount from the PCS 320 and calculate the output amount control value.

The operation characteristic generation unit 334 has an operation characteristic table 338 and generates the operation characteristic database 331.

Specifically, the operation characteristic generation unit 334 changes the target value of the output amount control value by referring to the operation characteristic table 338. Next, the operation characteristic generation unit 334 collects the output amount control value calculated from the output amount measured after the change of the target value at predetermined intervals by the data collection unit 333 at predetermined intervals. Then, the operation characteristic generation unit 334 associates the target value before and after the change with the output amount control value calculated at every predetermined interval, and stores them in the operation characteristic database 331 as the operation characteristic information. Details of the operation characteristic generation unit 334 will be described later.

The predicting unit 335 refers to the history database 332 when controlling the load amount and the output amount, and calculates the respective predicted values of the load amount and the power generation amount when performing the next control.

The output amount control unit 336 obtains the target value of the output amount control value based on the predicted values of the load amount and the power generation amount calculated by the prediction unit 335 and the operation characteristic information, and notifies the PCS 320 of the target value.

The load amount adjustment unit 337 adjusts the load amount by adjusting the charge amount of the storage battery 340 based on the predicted value of the load amount calculated by the prediction unit 335 and the operation characteristic information.

In the following description, the target value of the output amount control value determined by the information processing device 330 is simply referred to as the target value. Further, in the following description, the output amount control value calculated from the output rating of the solar power generation device 310 and the measured value of the output amount measured by the PCS 320 is referred to as an output amount control value based on the measured value.

Next, each database included in the information processing device 330 will be described with reference to FIGS. 5 and 6.

FIG. 5 is a diagram for explaining the operation characteristic table of the first embodiment. In this embodiment, the operation characteristic generation unit 334 holds an operation characteristic table 338.

As shown in FIG. 5, the operation characteristic table 338 stores a set of a first target value which is a target value before change and a second target value which is a target value after change. In the present embodiment, for the set in the operation characteristic table 338, the output amount control value based on the measured value is calculated at a predetermined interval for a predetermined time, and the data collecting unit 333 collects the output amount control value.

In the example of FIG. 5, the operation characteristic table 338 sets the target value before change to 0, 20, 40,..., 100[%], and sets the changed target value for each value. have. For example, the target value before the change is “40%”, the target value after the change is “20%”, the target value before the change is “40%”, and the target value after the change is “60%”. The group has a target value before the change of “40%” and the target value after the change of “80%”.

For example, in the set of the target value “40%” before the change and the target value “80%” after the change, when the predetermined time is 5 minutes and the predetermined interval is 1 minute, the output amount control value based on the measured value is , As shown in the graph 51.

From this graph 51, it is understood that in the PCS 320, when the target value is changed from 40% to 80% at the time t, the output amount control value based on the measured value gradually approaches 80%. Then, it is understood that the output amount control value based on the measured value does not reach 80% at time t1 which is five minutes after time t.

In other words, when the target value is set to 80% at time t, the output amount control value based on the measured value does not immediately reach 80% but gradually approaches 80%. The curve indicated by the graph 51 becomes the operating characteristic information of the PCS 320 when the target value is changed from “40%” to “80%”.

The operation characteristic generation unit 334 of this embodiment generates the operation characteristic information of each set as described above and stores it in the operation characteristic database 331.

The predetermined time and the predetermined interval when generating the operation characteristic information may be arbitrary. For example, when the information processing device 330 is set to control the load amount and the output amount every 5 minutes, the predetermined time in each set may be 5 minutes or more.

Further, the information processing device 330 changes the load amount at every predetermined interval in the adjustment of the load amount. Therefore, the predetermined interval may be an interval at which the load amount can be adjusted for each predetermined interval.

Further, in the present embodiment, the operation characteristic information is changed from the time t, which is the current time when the output amount and the load amount are controlled, for each set of target values before and after the change, to the time when the control is next performed. Although the information for the predetermined time until t1 is used, the information is not limited to this. The operation characteristic information includes the operation characteristic information of two or more sections when the predetermined time from the time t at which the output amount and the load amount are controlled to the time t1 at which the next control is performed is one section. It may be.

FIG. 6 is a diagram showing an example of the operation characteristic database of the first embodiment.

The operation characteristic database 331 of this embodiment is provided for each set shown in the operation characteristic table 338. The operation characteristic database 331 has date, time, and the ratio of the output amount to the output rating of the solar power generation device 310 (the output amount control value based on the measured value) as items of information.

The example shown in FIG. 6 is an operation characteristic database of the target value “40%” before the change and the target value “80%” after the change.

The value of the item “date” indicates the date when the corresponding information is generated. The value of the item “time” indicates the time when the value of the output amount is collected by the data collection unit 333. The value of the item “ratio of output amount” indicates the ratio of the collected output value to the output rating of the solar power generation device 310. In other words, the item “ratio of output amount” indicates the output amount control value based on the measured value.

In the following description, the information including the information for identifying the group shown in the operation characteristic table 338 and the value of each item included in the operation characteristic database 331 is referred to as operation characteristic information.

In the example of FIG. 6, when the target value is set to 40 [%] to 80 [%] and the output amount is collected every minute, the output amount control value based on the measured value changes only to 75% in 5 minutes. , 80% is not reached.

In the present embodiment, the operation characteristic database 331 is provided in the information processing device 330, but the present invention is not limited to this. The operation characteristic database 331 may be generated by the operation characteristic generation unit 334 and stored in, for example, a portable storage medium or the like, or may be stored in an external device of the information processing device 330.

Next, the history database 332 of this embodiment will be described with reference to FIG. 7. FIG. 7 is a diagram illustrating an example of the history database according to the first embodiment.

The history database 332 of this embodiment has date, time, power generation amount, and load amount as information items.

The values of the item “date” and the item “time” indicate the date and time when the value of the power generation amount and the value of the load amount were collected. The value of the item “power generation amount” indicates the power generation amount measured by the PCS 320. The value of the item “load amount” indicates the load amount measured by the smart meter 400.

In the following description, in the history database 332, information including the value of each item is called history information.

Next, the processing of the information processing device 330 of this embodiment will be described. FIG. 8 is a flowchart illustrating the operation of the information processing device according to the first embodiment.

When the information processing apparatus 330 according to the present embodiment is activated, the operation characteristic generation unit 334 generates an operation characteristic database (step S801). Details of the process of the operation characteristic generation unit 334 will be described later.

Subsequently, the information processing device 330 determines whether or not the output amount instruction value is received from the server 200 (step S802).

When the output amount instruction value is not accepted in step S802, the information processing device 330 collects data by the data collection unit 333 (step S803), and proceeds to step S807 described below. Note that here, the data collection unit 333 collects the load amount measured by the smart meter 400 and the power generation amount measured by the PCS 320 to generate the history database 332.

When the output amount instruction value is received in step S802, the information processing apparatus 330 causes the prediction unit 335 to refer to the history database 332, and predicts the power generation amount and the load amount predicted value at the time when the next control is performed. And are calculated (step S804).

The calculation of the predicted value by the prediction unit 335 will be described below.

In this embodiment, when the output amount instruction value is accepted, the output amount and the load amount are periodically adjusted so that the reverse power flow becomes zero, and the prediction unit 335 controls the control. The predicted values of the output amount and the load amount at the timing of execution are calculated.

When the prediction unit 335 of the present embodiment receives the output amount instruction value, the prediction unit 335 obtains the time t1 when the control interval has elapsed from the time t when the output amount instruction value is received. This time t1 is a time at which control for adjusting the output amount and the load amount is next performed. For example, when the time t at which the output amount instruction value is received is 9:00 and the control interval is 5 minutes, the time t1 is 9:5. Therefore, the prediction unit 335 predicts the power generation amount and the load amount at 9:05.

For example, when calculating the predicted value of the power generation amount at 9:05, the prediction unit 335 refers to the history database 332, extracts the power generation amount at the same time in the past fixed period, and calculates the average value of the extracted power generation amounts. , The predicted value of power generation. Specifically, for example, the prediction unit 335 extracts the power generation amount at 9:5 in the past two weeks and sets the average value of the power generation amount at 9:5 for two weeks as the predicted value.

In addition, when the history information in the history database 332 includes information indicating the weather, the average value of the power generation amount at the same time may be calculated for the history information in which the weather when the control is performed and the weather match. ..

Next, how to calculate the predicted value of the load amount will be described. The method of calculating the predicted value of the load amount is the same as that of the power generation amount. The prediction unit 335 refers to the history database 332, extracts the load amount at the same time in the past fixed period, and sets the average value of the extracted load amounts as the predicted value of the load amount.

When the predicted values of the power generation amount and the load amount are calculated, the information processing device 330 controls the output amount by referring to the operation characteristic database 331 by the output amount control unit 336 (step S805). Subsequently, the information processing apparatus 330 causes the load amount adjusting unit 337 to adjust the load amount (step S806). Details of the processing of the output amount control unit 336 and the load amount control unit 337 will be described later.

Subsequently, the information processing device 330 determines whether or not an operation end instruction has been received (step S807). The instruction to end the operation is, for example, when the power generation by the solar power generation device 310 is stopped or when the information processing device 330 is powered off.

If the end instruction is not received in step S807, the information processing device 330 returns to step S802. When the end instruction is received in step S807, the information processing device 330 ends the process.

Note that, in the example of FIG. 8, the process of generating the operation characteristic database 331, the process of controlling the output amount, and the process of adjusting the load are executed continuously, but the present invention is not limited to this. The process of generating the operation characteristic database 331 (the process of step S801) may be performed independently of the process of controlling the output amount and the load amount.

Further, the process of collecting history information (the process of step S803) by the data collection unit 333 may be performed independently of the process of controlling the output amount and the load amount.

Next, with reference to FIG. 9, the processing of the operation characteristic generation unit 334 will be described. FIG. 9 is a flowchart illustrating the process of the operation characteristic generation unit according to the first embodiment. FIG. 9 shows details of the processing in step S801 of FIG.

In the information processing device 330 of this embodiment, the operation characteristic generation unit 334 refers to the operation characteristic table 338 (step S901). Subsequently, the operation characteristic generation unit 334 sets the target value X before the change in the PCS 320 (step S902). At this time, the operation characteristic generation unit 334 may set, for example, the smallest target value before change in the operation characteristic table 338.

Subsequently, the operation characteristic generation unit 334 sets the changed target value Y in the PCS 320 (step S903). Subsequently, the information processing device 330 causes the data collection unit 333 to read the output amount control value based on the measured value from the PCS 320 (step S904).

In the present embodiment, the operation characteristic generation unit 334 reads the output amount control value based on the measured value from the PCS 320 at predetermined intervals for a predetermined time that is determined in advance. For example, when the predetermined time is 5 minutes and the predetermined interval is 1 minute, the operation characteristic generation unit 334 reads the output amount control value based on the measured value from the PCS 320 five times per minute.

Then, the operation characteristic generation unit 334 associates the set of the target value X before the change and the target value Y after the change, the output amount control value based on the measurement value collected from the PCS 32, and the date and time with each other to perform the operation. The characteristic information is stored in the operation characteristic database 331 (step S905).

Then, the operation characteristic generation unit 334 determines whether or not all the target values Y after the change associated with the target value X before the change are processed in the operation characteristic table 338 (step S906). ).

If all the changed target values Y have not been processed in step S906, the operation characteristic generation unit 334 sets the next target value Y in the PCS 320 from the operation characteristic table 338 (step S907). Return to S904.

When all the target values Y after the change are processed in step S906, the operation characteristic generation unit 334 determines whether or not all the target values X in the operation characteristic table 338 have been processed ( Step S908).

If processing has not been performed for all target values X in step S908, the operation characteristic generation unit 334 sets the next target value X in the PCS 320 (step S909) and returns to step S903.

In step S908, if the processing has been performed for all target values X, the operation characteristic generation unit 334 ends the processing of creating the operation characteristic database 331, and proceeds to step S802 in FIG.

Next, the processing of the output amount control unit 336 of this embodiment will be described with reference to FIG. FIG. 10 is a flowchart illustrating the process of the output amount control unit of the first embodiment. FIG. 10 shows details of the process of step S805 of FIG.

The output amount control unit 336 of the present embodiment determines whether the output amount instruction value notified from the server 200 is 100% (step S1001). In step S1001, when the output amount instruction value is 100%, it indicates that all the power generated by the solar power generation device 310 is output, and thus the output amount control is unnecessary. Therefore, the output amount control unit 336 ends the process and proceeds to step S806 in FIG.

When the output amount instruction value is not 100% in step S1001, the output amount control unit 336 reads the predicted value of the load amount at time t1 calculated in step S804 of FIG. 8 (step S1002). Subsequently, the output amount control unit 336 reads the predicted value of the power generation amount at time t1 calculated in step S804 of FIG. 8 (step S1003).

Subsequently, the output amount control unit 336 calculates the target value at time t (step S1004). In the present embodiment, the output amount control unit 336 obtains the target value at time t by the following equation (2).

Target value of output amount control value at time t=
100×(predicted value of load amount at time t1+predicted value of output amount at time t1)/rated output (2)
Time t1 in Expression (2) indicates the time when the output amount and the load amount are controlled next to the time t.

Subsequently, the output amount control unit 336 determines whether or not the calculated target value at time t is equal to or less than the output amount instruction value (step S1005).

In step S1005, if the target value at time t is less than or equal to the output amount instruction value, the output amount control unit 336 sets the output amount instruction value as the target value at time t (step S1006), and proceeds to step S1009 described later. move on.

In step S1005, if the target value at time t is not less than or equal to the output amount instruction value, that is, if the target value is greater than the output amount instruction value, the output amount control unit 336 determines whether the target value is 100% or more. The determination is made (step S1007).

When the target value is 100% or more in step S1007, the output amount control unit 336 sets the target value at time t to 100% (step S1008), and proceeds to step S1009 described later.

In step S1007, when the target value is not 100% or more, that is, when the target value is less than 100%, the output amount control unit 336 refers to the operation characteristic database 331. Then, when the output amount instruction value is the target value X before the change in the operation characteristic information, the output amount control unit 336 determines that the output amount control value based on the measured value at time t1 is the target value calculated in step S1004. The group closest to is selected (step S1009). The process of step S1009 will be described in more detail in FIG. 19 described later.

Subsequently, the output amount control unit 336 sets the changed target value Y in the selected set in the PCS 320 (step S1010), ends the output amount control process, and proceeds to step S806 in FIG.

As described above, according to this embodiment, the target value can be set in accordance with the change in the power generation amount after the target value is changed by referring to the operation characteristic database 331 of the PCS 320 created in advance. Therefore, according to this embodiment, the output amount can be appropriately controlled according to the actual operating characteristics of the PCS 320.

Next, with reference to FIG. 11, the processing of the load amount adjustment unit 337 of the present embodiment will be described. FIG. 11 is a flowchart illustrating the process of the load amount adjusting unit according to the first embodiment. FIG. 11 shows details of the processing in step S806 of FIG.

The load amount adjustment unit 337 of the present embodiment adjusts the load amount at every predetermined interval at which the operation characteristic generation unit 334 measures the output amount when generating the operation characteristic.

That is, in this embodiment, when the operation characteristic information is generated, if the predetermined time is 5 minutes and the predetermined interval is 1 minute, the load amount adjustment unit 337 adjusts the load amount every 1 minute. In this embodiment, as described above, the reverse flow can be brought close to 0 by adjusting the load amount according to the change of the output amount control value based on the measured value.

The information processing apparatus 330 of the present embodiment uses the load amount adjustment unit 337 to calculate the amount of charge to be increased for the storage battery 340 (step S1101). The amount of charge to be increased is represented by the following equation (3).

Charge amount to be increased=predicted value of load amount at time (t+Δt)−output amount at time (t+Δt) (3)
In Expression (3), Δt represents one minute of the predetermined interval when the operation characteristic is generated. Further, in Expression (3), the predicted value of the load amount at the time (t+Δt) is a predicted value calculated by the prediction unit 335, and the same method as the calculation of the predicted value of the load amount in step S804 of FIG. Is calculated.

Further, in Expression (3), the output amount at time (t+Δt) is a value corresponding to the output amount control value based on the measured value in the operation characteristic database 331. More specifically, the output amount at time (t+Δt) is the output amount control value based on the measured value at time (t+Δt) in the curve of the operating characteristics of the set selected by the output amount control unit 336, and the sunlight. It is calculated from the rated output of the power generation device 310.

Subsequently, the load amount adjustment unit 337 increases the charge amount for the storage battery 340 by the amount calculated in step S1101 (step S1102). Specifically, the load amount adjustment unit 337 may increase the value of the charging current supplied to the storage battery 340.

Subsequently, when the predetermined interval Δt has elapsed (step S1103), the load amount adjustment unit 337 determines whether a predetermined time has elapsed (step S1104). If the predetermined time has not elapsed in step S1104, the load amount adjustment unit 337 returns to step S1101.

When the predetermined time has elapsed in step S1104, the load amount adjustment unit 337 ends the adjustment of the load amount and proceeds to step S807 in FIG.

As described above, according to the present embodiment, the load is changed according to the change in the output amount control value indicated by the operation characteristic of the PCS 320 from the current time t to the time t1 when the next control is performed. Also change the amount. Therefore, according to the present embodiment, the load amount is adjusted according to the change in the output amount.

The effects of this embodiment will be described below with reference to FIGS. 12 to 22. First, a first comparative example and a second comparative example in the case where the present embodiment is not applied will be described.

The first comparative example is an example in which, when the output amount is controlled, the output amount and the load amount at that time are measured, and the output amount is controlled using the value of the measurement result.

FIG. 12 is a first diagram illustrating the adjustment of the output amount and the load amount in the first comparative example. In FIG. 12, a curve S1 represents the electric power (power generation amount) generated by the solar power generation device 310. Further, in FIG. 12, a curve P indicates the load amount read from the smart meter 400. The curve P indicates the load amount that is not controlled according to the output amount.

Further, in the example of FIG. 12, the target value before the change is set to 40%, and the output amount and the load amount are adjusted at each of time t and time t1.

In the example of FIG. 12, since the load amount P is larger than the target value at the time t, the target value of the output amount control value is changed to 50% according to the load amount P at the time t.

FIG. 13 is a second diagram illustrating the adjustment of the output amount and the load amount in the first comparative example.

FIG. 13 shows a state in which the target value is changed from 40% to 50%. In this case, the output amount is about the same as the load amount P at time t. However, since the output amount at time t is smaller than the power generation amount S1, in the first comparative example, the load amount P is increased to set the load amount Pa in order to set the reverse power flow to 0 from the measurement result at time t. ..

FIG. 14 is a third diagram illustrating the adjustment of the output amount and the load amount in the first comparative example.

As shown in FIG. 14, in the first comparative example, by changing the target value of the output amount control value to 50% and setting the load amount to Pa, extra power purchase or discard is performed at time t. No electricity is generated.

However, in the first comparative example, changes in the output amount and the load amount from the time t to the time t1 when the output amount and the load amount are controlled next time are not considered based on the measurement result at the time t. Therefore, the power amount shown in the region R1 after the time t is avoided from being discarded, but the power amount shown in the region R2 is discarded. The amount of electric power shown in the region R2 is an amount of electric power that exceeds the output amount corresponding to the target value 50% of the amount of electric power generated by the solar power generation device 310.

As described above, in this first comparative example, it is understood that electric power that cannot be discarded is generated by power generation.

Next, a second comparative example will be described. The second comparative example is an example of controlling the output amount and the load amount at the time t using the predicted values of the power generation amount and the load amount at the time t1.

FIG. 15 is a first diagram illustrating the adjustment of the output amount and the load amount in the second comparative example. In the example of FIG. 15, when the output amount and the load amount are controlled at the time t, the predicted values of the power generation amount and the load amount at the time t1 when the control is performed next are referred to.

In the example of FIG. 15, the power generation amount at time t1 is predicted, and the target value is changed from 40% to 80% at time t in accordance with the predicted value.

FIG. 16 is a second diagram illustrating the adjustment of the output amount and the load amount in the second comparative example. In the second comparative example, in the control of the load amount from time t to time t1, the charging/discharging speed of the storage battery is determined so that the load amount becomes the predicted value at time t1. By this control, the load amount P increases as the amount of power generation increases, as indicated by the load amount Pb.

However, the second comparative example does not consider the operating characteristics of the PCS 320 that controls the output amount.

FIG. 17 is a third diagram illustrating the adjustment of the output amount and the load amount in the second comparative example. FIG. 17A is a diagram for explaining an ideal change in the output amount, and FIG. 17B is a diagram for explaining a change in the output amount based on the operating characteristics of the PCS. A solid line C1 in FIG. 17A and a solid line in FIG. 17B show changes in the output amount.

When the target value of the output amount control value is changed, the output amount of electric power output from the PCS 320 to the load 350 also changes at the changed timing, as indicated by the solid line C1 shown in FIG. Is ideal.

However, the actual output amount of electric power changes as shown by the solid line C2 in FIG. 17B due to the operating characteristics of the PCS 320. Therefore, in the second comparative example, even if the target value at time t is set based on the predicted value of the power generation amount at time t1, the output amount control value based on the measured value at time t1 is different from the set target value. It becomes a value. Therefore, in the second comparative example, when the load amount is increased based on the predicted value of the power generation amount at time t1, the load amount becomes larger than the actual output amount, and power purchase will occur.

FIG. 18 is a fourth diagram illustrating the adjustment of the output amount and the load amount in the second comparative example. In the second comparative example, it is assumed that the load amount P is changed to the load amount Pb based on the predicted value of the power generation amount at time t1. In this case, since the actual output amount changes as shown by the solid line C2, the load amount Pb becomes larger than the output amount.

Therefore, in the second comparative example, the electric power shown in the region R3 is purchased from the power supply source in accordance with the load amount Pb, and useless power purchase occurs.

On the other hand, in the present embodiment, the operating characteristic information indicating the operating characteristic of the PCS 320 is acquired in advance, and the output amount control value is set so that the predicted value of the power generation amount at the time t1 and the output amount are closest to each other. Select the target value. Further, in this embodiment, the load amount is changed based on the output amount according to the operating characteristics of the PCS 320.

FIG. 19 is a first diagram illustrating the effect of the first embodiment. In FIG. 19, the target value at time t is set to 40%.

In the present embodiment, when the control for adjusting the output amount and the load amount is performed at this time t, the prediction unit 335 calculates the predicted value for each of the power generation amount and the load amount at the time t1 when the control is performed next. ..

Then, the output amount control unit 336 calculates the changed target value at the time t using the predicted values of the power generation amount and the load amount. Here, an example is shown in which the calculated target value after change is 80%.

Next, the output amount control unit 336 of the present embodiment refers to the operation characteristic database 331, the target value before change is 40%, and the output amount control value based on the measured value after a predetermined time has elapsed is calculated. The group that is closest to the changed target value of 80% is specified.

Here, a case where the time t is 9:00 and the predetermined time is 5 minutes will be described. In this case, the operation characteristic database 331 refers to the operation characteristic information of a set in which the target value before change is 40% and the target value after change is 80% (see FIG. 6 ). In this case, when the target value is changed from 40% to 80% at 9:00 at time t, the output amount control value based on the measured value at 9:5 at time t1 is 75%. In FIG. 19, the operating characteristic information of the set in which the target value before change is 40% and the target value after change is 80% is shown as a curve C11.

Therefore, the output amount control unit 336 of the present embodiment refers to the operation characteristic database 331, the target value before change is 40%, and the output amount control based on the measured value at 9:5 which is the time t1. The pair whose value is closest to 80% is identified.

For example, in FIG. 19, the curve C12 shows the operation characteristic information of the set in which the target value before the change is 40% and the target value after the change is 60%, and the output amount control based on the measured value at the time t1 of this set is shown. It can be seen that the values are even lower than 75%.

Further, in FIG. 19, the operation characteristic information of the set in which the target value before the change is 40% and the target value after the change is 100% is shown by a curve C13, and the output amount control based on the measured value at time t1 of this set is shown. It can be seen that the value is closest to 80%.

Therefore, the output amount control unit 336 of the present embodiment sets 100% as the changed target value for the PCS 320. As described above, in the present embodiment, when the target value is changed at time t, the changed target value is set in accordance with the change in the output amount control value based on the operation characteristic of the PCS 320 after the target value is changed. To do.

In the present embodiment, by setting the changed target value in this way, the difference between the predicted value of the power generation amount at the time t1 and the output amount actually output from the PCS 320 can be reduced, and the power generation is performed. It is possible to effectively utilize the generated power.

FIG. 20 is a second diagram illustrating the effect of the first embodiment. In the present embodiment, the load amount adjusting unit 337 adjusts the load amount in accordance with the operation characteristic information indicated by the curve C13. A predicted value of the load amount at t+Δt is obtained. Further, the load amount adjustment unit 337 refers to the operation characteristic information indicating the curve C13, and acquires the output amount control value at time t+Δt. Then, the load amount adjustment unit 337 calculates the output amount at the time t+Δt from the rated output amount of the solar power generation system 300 and the output amount control value at the time t+Δt.

Then, the increase amount of the load amount from the time t to the time t+Δt is calculated from the output amount at time t+Δt and the predicted value of the load amount, and the charge amount to the storage battery 340 is increased by the calculated increase amount.

Next, the load amount adjustment unit 337 performs the same processing at time t+2Δt when the predetermined interval Δt has further elapsed from time t+Δt. As a result, the load amount increases like the load amount Pa1.

In this way, the load amount adjustment unit 337 of the present embodiment increases the charge amount of the storage battery 340 by the increase amount of the load amount at each predetermined interval Δt. In other words, since the load amount adjustment unit 337 of the present embodiment increases the load amount according to the operating characteristics of the PCS 320, the change in the load amount can follow the change in the output amount.

FIG. 21 is a third diagram illustrating the effect of the first embodiment. In the present embodiment, as described above, the change in the load amount can be made to follow the change in the output amount, and the difference between the output amount and the power generation amount can be reduced.

Therefore, in the present embodiment, there is no need to purchase the power corresponding to the region R4 in FIG. The electric power corresponding to the region R4 is the electric power that is insufficient at the time t when the load amount is increased according to the predicted value of the load amount at the time t1, and is the electric power to be purchased from the power supply source. ..

FIG. 22 is a fourth diagram illustrating the effect of the first embodiment. Further, in this embodiment, the output target amount is changed to 100% by changing the changed target value based on the operation characteristic information indicated by the curve C13, compared to the case where the changed target value is set to 80%. Is increased by the amount of electric power corresponding to the region R5.

Therefore, according to this embodiment, the power corresponding to the region R5 can be avoided from being discarded.

As described above, according to the present embodiment, the output amount control value indicating the output amount from the photovoltaic power generation system 300 is adjusted according to the operating characteristics of the PCS 320, and the load amount is also referred to the operating characteristics of the PCS 320. And adjust. Therefore, according to the present embodiment, it is possible to suppress the consumption of generated electric power and the generation of useless power purchase and consume the generated electric power, and it is possible to utilize the electric power generated by solar power generation.

(Second embodiment)
The second embodiment will be described below with reference to the drawings. The second embodiment is different from the first embodiment in that the timing for adjusting the output amount and the load amount is determined. Therefore, in the following description of the second embodiment, only differences from the first embodiment will be described, and those having the same functional configuration as the first embodiment will be described in the first embodiment. The same reference numerals as those used in step 1 are given and the description thereof is omitted.

FIG. 23 is a diagram illustrating the functions of the information processing apparatus according to the second embodiment. The solar power generation system 300A of the present embodiment has an information processing device 330A.

The information processing device 330A includes an operation characteristic database 331A, a history database 332, a data collection unit 333, an operation characteristic generation unit 334A, a prediction unit 335, an output amount control unit 336, a load amount adjustment unit 337, and a timing determination unit 339.

In the operation characteristic database 331A of the present embodiment, when the predetermined time from the time t at which the output amount and the load amount are controlled to the time t1 at which the control is performed next is defined as one section, the change before and after the change is performed. The operation characteristic information for two sections is stored for each set of target values.

The operation characteristic generation unit 334A of the present exemplary embodiment refers to the operation characteristic table 338, generates operation characteristic information for two sections for each set of target values before and after the change, and stores it in the operation characteristic database 331A.

The timing determination unit 339 of the present embodiment refers to the operation characteristic information for two sections, and determines the timing for controlling the output amount and the load amount after the time t.

FIG. 24 is a diagram explaining the operation characteristic information of the second embodiment. As shown in the graph 51A, the operation characteristic information of the present embodiment is information in which output amount control values based on measured values are collected over two sections for each set of target values before and after the change.

In the graph 51A, in the set of the target value "40%" before the change and the target value "80%" after the change, when the predetermined time which is one section is 5 minutes and the predetermined interval is 1 minute, there are two sections. The output amount control value based on the measured value for 10 minutes is included.

In the example of FIG. 24, when the target value is changed from 40% to 80% at the time t, the output amount control value based on the measured value gradually increases, and the time t1 when the control is performed next elapses. , Reaches 80% by the time t2 when control is performed next to time t1.

That is, it can be seen from the graph 51A shown in FIG. 24 that when the target value is changed from 40% to 80% at the time t, the output amount control value based on the measured value does not reach 80% at the time t1.

In the operation characteristic database 331A of the present embodiment, as shown in FIG. 24, the output amount control value based on the measured values for two sections is stored for each set of target values before and after the change.

Next, the operation of the information processing device 330A of the present embodiment will be described with reference to FIG. FIG. 25 is a flowchart illustrating the operation of the information processing device according to the second embodiment.

In the information processing apparatus 330A of the present embodiment, the operation characteristic generation unit 334A generates the operation characteristic information for two sections for each set of the target value before and after the change and stores it in the operation characteristic database 331A (step S2501).

The processes of steps S2502 and S2503 of FIG. 25 are similar to the processes of steps S802 and S803 of FIG.

When the output amount instruction value is received from the server 200 in step S2502, the prediction unit 335 refers to the history database 332, and determines the predicted value of the power generation amount and the predicted value of the load amount at the time when the next control is performed. It is calculated (step S2504). That is, the prediction unit 335 predicts the power generation amount and the load amount at time t2 when the time for two sections has elapsed from time t.

Subsequently, in the information processing device 330A, at the time t2, the output amount control unit 336 refers to the operation characteristic database 331A to control the output amount (step S2505).

At this time, the information processing apparatus 330A of the present embodiment refers to the operation characteristic database 331A, and at time t2, selects and selects a set in which the output amount control value based on the measured value is closest to the changed target value. The target value after the change of the saucer set is selected as the output amount control value.

Subsequently, in the information processing device 330A, the timing determination unit 339 determines the timing for controlling the output amount and the load amount (step S2506). In other words, the timing determination unit 339 determines the timing to change the target value before the change to the target value selected in step S2505 between the time t and the time t1.

Here, the timing determination unit 339 determines the timing at which the difference between the power generation amount and the output amount becomes the smallest when the target value is changed between the time t and the time t1. Details of the processing of the timing determination unit 339 in step S2506 will be described later.

Subsequently, the information processing apparatus 330A causes the load amount adjusting unit 337 to adjust the load amount according to the change in the output amount (step S2507).

The processes of steps S2507 and S2508 of FIG. 25 are the same as steps S806 and S807 of FIG.

Next, the processing of the timing determination unit 339 of this embodiment will be described with reference to FIG. FIG. 26 is a diagram for explaining the processing of the timing determination unit of the second embodiment.

The function S(t) in FIG. 26 shows the amount of power generation at time t, and the function C(t) shows the output amount control value based on the measured value at time t.

In the example of FIG. 26, the target value before change at time t is 40%, the target value before change is 40%, and at time t2, the output amount corresponding to the output amount control value based on the measured value is equal to the output amount. , The target value after the change that is the closest to the predicted value of the power generation amount is 80%.

When the operation characteristic information in which the target value before the change is 40% and the target value after the change is 80% is selected, the timing determination unit 339 of the present embodiment determines which of the time period from the time t to the time t1. If the target value is changed at the timing, it is determined whether the amount of wasted electric power is minimized. Note that the wasted power is, for example, discarded power or power purchased from a power supply source.

Here, in FIG. 26, the change in the output amount control value when the target value before the change is 40% and the target value after the change is 80% is shown as a function C(t), and the change in the power generation amount is shown as a function. Denote by S(t). Further, the time at which the target value is changed between time t and time t1 is time tx.

At this time, the timing determination unit 339 determines the time tx so that the |function C(t)-function S(t)| from the time tx to the time t2 is the smallest. In other words, the timing determination unit 339 determines the timing when the difference between the power generation amount and the output amount becomes the smallest when changing the target value.

In the example of FIG. 26, the timing determination unit 339 determines time tx=time t11. If the target value is changed from 40% to 80% at time t11, for example, rather than changing the target value at time t12 or time t13, the output amount and the power generation amount from the time when the target value is changed to the time t2 are changed. It can be seen that the difference between is small.

As described above, in the present embodiment, the operation characteristic information for two sections is held, and the changed value based on the predicted value of the power generation amount at the time t2, which is the end time of the second section, and the operation characteristic information. Select the target value.

Then, when changing the target value, the target value is changed at the timing when the difference between the output amount and the power generation amount becomes the smallest from the time when the target value is changed to the time t2.

Therefore, according to this embodiment, the target value is changed at a timing when the difference between the output amount and the power generation amount becomes the smallest, without fixing the timing for changing the target value. Therefore, according to the present embodiment, it is possible to suppress the discarding of power and the occurrence of power purchase, and it is possible to effectively consume the generated power.

In the present embodiment, the timing of changing the target value that minimizes the difference between the output amount and the power generation amount for two sections is detected in one section, but the present invention is not limited to this. In the present embodiment, for example, in two sections, the timing of changing the target value in which the difference between the output amount and the power generation amount for three sections is the smallest may be detected. In this case, as the operation characteristic information, the operation characteristic information for three sections is stored in the operation characteristic database 331A.

In each of the above-described embodiments, the electric power generated by the solar power generation device 310 has been described, but the present invention is not limited to this. In this embodiment, instead of the solar power generation device 310, a power generation device using another renewable energy may be used.

In the disclosed technology, the following additional forms are conceivable.
(Appendix 1)
An information processing system including an output control device that outputs electric power generated by solar power generation to a load, and an information processing device that notifies the output control device of a target value of the output amount of the electric power,
The information processing device,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and stores the operation characteristic information in a storage unit;
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time from a certain time, and the operation characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing system comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information.
(Appendix 2)
The operation characteristic generation unit,
During a predetermined time after the first target value is changed to the second target value, the output amount control value indicating the ratio of the output amount to the rated output amount in the photovoltaic power generation is acquired at predetermined intervals at predetermined intervals. ,
The information processing system according to appendix 1, wherein the first target value, the second target value, and the output amount control value are associated with each other and used as the operation characteristic information.
(Appendix 3)
The target value is a target value of the output amount control value,
The output amount control unit,
Of the operating characteristic information stored in the storage unit, the first target value matches the target value at the time, and the output amount indicated by the output amount control value is the most predictive value of the power generation amount. Select the operating characteristic information that is close,
Determining the second target value included in the selected operation characteristic information as the target value to be notified,
The information processing system according to attachment 2.
(Appendix 4)
The load amount adjustment unit,
The load amount is adjusted so that the output amount indicated by the output amount control value for each of the predetermined intervals and the predicted value of the load amount for each of the predetermined intervals included in the selected operation characteristic information are brought close to each other. The information processing system according to appendix 3.
(Appendix 5)
The information processing system,
Has a storage battery,
The load amount adjustment unit,
The information processing system according to any one of appendices 1 to 4, wherein the load amount is adjusted by adjusting a charge amount of the storage battery.
(Appendix 6)
The information processing device,
A data collection unit that collects the power generation amount measured in the output control device and the load amount measured by a load amount measuring device, and stores the load amount in the storage unit,
Any one of Supplementary Notes 1 to 5, further comprising: a prediction unit that calculates a predicted value of the power generation amount and a predicted value of the load amount from the power generation amount and the load amount stored in the storage unit. Information processing system described.
(Appendix 7)
The information processing device,
In the predetermined time, has a timing determination unit that determines the timing of notifying the target value determined by the output amount control unit,
The timing determination unit,
The notification timing is the timing at which the difference between the predicted value of the power generation amount and the output amount is the smallest when the target value is notified to the output control device during the predetermined time. The information processing system according to any one of 1.
(Appendix 8)
An output control device that outputs electric power generated by solar power generation to a load, an information processing device that notifies the output control device of a target value of the output amount of the electric power, and an output control device that outputs the output value to the information processing device. An information processing system including a server that notifies an instruction value that indicates competence,
The information processing device,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in a target value and stores the operation characteristic information in a storage unit;
When the instruction value notified from the server is smaller than the target value notified to the output control device, a predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time has elapsed from a certain time, Based on the operating characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing system comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information.
(Appendix 9)
An information processing device for notifying a target value of the output amount of the electric power to an output control device that outputs electric power generated by solar power generation to a load,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and stores the operation characteristic information in a storage unit;
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time from a certain time, and the operation characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing apparatus comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information.
(Appendix 10)
A program executed by an information processing device that notifies a target value of the output amount of the electric power to an output control device that outputs electric power generated by solar power generation to a load,
In the information processing device,
A process of generating operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and storing the operation characteristic information in a storage unit;
A process of determining a target value to be notified at the time based on the predicted value of the power generation amount of the electric power and the load amount of the load after a lapse of a predetermined time from a certain time, and the operation characteristic information,
A program for executing a process of adjusting the load amount according to a change in the output amount indicated by the operation characteristic information.
(Appendix 11)
An information processing method by an information processing system including an output control device that outputs electric power generated by solar power generation to a load, and an information processing device that notifies the output control device of a target value of the output amount of the electric power And
The information processing device is
Generate operating characteristic information of the output control device showing a change in the output amount according to a change in the target value, and store it in a storage unit,
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a lapse of a predetermined time from a certain time, and the operation characteristic information, the target value to be notified at the time is determined,
An information processing method for adjusting the load amount according to a change in the output amount indicated by the operation characteristic information.
(Appendix 12)
An information processing system including: an output control device that outputs electric power generated using renewable energy to a load; and an information processing device that notifies the output control device of a target value of the output amount of electric power. There
The information processing device,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and stores the operation characteristic information in a storage unit;
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time from a certain time, and the operation characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing system comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information.

The present invention is not limited to the specifically disclosed embodiments, and various modifications and changes can be made without departing from the scope of the claims.

100 solar power generation control system 200 server 300 solar power generation system 310 solar power generation device 320 PCS
330, 330A Information processing device 331, 331A Operation characteristic database 332 History database 334 Operation characteristic generation unit 335 Prediction unit
336 Output amount control unit 337 Load amount adjustment unit 338 Operation characteristic table 339 Timing determination unit

Claims (7)

An information processing system including an output control device that outputs electric power generated by solar power generation to a load, and an information processing device that notifies the output control device of a target value of the output amount of the electric power,
The information processing device,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and stores the operation characteristic information in a storage unit;
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time from a certain time, and the operation characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing system comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information. The operation characteristic generation unit,
During a predetermined time after the first target value is changed to the second target value, the output amount control value indicating the ratio of the output amount to the rated output amount in the photovoltaic power generation is acquired at predetermined intervals at predetermined intervals. ,
The information processing system according to claim 1, wherein the first target value, the second target value, and the output amount control value are associated with each other to be the operation characteristic information. The target value is a target value of the output amount control value,
The output amount control unit,
Of the operating characteristic information stored in the storage unit, the first target value matches the target value at the time, and the output amount indicated by the output amount control value is the most predictive value of the power generation amount. Select the operating characteristic information that is close,
The information processing system according to claim 2, wherein the second target value included in the selected operation characteristic information is determined as the target value to be notified. The load amount adjustment unit,
The load amount is adjusted so that the output amount indicated by the output amount control value for each of the predetermined intervals and the predicted value of the load amount for each of the predetermined intervals included in the selected operation characteristic information are brought close to each other. The information processing system according to claim 3, wherein An information processing device for notifying a target value of the output amount of the electric power to an output control device that outputs electric power generated by solar power generation to a load,
An operation characteristic generation unit that generates operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and stores the operation characteristic information in a storage unit;
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a predetermined time from a certain time, and the operation characteristic information, an output amount control unit that determines a target value to be notified at the time,
An information processing apparatus comprising: a load amount adjusting unit that adjusts the load amount according to a change in the output amount indicated by the operation characteristic information. A program executed by an information processing device that notifies a target value of the output amount of the electric power to an output control device that outputs electric power generated by solar power generation to a load,
In the information processing device,
A process of generating operation characteristic information of the output control device indicating a change in the output amount according to a change in the target value, and storing the operation characteristic information in a storage unit;
A process of determining a target value to be notified at the time based on the predicted value of the power generation amount of the electric power and the load amount of the load after a lapse of a predetermined time from a certain time, and the operation characteristic information,
A program for executing a process of adjusting the load amount according to a change in the output amount indicated by the operation characteristic information. An information processing method by an information processing system including an output control device that outputs electric power generated by solar power generation to a load, and an information processing device that notifies the output control device of a target value of the output amount of the electric power And
The information processing device is
Generate operating characteristic information of the output control device showing a change in the output amount according to a change in the target value, and store it in a storage unit,
Based on the predicted value of the power generation amount of the electric power and the load amount of the load after a lapse of a predetermined time from a certain time, and the operation characteristic information, the target value to be notified at the time is determined,
An information processing method for adjusting the load amount according to a change in the output amount indicated by the operation characteristic information.

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