JP2019205283A - Power control device, private power generation output control device, power management system, and power control method - Google Patents

Abstract

To provide a power control device, private power generation output control device, power management system, and power control method that can suppress steep changes in residual demand.SOLUTION: A power control device controls an upper limit value of generated power of a private power generation possessed by a private power generation user, a user who privately generates power. The power control device includes: a communication unit that receives an output control instruction signal including power change rate information which is information indicating a temporal change in an upper limit value of power output by private power generation; and an output control unit that controls an output upper limit of private power generation on the basis of the power change rate information included in the output control instruction signal.SELECTED DRAWING: Figure 7

Description

  Embodiments described herein relate generally to a power control device, a private power generation output control device, a power management system, and a power control method.

With the introduction of a large amount of PV (Photovoltaics), a time period in which it is difficult to maintain the frequency of the power system is occurring. In order to solve this problem, PV output control has already been implemented in some areas in accordance with the instructions of the grid operator. At this time, technical specifications of the power conditioner (Power Conditioning System: PCS) having the output control function are determined so that the output change of the PV power generation does not become steep according to the output control instruction from the general power transmission and distribution company. .
On the other hand, with respect to a technique for relaxing the output control instruction itself of PV power generation, a technique for intentionally creating demand and relaxing PV output for the generated electric power is known (for example, see Patent Document 1).

JP 2017-158375 A

In the power management system, when the power supply becomes excessive, there is a case where the output is suppressed to suppress the reverse power flow to the consumer. In this case, the consumer suppresses the maximum generated power for self-power generation, but it is reasonable to moderate this output suppression by arbitrarily increasing the power demand.
If the general transmission / distribution company issues an output control instruction and the output suppression mitigation that suppresses the reverse power flow is not performed by the aggregator, the residual demand obtained by excluding the output of the PCS from the demand is Do not make steep changes.

However, when a general power transmission / distribution company issues an output control instruction and the output is alleviated by the aggregator that suppresses the reverse power flow to the consumer, the PCS output is controlled so that the PV output change does not become steep. If this is the case, the residual demand may change sharply. A sudden change in the residual demand is not preferable because it causes a load on the general power transmission and distribution company.
The present invention has been made in view of the above circumstances, and an object thereof is to provide a power control device, a private power generation output control device, a power management system, and a power control method that can suppress a steep change in residual demand. .

One aspect of the present invention is a power control apparatus that controls an upper limit value of power generated by a private power generation consumer who is a consumer who performs private power generation, and the upper limit value of the power output by the private power generation. A communication unit that receives an output control instruction signal including power change ratio information that is information indicating a time change, and controls an output upper limit of the private power generation based on the power change ratio information included in the output control instruction signal It is a power control apparatus provided with an output control part.
In the power control apparatus of one aspect of the present invention, the output control instruction signal includes output upper limit control information that is information for controlling an upper limit value of the generated power of the private power generation, and the communication unit includes the output control A plurality of instruction signals are received, and the output control unit controls the output upper limit of the private power generation based on output upper limit control information and power change rate information included in each of the plurality of output control instruction signals.
In the power control apparatus according to an aspect of the present invention, the output control unit controls the upper limit output of the private power generation according to the latest output control instruction signal among the plurality of output control instruction signals received by the communication unit. .
In the power control apparatus according to one aspect of the present invention, the output control unit, when the output control instruction signal does not include the power change ratio information, preset first power change ratio information and the output control instruction Based on the output upper limit control information included in the signal, the output upper limit of the private power generation is controlled.
In the power control apparatus of one aspect of the present invention, the output control unit is preset with second output upper limit control information that is set in advance when there is no output control instruction signal to be processed for a first time. The upper limit of the output of the private power generation is controlled based on the second power change rate information.
In the power control apparatus according to one aspect of the present invention, the upper limit value of the power output by the power control apparatus that adjusts the upper limit value of the generated power output by the private power generation consumer of the private power generation consumer who is the consumer who performs the private power generation. A creation unit that creates an output control instruction signal including power change rate information that is information indicating a time change, and a communication unit that transmits the output control instruction signal created by the creation unit to the power control apparatus.
One aspect of the present invention is a power control device that controls an upper limit value of the power generated by the private power generation that a private power generation consumer who is a consumer that performs private power generation, and the power generation power of the private power generation of the power control device A power management system comprising a private power generation output control device that controls an upper limit value, wherein the private power generation output control device is information indicating a time change of an upper limit value of power output from the power control device. A creation unit that creates an output control instruction signal including information; and a private power generation output control device communication unit that transmits the output control instruction signal created by the creation unit to the power control device, wherein the power control device includes: A power control device communication unit that receives the output control instruction signal, and an output control that controls an output upper limit of the private power generation based on the power change rate information included in the output control instruction signal Comprising the door, a power management system.
One aspect of the present invention is a power control method executed by a power control apparatus that controls an upper limit value of power generated by a private power generation consumer who is a consumer who performs private power generation. Receiving the output control instruction signal including the power change ratio information that is information indicating the time change of the upper limit value of the power to be performed, and based on the power change ratio information included in the output control instruction signal, And a step of controlling an output upper limit.
One aspect of the present invention is information indicating time variation of an upper limit value of power output by a power control device that adjusts an upper limit value of power output from the private power generation that a private power generation consumer who is a consumer who performs private power generation outputs. A private power generation output control device, comprising: generating an output control instruction signal including power change ratio information, and transmitting the output control instruction signal created in the creating step to the power control device. This is a power control method to be executed.
One aspect of the present invention is a power control method executed by a power management system, wherein the self-power generation output control device has an upper limit of power output by the self-power generation that a self-power generation consumer who is a consumer that performs self-power generation. A step of creating an output control instruction signal including power change ratio information, which is information indicating a time change of the upper limit value of the power output by the power control device for adjusting the value, and the private power generation output control device in the step of creating A step of transmitting the generated output control instruction signal to the power control device, and the power control device is a power change rate information which is information indicating a time change of an upper limit value of the power output from the private power generation. Receiving the output control instruction signal including the output of the private power generation based on the power change rate information included in the output control instruction signal And a step of controlling the limit, a power control method.

  According to the embodiment of the present invention, it is possible to provide a power control device, a private power generation output control device, a power management system, and a power control method that can suppress a steep change in residual demand.

It is a figure which shows an example of the power management system of 1st Embodiment. It is a figure which shows an example of the load with which a consumer is provided. It is a figure which shows an example of the flow of the electric power of the power management system of 1st Embodiment. It is a block diagram which shows the private power generation output control apparatus contained in the power management system of 1st Embodiment. It is a figure which shows an example of load information. It is a figure which shows an example of power generation equipment capacity information. It is a figure which shows an example (the 1) of operation | movement of the power management system of 1st Embodiment. It is a figure which shows an example (the 2) of operation | movement of the power management system of 1st Embodiment. It is a figure which shows an example of operation | movement of a power management system. It is a figure which shows an example (the 3) of operation | movement of the power management system of 1st Embodiment. It is a figure which shows an example of operation | movement of a power management system. It is a figure which shows an example (the 4) of operation | movement of the power management system of 1st Embodiment. It is a block diagram which shows PCS contained in the power management system of 1st Embodiment. It is a figure which shows an example (the 1) of operation | movement of PCS of 1st Embodiment. It is a figure which shows an example (the 2) of operation | movement of PCS of 1st Embodiment. It is a sequence chart which shows an example of operation | movement of the power management system of 1st Embodiment. It is a block diagram which shows the private power generation output control apparatus contained in the power management system of 2nd Embodiment. It is a figure which shows an example (the 1) of operation | movement of the power management system of 2nd Embodiment. It is a flowchart which shows an example of operation | movement of the private power generation output control apparatus contained in the power management system of 2nd Embodiment. It is a figure which shows an example of operation | movement of the power management system of 2nd Embodiment. It is a figure which shows an example (the 2) of operation | movement of the power management system of 2nd Embodiment. It is a figure which shows an example (the 3) of operation | movement of the power management system of 2nd Embodiment. It is a figure which shows an example (the 4) of operation | movement of the power management system of 2nd Embodiment. It is a figure which shows an example of operation | movement of the power management system of 2nd Embodiment.

Next, a power control device, a private power generation output control device, a power management system, and a power control method according to the present embodiment will be described with reference to the drawings. Embodiment described below is only an example and embodiment to which this invention is applied is not restricted to the following embodiment.
Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiments, and the repetitive description will be omitted.
Further, “based on XX” in the present application means “based on at least XX”, and includes a case based on another element in addition to XX. Further, “based on XX” is not limited to the case where XX is directly used, but also includes the case where it is based on an operation or processing performed on XX. “XX” is an arbitrary element (for example, arbitrary information).

(First embodiment)
(Power management system)
FIG. 1 is a diagram illustrating an example of a power management system according to the first embodiment.
The power management system 10 includes a private power generation output control device 100, a home energy management system (HEMS) server 300A, a HEMS server 300B, a HEMS server 300C, a HEMS server 300D, and a power conditioner (Power Conditioning). System: PCS) 200C.
The private power generation output control device 100, the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, the HEMS server 300D, and the PCS 200C are connected via a network 50 such as the Internet. Moreover, the private power generation output control apparatus 100 is connected to a server of a general power transmission and distribution company. Here, the general power transmission / distribution company refers to a company that stably supplies power by adjusting the power demand and the power supply in the jurisdiction to coincide with each other.

The private power generation output control device 100 is, for example, an aggregator, and performs private power generation with a HEMS server 300A possessed by a consumer A that does not perform private power generation, and a HEMS server 300B possessed by a consumer B that does not perform private power generation. Communication is performed via the network 50 with the HEMS server 300C of the customer C and the HEMS server 300D of the customer D who does not perform private power generation. Hereinafter, when the customer A, the customer B, and the customer D that do not perform private power generation are not distinguished from the customer C that performs private power generation, they are collectively referred to as a consumer.
Of the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, and the HEMS server 300D, an arbitrary HEMS server is referred to as a HEMS server 300.

FIG. 2 is a diagram illustrating an example of a load provided by a consumer. FIG. 2 shows, as an example, a load M included in the HEMS server 300A that the customer A has. The HEMS server 300A included in the customer A is connected to a load α, a load β, a load 1, a load 2, and a network. The HEMS server 300A controls the load α, the load β, the load 1 and the load 2. Hereinafter, when the load α, the load β, the load 1 and the load 2 are not distinguished, they are simply referred to as the load M. Similarly to the customer A, the customer B, the customer C, and the customer D have a load M (not shown).
Specifically, the load M is connected to a network such as an electric light, a washing machine, a dishwasher, an air conditioner, a futon dryer, a water heater, a rice cooker, an electric bicycle battery charger, and an electric vehicle (charging). It is a device (IoT device) that operates by consuming electric power. The load M is preferably a device that does not require advance preparation for operation.
The control of the load M includes, for example, starting the load M at a specified time, stopping the load M, and operating a specific function of the load M. Further, the HEMS server 300 stores information on the load M such as the power consumption amount of the connected load M, and transmits the information on the load M to the private power generation output control device 100 in response to a request. Returning to FIG. 1, the description will be continued.

  The customer C includes a PCS 200C. The PCS 200C controls the power of private power generation. Specifically, the PCS 200C controls the upper limit value of power generated by private power generation. Examples of in-house power generation are PV, fuel cells, and the like. Hereinafter, description will be continued for the case where the private power generation is PV. The PCS 200C has a function of selling generated power as surplus power as much as possible. The PCS 200C uses a function and a load for storing surplus power without selling power when receiving a signal for suppressing power generated by the customer C that performs private power generation (hereinafter referred to as “suppression signal”). Function to reduce the maximum power by reducing the efficiency of power generation.

FIG. 3 is a diagram illustrating an example of the power flow of the power management system according to the first embodiment.
As shown in FIG. 3, electric power TK is supplied from a general power transmission / distribution company to customer A, customer B, customer C, and customer D through a distribution line. In addition, surplus power generated by the customer C who performs private power generation is transmitted as a reverse power RC through the distribution line. The consumer A, the consumer B, and the consumer D consume the electric power TK and the reverse power flow RC. In this example, it is described that consumer A, consumer B, consumer C, and consumer D consume power. However, the consumer is not limited to the above, and a consumer that does not have a HEMS server is also the same. Electric power TK and reverse power RC are consumed. In addition, the consumer who consumes electric power TK and reverse power flow RC does not need to be supplied by the same distribution line. Moreover, you may supply reverse power flow RC across the transformer in a substation.
In the power management system 10 of the first embodiment, when the private power generation output control device 100 instructs the customer to create demand, the residual indicated by removing the output of the PCS 200C from the demand by the demand creation. The time change of the upper limit value of the power output by the PCS 200C is controlled so that the change in demand does not become steep. Hereinafter, controlling the time variation of the upper limit value of the power output by the PV may be referred to as “slope control”.

Hereinafter, among the private power generation output control device 100, the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, the HEMS server 300D, and the PCS 200C constituting the power management system 10, the private power generation output control device 100, The PCS 200C will be described in detail.
FIG. 4 is a block diagram illustrating the private power generation output control device included in the power management system of the first embodiment.
(In-house power generation output control device)
The private power generation output control device 100 includes a device such as a personal computer, a server, or an industrial computer.
The private power generation output control device 100 includes a communication unit 110, a storage unit 120, an information processing unit 130, an address bus, a data bus, and the like for electrically connecting each component as shown in FIG. Bus line 150.

The communication unit 110 is realized by a communication module. The communication unit 110 communicates with an external communication device such as the PCS 200C, the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, and the HEMS server 300D via the network 50. The communication unit 110 communicates with a general power transmission / distribution company server (not shown).
Specifically, the communication unit 110 receives an output control signal transmitted from the server of the general power transmission and distribution company, and outputs the received output control signal to the information processing unit 130. Here, the output control signal is a signal for controlling the upper limit value of the power output by the PV. Further, the communication unit 110 transmits the power consumption instruction signal output from the information processing unit 130 to the HEMS server 300. Here, the power consumption instruction signal is a signal for instructing the power consumption of the load connected to the HEMS server 300. In addition, the communication unit 110 transmits the output control instruction signal output from the information processing unit 130 to the PCS 200C. Here, the output control instruction signal is a signal for instructing an upper limit value of the PV generated power.

  The storage unit 120 is realized by, for example, a random access memory (RAM), a read only memory (ROM), a hard disk drive (HDD), a flash memory, or a hybrid storage device in which a plurality of these are combined. Instead of being provided as a part of the private power generation output control device 100, a part or all of the storage unit 120 is replaced by a processor of the private power generation output control device 100 such as a NAS (Network Attached Storage) or an external storage server. 50 may be realized by an external device accessible via the network 50. The storage unit 120 stores a program 121 executed by the information processing unit 130, an application 122, load information 123, and power generation facility capacity information 124.

The application 122 causes the private power generation output control device 100 to receive the output control signal transmitted from the server of the general power transmission and distribution company. As described above, the output control signal is a signal for controlling the upper limit value of the power output by the PV, and the upper limit value of the power output by the PV is the power supply and power in the area under the jurisdiction of the general power transmission and distribution company. Determined on the basis of demand. The output control signal includes a suppression rate that is information for suppressing the power generated by the consumer C that performs private power generation. The suppression rate is information that specifies what percentage of the capacity of the power generation equipment held by the customer C may be generated as information for suppressing the maximum power generated by the customer C that performs private power generation. That is, the suppression rate is the same as the output upper limit.
The application 122 causes the private power generation output control device 100 to derive an increase in power consumption based on the suppression rate included in the output control signal. The application 122 generates a power consumption instruction signal based on information indicating the derived increase in power consumption. The application 122 causes the private power generation output control device 100 to transmit the created power consumption instruction signal to the HEMS server 300.
Further, the application 122 causes the private power generation output control device 100 to derive the PV output upper limit based on the suppression rate included in the output control signal and the derived increase in power consumption. The application 122 causes the private power generation output control device 100 to create an output control instruction signal including information indicating the PV output upper limit and information indicating the slope control. Here, the information indicating the slope control includes information indicating a temporal change in the upper limit value of the PV generated power. The application 122 causes the private power generation output control device 100 to transmit the generated output control instruction signal to the PCS 200C.

The load information 123 includes information on the load M. Specifically, the information on the load M includes customer information, load identification information, power increase information, operable time information, and priority. The information included in the load information 123 is information selected according to a pre-contract between a power retailer or the like and a customer, or a customer selected a load M that may be temporarily operated.
FIG. 5 is a diagram illustrating an example of load information. In the example shown in FIG. 5, the power increase is represented by (W), and the operable time is represented by (minutes).
Specifically, as information on the load M, the customer “A”, the load “α”, the power increase “1500” (W), the operable time “120” (minutes), and the priority “1”. Are stored in association with each other. Further, as information on the load M, the customer “A”, the load “β”, the power increase “500” (W), the operable time “180” (minutes), and the priority “2” are mutually connected. Associated and stored. In this case, as for the information on the load M, the consumer A includes the load “α” and the load “β”, and the load “α” consumes “1500” (W) of power, and “120” (minutes). ) It can be operated and indicates that it can operate with priority over the load “β”. The load “β” consumes 500 (W) of power and can operate “180” (minutes). It indicates that the priority of operation is lower than “α”.
Further, as information on the load M, the customer “B”, the load “γ”, the power increase “50” (W), the operable time “360” (minutes), and the priority “1” are mutually connected. Associated and stored.
Further, the customer “C”, the load “Δ”, the power increase “200”, the operable time “300” (minutes), and the priority “3” are stored in association with each other.

The power generation facility capacity information 124 is information in which information on a customer who performs private power generation is associated with information on the power generation facility capacity of a power generation facility such as a PV owned by the consumer who performs the private power generation.
FIG. 6 is a diagram illustrating an example of the power generation facility capacity information. In the example shown in FIG. 6, the power generation facility capacity information 124 associates the customer with the power generation facility capacity information [kW] of the power generation facility held by the consumer.
Specifically, the customer “X” who performs private power generation and the information “3” (kW) of the power generation facility capacity of the power generation facility held by the customer [X] are associated with each other. Further, the customer “Y” who performs private power generation and the information “4” (kW) of the power generation facility capacity of the power generation facility owned by the customer “Y” are associated with each other. The customer “Z” that performs private power generation is associated with the information “5” (kW) of the power generation facility capacity of the power generation facility owned by the customer “Z”.

The information processing unit 130 is, for example, a functional unit (hereinafter referred to as “software functional unit”) realized by a program 121 stored in the storage unit 120 by a processor such as a CPU (Central Processing Unit) or the application 122. It is. Note that all or part of the information processing unit 130 may be realized by hardware such as LSI (Large Scale Integration), ASIC (Application Specific Integrated Circuit), or FPGA (Field-Programmable Gate Array). It may be realized by a combination of a unit and hardware.
The information processing unit 130 includes, for example, an acquisition unit 131, an output power deriving unit 132, a power consumption deriving unit 133, and a creating unit 134.
The acquisition unit 131 acquires the output control signal output from the communication unit 110, and outputs the acquired output control signal to the output power deriving unit 132.

The output power deriving unit 132 acquires the suppression rate included in the output control signal output by the acquiring unit 131. The output power deriving unit 132 acquires the suppression rate included in the output control signal output by the acquisition unit 131, and derives the PV output upper limit based on the acquired suppression rate. The output power deriving unit 132 outputs information indicating the derived PV output upper limit (hereinafter referred to as “generated power information”) to the creating unit 134. The output power deriving unit 132 outputs information on the suppression rate to the power consumption deriving unit 133.
Specifically, when a consumer who performs self-power generation capable of generating 5 kW of power receives an output control signal including a suppression rate of 50 (%), the demand for performing self-power generation that has received the output control signal The electric power generated by the house is 2.5 (kW).
In addition, when the output control signal including the suppression rate of 80 (%) is received by the customer X that performs 3 (kW) private power generation and the customer Y that performs 2 (kW) private power generation, output The power generated by the customer X that receives the control signal and that generates the power is 2.4 (kW), and the power that is generated by the consumer Y that receives the power control signal and generates the power is 1.6 (kW). become.
The power consumption deriving unit 133 acquires information on the suppression rate output by the output power deriving unit 132. The power consumption deriving unit 133 acquires information on the load M included in the load information 123 of the storage unit 120. The power consumption deriving unit 133 acquires information on the power generation facility capacity included in the power generation facility capacity information 124 of the storage unit 120.
The power consumption deriving unit 133 derives an increase in power consumption based on the information indicating the suppression rate included in the output control signal, the acquired information on the load M, and the information on the power generation facility capacity, and derives the derived power consumption Information indicating the increase in the number is output to the creation unit 134.

The creation unit 134 acquires the generated power information output by the output power deriving unit 132 and acquires information indicating the increase in power consumption output by the power consumption deriving unit 133. The creation unit 134 creates a power consumption instruction signal destined for the HEMS server 300 based on the information indicating the increase in power consumption, and outputs the created power consumption instruction signal to the communication unit 110.
Further, the creation unit 134 creates information indicating the PV output upper limit based on the acquired generated power information and information indicating the increase in power consumption. In addition, the creation unit 134 determines whether to perform slope control based on information indicating an increase in power consumption. Specifically, the creation unit 134 determines whether to perform slope control according to whether to change the power consumption (demand) of the load M. The creation unit 134 determines that the slope control is performed when the power consumption (demand) of the load M is not changed, and determines that the slope control is not performed when the power consumption (demand) is changed. The creation unit 134 makes the time change of the output of the PCS 200C steep when increasing the power consumption of the load M.
The creation unit 134 includes information indicating the PV output upper limit and information indicating slope control, creates an output control instruction signal destined for the PCS 200C, and outputs the created output instruction signal to the communication unit 110.

Here, the process for determining whether or not to perform slope control will be described in detail when the private power generation output control device 100 increases the demand and when the demand is reduced.
(When private power generation output control device 100 increases demand (part 1))
FIG. 7 is a diagram illustrating an example (part 1) of the operation of the power management system according to the first embodiment. In the example shown in FIG. 7, when the private power generation output control apparatus 100 increases the demand, the process of performing slope control of the output of the PCS 200C is shown.
A case where the output upper limit changes from a1 to a2 (> a1) as shown in (1) will be described.
The creation unit 134 outputs, to the communication unit 110, an output control instruction signal including information indicating that the output upper limit of the PCS 200C is controlled to a2 at time t1, as indicated by the no-slope SN in (2). Specifically, the creation unit 134 displays “a2” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a1 to a2 at time t1 (slope control) as information indicating the slope control. Output control instruction signal including information indicating that no operation is performed). In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (5), since the residual demand indicated by subtracting the output of the PCS 200C from the demand is constant at c1, there is no sharp change in the residual demand.
As shown in (2) SA with slope, output control including information indicating that the output upper limit of the PCS 200C is slope-controlled from a1 to a2 between time t1 and time t2. A case where the instruction signal is output to the communication unit 110 will be described. Specifically, the creation unit 134 sets “a2” as the information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a1 to a2 between time t1 and time t2 as information indicating the slope control. A case where an output control instruction signal including “information indicating (indicating that slope control is performed)” is created will be described. In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.

  In this case, as shown in (4), the residual demand changes sharply from c1 to c2 at time t1. This sudden change in residual demand is a burden on general power transmission and distribution companies.

(When private power generation output control device 100 reduces demand (part 2))
FIG. 8 is a diagram illustrating an example (part 2) of the operation of the power management system according to the first embodiment. In the example shown in FIG. 8, when the private power generation output control apparatus 100 reduces the demand, it shows a process of performing slope control.
A case where the output upper limit changes from a1 to a2 (a2 <a1) as shown in (1) will be described.
Further, the creation unit 134 outputs, to the communication unit 110, an output control instruction signal including information indicating that the output upper limit of the PCS 200C is controlled to a2 at time t1, as indicated by the no-slope SN in (2). To do. Specifically, the creation unit 134 displays “a2” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a1 to a2 at time t1 (slope control) as information indicating the slope control. Output control instruction signal including information indicating that no operation is performed). In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 reduces the demand from b1 to b2 at time t1, in accordance with the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (5), since the residual demand is constant at c1, there is no sharp change in the residual demand.
As shown in (2) SA with slope, output control including information indicating that the output upper limit of the PCS 200C is slope-controlled from a1 to a2 between time t1 and time t2. A case where the instruction signal is output to the communication unit 110 will be described. Specifically, the creation unit 134 sets “a2” as the information indicating the rate of change in the PV output upper limit, and sets “the output upper limit from a1 to a2 between time t1 and time t2 as information indicating the slope control. A case will be described in which an output control instruction signal including “information indicating change (information indicating that slope control is performed)” is created. In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
In this case, as shown in (4), the residual demand changes sharply from c1 to c2 at time t1. This sudden change in residual demand is a burden on general power transmission and distribution companies.

(When private power generation output control device 100 increases demand (part 3))
FIG. 9 is a diagram illustrating an example of the operation of the power management system. In the example shown in FIG. 9, the power control is increased by the output control signal from the general power transmission / distribution company and the slope control is performed when the private power generation output control device 100 increases the demand.
A case where the output upper limit changes from a1 to a3 (a3> a1) as shown in (1) will be described. Here, the increase from the output upper limit a1 to the output upper limit a3 is the increase by increasing the demand from a1 to a2 (a2> a1) and the general increase of the output upper limit a2 to the output upper limit a3 (a3> a2). It includes the increase due to the output control signal from the server of the power transmission and distribution company.
As shown in (2) SA with slope, output control including information indicating that the output upper limit of the PCS 200C is slope-controlled from a1 to a3 between time t1 and time t2. A case where the instruction signal is output to the communication unit 110 will be described. Specifically, the creation unit 134 sets “a3” as the information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from a1 to a3 between time t1 and time t2 as information indicating the slope control. A case where an output control instruction signal including “information (information indicating that slope control is to be performed)” is generated will be described. In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.

As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (4), the residual demand changes sharply from c1 to c2 at time t1. This sudden change in residual demand is a burden on general power transmission and distribution companies.
FIG. 10 is a diagram illustrating an example (part 3) of the operation of the power management system according to the first embodiment. In the example shown in FIG. 10, the slope control is not performed for the increase in demand in FIG. 9.
A case where the output upper limit changes from a1 to a3 (a3> a1) as shown in (1) will be described. Here, as described above, the increase from the output upper limit a1 to the output upper limit a3 includes the increase caused by increasing the demand from a1 to a2 (a2> a1), and the output upper limit a2 to the output upper limit a3 (a3> a2) an increase due to the output control signal from the server of the general power transmission and distribution company.

The creation unit 134 has information indicating that the output upper limit of the PCS 200C is controlled from a1 to a2 at time t1 as indicated by (2) no slope SN and (2) SA with slope. In addition, an output control instruction signal including information indicating that slope control is performed from a2 to a3 at time t1 is output to the communication unit 110. Specifically, the creation unit 134 displays “a2” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a1 to a2 at time t1 (slope control) as information indicating the slope control. Output information between the time t1 and the time t2 as information indicating the slope control, and “a3” as the information indicating the output upper limit of the PV. An output control instruction signal including second output control instruction information including information indicating that the upper limit changes from a2 to a3 (information indicating that slope control is performed) is created.
Further, the creation unit 134 displays “a2” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a1 to a2 at time t1 as information indicating the slope control (does not perform slope control). ) "As the information indicating the output upper limit of PV, and as the information indicating the slope control, the output upper limit is a2 between time t1 and time t2. And a second output control instruction signal including information indicating that the transition from a to a3 (information indicating that slope control is performed) may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1. Further, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (4), since the residual demand changes gently from c1 to c3 from time t1 to time t2, there is no sharp change in the residual demand.

FIG. 11 is a diagram illustrating an example of the operation of the power management system. The example shown in FIG. 11 shows a process for performing slope control when the output upper limit is reduced by the output control signal from the server of the general power transmission and distribution company and the private power generation output control device 100 increases the demand. It is.
A case where the output upper limit changes from a3 to a2 (a3> a2) as shown in (1) will be described. Here, the decrease from the output upper limit a3 to the output upper limit a2 is the decrease from the output upper limit a3 to the output upper limit a1 (a3>a2> a1) by the output control signal from the server of the general power transmission and distribution company, and from a1 and an increase due to an increase in demand for a2 (a2> a1).
As shown in (2) SA with slope, output control including information indicating that the output upper limit of the PCS 200C is slope-controlled from a3 to a2 between time t1 and time t2. A case where the instruction signal is output to the communication unit 110 will be described. Specifically, the creation unit 134 sets “a2” as the information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from a3 to a2 between time t1 and time t2 as information indicating the slope control. A case where an output control instruction signal including “information (information indicating that slope control is to be performed)” is generated will be described. In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (4), the residual demand changes sharply from c1 to c2 at time t1. This sudden change in residual demand is a burden on general power transmission and distribution companies.

FIG. 12 is a diagram illustrating an example (part 4) of the operation of the power management system according to the first embodiment. In the example shown in FIG. 12, in FIG. 11, the slope control is not performed for the increased demand.
A case where the output upper limit changes from a3 to a2 (a3> a2) as shown in (1) will be described. Here, the decrease from the output upper limit a3 to the output upper limit a2 is the decrease from the output upper limit a3 to the output upper limit a1 (a3>a2> a1) by the output control signal from the server of the general power transmission and distribution company, and from a1 and an increase due to an increase in demand for a2 (a2> a1).

  The creation unit 134 has information indicating that the output upper limit of the PCS 200C is controlled from a3 to a4 at time t1 as indicated by (2) no slope SN, and (2) the sloped SA is indicated. In addition, an output control instruction signal including information indicating that slope control is performed from a4 to a2 at time t1 is output to communication unit 110. Specifically, the creation unit 134 displays “a4” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a3 to a4 at time t1 (slope control) as information indicating the slope control. First output control instruction information including “a2” as information indicating the output upper limit of PV, and “output upper limit between time t1 and time t2 as information indicating slope control”. Output control instruction signal including the second output control instruction information including “information indicating that the signal changes from a4 to a2 (information indicating that slope control is performed)”.

The creation unit 134 also includes “a4” as information indicating the PV output upper limit and “information indicating that the output upper limit changes from a3 to a4 at time t1” as information indicating the slope control. The output control instruction signal, “a2” as information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from a4 to a2 between time t1 and time t2” as information indicating the slope control, A second output control instruction signal including
The communication unit 110 transmits the output control instruction signal output from the creation unit 134 to the PCS 200C at time t1. Further, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134 to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100.
In this case, as shown in (4), since the residual demand changes gently from c1 to c3 from time t1 to time t2, there is no sharp change in the residual demand.

(PCS)
FIG. 13 is a block diagram illustrating a PCS included in the power management system according to the first embodiment.
The PCS 200C includes a device such as a personal computer, a server, or an industrial computer.
The PCS 200C includes a communication unit 210, a storage unit 220, an information processing unit 230, and a bus line 250 such as an address bus and a data bus for electrically connecting each component as shown in FIG. Is provided.

  The communication unit 210 is realized by a communication module. The communication unit 210 communicates with an external communication device such as the private power generation output control device 100 via the network 50. Specifically, the communication unit 210 receives the output control instruction signal transmitted by the private power generation output control device 100 and outputs the received output control instruction signal to the information processing unit 230. Further, the communication unit 210 receives the first output control instruction signal and the second output control instruction signal transmitted by the private power generation output control device 100, and receives the received first output control instruction signal and second output control instruction signal. May be output to the information processing unit 230.

  The storage unit 220 is realized by, for example, a RAM, a ROM, an HDD, a flash memory, or a hybrid storage device in which a plurality of these are combined. Instead of being provided as a part of the PCS 200C, a part or all of the storage unit 220 is replaced by an external device that can be accessed by the processor of the private power generation output control device 100 via the network 50, such as a NAS or an external storage server. It may be realized. The storage unit 220 stores a program 221 executed by the information processing unit 230 and an application 222.

The application 222 causes the PCS 200C to receive the output control instruction signal transmitted by the private power generation output control device 100. The application 222 causes the PCS 200C to control the power output by the PCS 200C according to the information indicating the PV output upper limit included in the output control instruction signal and the information indicating the slope control.
The application 222 may cause the PCS 200C to receive the first output control instruction signal and the second output control instruction signal transmitted by the private power generation output control device 100. The application 222 informs the PCS 200C of information indicating the PV output upper limit included in the first output control instruction signal and information indicating the slope control, information indicating the PV output upper limit included in the second output control instruction signal, and the slope control. The power output from the PCS 200C may be controlled in accordance with the information indicating.

The information processing unit 230 is, for example, a software function unit realized by executing a program 221 stored in the storage unit 220 or an application 222 by a processor such as a CPU. Note that all or part of the information processing unit 230 may be realized by hardware such as LSI, ASIC, or FPGA, or may be realized by a combination of a software function unit and hardware.
The information processing unit 230 includes, for example, an acquisition unit 231 and an output control unit 232.
The acquisition unit 231 acquires the output control instruction signal output from the communication unit 210 and outputs the acquired output control instruction signal to the output control unit 232. The acquisition unit 231 acquires the first output control instruction signal and the second output control instruction signal output from the communication unit 210, and outputs the acquired first output control instruction signal and the second output control instruction signal. You may output to the control part 232.

The output control unit 232 acquires information indicating the PV output upper limit included in the output control instruction signal output by the acquisition unit 231 and information indicating slope control, information indicating the acquired PV output upper limit, and the slope The output upper limit of the PCS 200C is controlled according to the information indicating the control. Specifically, the output control unit 232 controls the upper limit value of the PV generated power according to the PV output upper limit indicated by the information indicating the PV output upper limit and the information indicating the slope control. With this configuration, the output of the PCS 200C is controlled.
In addition, the output control unit 232 acquires first output control instruction information and second output control instruction information included in the output control instruction signal output by the acquisition unit 231. The output control unit 232 executes the first output control instruction information and the second output control instruction information in this order in accordance with the acquired first output control instruction information and second output control instruction information. Specifically, the output control unit 232 acquires information indicating the PV output upper limit and information indicating slope control included in the acquired first output control instruction information, and includes them in the acquired second output control instruction information. The information indicating the output upper limit of the PV and the information indicating the slope control are acquired. The output control unit 232 performs the PV output upper limit indicated by the information indicating the PV output upper limit and the slope control according to the information indicating the PV output upper limit acquired from the first output control instruction information and the information indicating the slope control. The upper limit value of the generated power of PV is controlled according to the information shown. Thereafter, the output control unit 232 determines the PV output upper limit indicated by the information indicating the PV output upper limit and the slope according to the information indicating the PV output upper limit acquired from the second output control instruction information and the information indicating the slope control. The upper limit value of the PV generated power is controlled according to the information indicating the control.

  Further, the output control unit 232 acquires the first output control instruction signal and the second output control instruction signal output by the acquisition unit 231. The output control unit 232 may execute the first output control instruction signal and the second output control instruction signal in this order in accordance with the acquired first output control instruction signal and second output control instruction signal. Specifically, the output control unit 232 acquires information indicating the output upper limit of PV and information indicating slope control included in the acquired first output control instruction signal, and information indicating the acquired output upper limit of PV. According to the information indicating the slope control, the upper limit value of the PV generated power is controlled according to the PV output upper limit indicated by the information indicating the PV output upper limit and the information indicating the slope control. The output control unit 232 acquires information indicating the PV output upper limit and information indicating the slope control included in the acquired second output control instruction signal, and information indicating the acquired PV output upper limit and information indicating the slope control. The upper limit value of the PV generated power is controlled according to the PV output upper limit indicated by the information indicating the PV output upper limit and the information indicating the slope control.

FIG. 14 is a diagram illustrating an example (part 1) of the operation of the PCS according to the first embodiment. Here, when the output upper limit of the PCS 200C is changed from a1 to a2 at the time t1, and then the output upper limit of the PCS 200C between the time t1 and the time t2 is changed from a2 to a3, the method 1 and the method 2 are divided. explain.
(Method 1)
Private power generation output control device 100 transmits an output control instruction signal including first output control instruction information (a) and second output control instruction information (b) to PCS 200C. Here, the first output control instruction information (a) includes information indicating the PV output upper limit (PV output control instruction) and information indicating the slope control (slope control instruction (no slope)), and the second output control instruction information (B) includes information indicating the PV output upper limit (PV output control instruction) and information indicating the slope control (slope control instruction (with slope)) By configuring in this way, information indicating the PV output upper limit (PV output control instruction) and first output control instruction information (a) including information indicating slope control (slope control instruction (no slope)), information indicating PV output upper limit (PV output control instruction), and slope Since the second output control instruction information (b) including the control information (slope control instruction (with slope)) can be transmitted with one signal, the output of the PCS 200C can be increased by one communication. A, it can be controlled to have a slope from no slope.

(Method 2)
The private power generation output control apparatus 100 transmits the first output control instruction signal (a) and the second output control instruction signal (b) to the PCS 200C. Here, the first output control instruction signal (a) includes information indicating the PV output upper limit (PV output control instruction) and information indicating the slope control (slope control instruction (no slope)), and the second output control instruction signal (B) includes information indicating the PV output upper limit (PV output control instruction) and information indicating the slope control (slope control instruction (with slope)) By configuring in this way, information indicating the PV output upper limit First output control instruction signal (a) including (PV output control instruction) and information indicating slope control (slope control instruction (no slope)), information indicating PV output upper limit (PV output control instruction), and slope Since the second output control instruction signal (b) including control information (slope control instruction (with slope)) can be transmitted, the output upper limit of the PCS 200C can be set to It can be controlled from no-flops to have slope.

FIG. 15 is a diagram illustrating an example (part 2) of the operation of the PCS according to the first embodiment. Here, while the output control unit 232 of the PCS 200C controls the output upper limit of the PCS 200C from a1 to a2 from the time t1 to the time t3, the private power generation output control device 100 indicates the PV output upper limit. Output including “a0 (a0 <a1)” as information and “information indicating that the output upper limit changes to a0 at time t2 (information indicating that slope control is not performed)” as information indicating slope control The operation when a control instruction signal is transmitted is shown.
(Example 1)
Private power generation output control device 100 transmits a first output control instruction signal to PCS 200C. Here, the first output control instruction signal is “a2” as information indicating the PV output upper limit, and “indicating that the output upper limit is changed to a2 between time t1 and time t3” as information indicating the slope control. Information (information indicating that slope control is performed).
The PCS 200C receives the first output control instruction signal transmitted from the private power generation output control device 100, and is based on information indicating the PV output upper limit included in the received first output control instruction signal and information indicating slope control. Then, the upper limit value of the PV generated power is controlled. When the PCS 200C controls the upper limit value of the generated power of PV, the output upper limit of the PCS 200C changes from a1 to a3 (a1 <a3 <a2) as shown in the SA with slope of Example 1 in FIG. Moreover, the private power generation output control device 100 transmits the second output control instruction signal to the PCS 200C. Here, the second output control instruction signal is “a0” as information indicating the PV output upper limit, and “information indicating that the electric power is changed to a0 at time t2 (slope control is performed) as information indicating the slope control. Information indicating that there is no information).
The PCS 200C receives the second output control instruction signal transmitted from the private power generation output control apparatus 100, and processes the received second output control instruction signal with priority. The PCS 200C preferentially processes the output control instruction signal received most recently. The PCS 200C controls the output upper limit of the PCS 200C based on information indicating the PV output upper limit included in the second output control instruction signal and information indicating the slope control. As a result, the output upper limit of the PCS 200C changes from a3 to a0 at time t2, as indicated by the no-slope SN of Example 1 in FIG.

(Example 2)
Private power generation output control device 100 transmits a first output control instruction signal to PCS 200C. Here, the first output control instruction signal is “a2” as information indicating the PV output upper limit, and “indicating that the output upper limit is changed to a2 between time t1 and time t3” as information indicating the slope control. Information (information indicating that slope control is performed).
The PCS 200C receives the first output control instruction signal transmitted from the private power generation output control device 100, and follows the information indicating the PV output upper limit included in the received first output control instruction signal and the information indicating the slope control. The output upper limit of the PCS 200C is controlled. When the PCS 200C controls the output upper limit of the PCS 200C to change from a1 to a3 (a1 <a3 <a2) as shown in SA1 with a slope in Example 2 of FIG. 15, the private power generation output control device 100 Transmits a second output control instruction signal to the PCS 200C. Here, the second output control instruction signal is “a0” as information indicating the PV output upper limit, and “information indicating that the output upper limit is changed to a0 between time t2 and t4 as information indicating the slope control. (Information indicating that slope control is performed).
The PCS 200C receives the second output control instruction signal transmitted from the private power generation output control apparatus 100, and processes the received second output control instruction signal with priority. The PCS 200C preferentially processes the output control instruction signal received most recently. The PCS 200C controls the output upper limit of the PCS 200C based on information indicating the PV output upper limit included in the second output control instruction signal and information indicating the slope control. As a result, the output upper limit of the PCS 200C changes from a3 to a0 between time t2 and time t4, as indicated by SA2 with slope in Example 2 of FIG.

(Operation of power management system)
FIG. 16 is a sequence chart illustrating an example of the operation of the power management system according to the first embodiment.
(Step S1)
The communication unit 110 of the private power generation output control device 100 receives an output control signal transmitted from a server (not shown) of a general power transmission and distribution company, and outputs the received output control signal to the information processing unit 130. The acquisition unit 131 of the information processing unit 130 acquires the output control signal output from the communication unit 110 and outputs the acquired output control signal to the output power deriving unit 132.
(Step S2)
The output power deriving unit 132 acquires the output control signal output by the acquiring unit 131 and acquires information on the suppression rate included in the acquired output control signal. The output power deriving unit 132 outputs the acquired information on the suppression rate to the power consumption deriving unit 133. The power consumption deriving unit 133 acquires information on the suppression rate output by the output power deriving unit 132. The power consumption deriving unit 133 acquires information on the load M included in the load information 123 of the storage unit 120. The power consumption deriving unit 133 acquires information on the power generation facility capacity included in the power generation facility capacity information 124 of the storage unit 120.
The power consumption deriving unit 133 derives an increase in power consumption based on the information indicating the suppression rate, the acquired information on the load M and the information on the power generation facility capacity, and information indicating the derived increase in power consumption Is output to the creation unit 134.
(Step S3)
The creation unit 134 acquires information indicating the increase in power consumption output from the power consumption deriving unit 133. The creation unit 134 creates a power consumption instruction signal destined for the HEMS server 300 based on the information indicating the increase in power consumption, and outputs the created power consumption instruction signal to the communication unit 110.
(Step S4)
The communication unit 110 transmits the power consumption instruction signal output from the information processing unit 130 to the HEMS server 300.

(Step S5)
The HEMS server 300 receives the power consumption instruction signal transmitted by the private power generation output control device 100, and controls the power consumption of the load M of the consumer based on the received power consumption instruction signal.
(Step S6)
The output power deriving unit 132 of the private power generation output control apparatus 100 derives the PV output upper limit based on the acquired suppression rate. The output power deriving unit 132 outputs the generated power information indicating the derived PV output upper limit to the creating unit 134.
(Step S7)
The creation unit 134 acquires the generated power information output by the output power deriving unit 132, and generates information indicating the PV output upper limit based on the acquired generated power information and information indicating the increase in power consumption. . The creation unit 134 determines whether to perform slope control based on information indicating an increase in power consumption. The creation unit 134 creates information indicating the output upper limit of PV and information indicating slope control, creates an output control instruction signal destined for the PCS 200C, and outputs the created output control instruction signal to the communication unit 110. . Here, the description will be continued for a case where the output control instruction signal includes information indicating the output upper limit of a set of PV and information indicating slope control.
(Step S8)
Communication unit 110 transmits the output control instruction signal output from information processing unit 130 to PCS 200C.
(Step S9)
The communication unit 210 of the PCS 200 </ b> C receives the output control instruction signal transmitted by the private power generation output control device 100, and outputs the received output control instruction signal to the information processing unit 230.
The acquisition unit 231 of the information processing unit 230 acquires the output control instruction signal output from the communication unit 210 and outputs the acquired output control instruction signal to the output control unit 232. The output control unit 232 acquires information indicating the PV output upper limit included in the output control instruction signal output by the acquisition unit 231 and information indicating slope control, information indicating the acquired PV output upper limit, and the slope The power output from the PV is controlled according to the information indicating the control. Specifically, the output control unit 232 controls the upper limit value of the PV generated power according to the PV output upper limit indicated by the information indicating the PV output upper limit and the information indicating the slope control. With this configuration, the output of the PCS 200C is controlled.

In the first embodiment described above, the case where the power management system 10 includes the four HEMS servers 300 has been described. For example, the power management system 10 may include one to three HEMS servers 300, or may include five or more HEMS servers 300.
In the first embodiment described above, the case where the power management system 10 includes one PCS 200C has been described. For example, the power management system 10 may include two or more PCSs.
In the first embodiment described above, the case where the power management system 10 includes one private power generation output control device 100 has been described, but this is not restrictive. For example, the power management system 10 may include two or more private power generation output control devices.
In the first embodiment described above, the case where the HEMS server 300 and the private power generation output control device 100 are connected has been described, but this is not restrictive. For example, a HEMS controller having a controller function and the private power generation output control device 100 may be connected together with the HEMS server 300 or instead of the HEMS server 300.
In the first embodiment described above, the case where the HEMS server 300 includes the load M has been described. For example, a load having a function that can be directly connected to the network 50 instead of the load M and the private power generation output control device 100 may be connected.
In 1st Embodiment mentioned above, although PV was demonstrated as an example of private power generation, it is not this limitation. For example, the present invention can be applied not only to PV but also to private power generation other than PV, such as a fuel cell.
In the first embodiment described above, the private power generation output control device 100 of the power management system 10 includes the first output control instruction information including information indicating the PV output upper limit and information indicating the slope control, and the PV output upper limit. In the above description, the output control instruction signal including the second output control instruction information including the information indicating the slope control and the information indicating the slope control has been described. The private power generation output control device 100 includes a first output control instruction signal including information indicating the PV output upper limit and information indicating the slope control, information indicating the PV output upper limit, and information indicating the slope control. The case of creating the second output control instruction signal has been described. That is, although the case where the private power generation output control apparatus 100 can create two types of signals has been described, the present invention is not limited to this. For example, the private power generation output control device 100 may generate any one of the above-described signals.
In the first embodiment described above, the case where the private power generation output control device 100 of the power management system 10 creates an output control instruction signal including information indicating the PV output upper limit and information indicating the slope control has been described. However, this is not the case. For example, the private power generation output control apparatus 100 may transmit an output control instruction signal including information indicating the PV output upper limit. In this case, the PCS 200C stores power ratio information, which is information indicating slope control, in the storage unit 220. The PCS 200 </ b> C performs control based on the information indicating the PV output upper limit included in the output control instruction signal transmitted by the private power generation output control device 100 and the power ratio information stored in the storage unit 220. With this configuration, the amount of information included in the output control instruction signal can be reduced.

According to the power management system of the first embodiment, the slope of the output upper limit of the PCS 200C is changed by the output control instruction signal transmitted by the private power generation output control device 100. By comprising in this way, it can prevent giving a load suddenly to a general power transmission and distribution company. Specifically, when the private power generation output control device 100 transmits an output control instruction signal to the PCS 200C, it is caused by the fact that the PV output upper limit is relaxed by demand creation, and the general power transmission / distribution company, etc. In some cases, it is caused by a control command from the grid operator.
When transmitting the output control instruction signal, the private power generation output control device 100 transmits the information including information indicating that the slope control is not performed if the PV output is reduced. Further, when transmitting the output control instruction signal, the private power generation output control device 100 transmits the information including the information indicating that the slope control is performed when the control command is caused. The PCS 200C performs output control according to information indicating the output upper limit of PV included in the output control instruction signal transmitted by the private power generation output control device 100 and information indicating slope control. Since the conventional PCS can only perform slope control, a steep change occurs in the residual demand. However, according to the PCS 200C, the PV output upper limit included in the output control instruction signal transmitted by the private power generation output control device 100 is set. Since output control can be performed according to the information indicating and the information indicating the slope control, there is no sharp change in the residual demand.

(Second Embodiment)
(Power management system)
FIG. 1 can be applied to the power management system 10a of the second embodiment. However, instead of the private power generation output control device 100, a private power generation output control device 100a is provided.
The power management system 10a includes a private power generation output control device 100a, a HEMS server 300A, a HEMS server 300B, a HEMS server 300C, a HEMS server 300D, and a PCS 200C.
The private power generation output control device 100a, the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, the HEMS server 300D, and the PCS 200C are connected via the network 50. The private power generation output control device 100a is connected to a server of a general power transmission and distribution company.
Further, the private power generation output control device 100a includes a HEMS server 300A possessed by a consumer A that does not perform private power generation, a HEMS server 300B possessed by a consumer B that does not perform private power generation, and a HEMS possessed by the consumer C that performs private power generation. Communication is performed via the network 50 with the server 300C and the HEMS server 300D of the customer D who does not perform private power generation.
In the power management system 10a of the second embodiment, when the private power generation output control device 100a instructs the consumer C that performs private power generation to create demand, the change in residual demand is sharply caused by the demand creation. In order to prevent this, the time change of the upper limit value of the power output by the PCS 200C is controlled. The private power generation output control device 100a divides demand creation when the output of the PCS 200C is assumed to exceed 100% when deriving information indicating the output upper limit of PV.

Hereinafter, among the private power generation output control device 100a, the HEMS server 300A, the HEMS server 300B, the HEMS server 300C, the HEMS server 300D, and the PCS 200C constituting the power management system 10a, This will be described in detail.
FIG. 17 is a block diagram illustrating a private power generation output control device included in the power management system of the second embodiment.
(In-house power generation output control device)
The private power generation output control device 100a includes devices such as a personal computer, a server, a smartphone, a tablet terminal, or an industrial computer.
The private power generation output control device 100a includes a communication unit 110, a storage unit 120a, an information processing unit 130a, and an address bus and a data bus for electrically connecting each component as shown in FIG. Bus line 150.

  The storage unit 120a is realized by, for example, a RAM, a ROM, an HDD, a flash memory, or a hybrid storage device in which a plurality of these are combined. Instead of being provided as a part of the private power generation output control device 100a, a part or all of the storage unit 120a is accessed via the network 50 by the processor of the private power generation output control device 100a such as a NAS or an external storage server. It may be realized by a possible external device. The storage unit 120a stores a program 121 executed by the information processing unit 130a, an application 122a, load information 123, and power generation facility capacity information 124.

The application 122a causes the private power generation output control device 100a to receive the output control signal transmitted by the server of the general power transmission and distribution company. The application 122a causes the private power generation output control device 100a to derive an increase in power consumption based on the suppression rate included in the output control signal. The application 122a generates a power consumption instruction signal based on information indicating the derived increase in power consumption. The application 122a causes the private power generation output control device 100a to transmit the created power consumption instruction signal to the HEMS server 300.
Further, the application 122a causes the private power generation output control device 100a to derive the PV output upper limit based on the suppression rate included in the output control signal and the derived increase in power consumption. The application 122a causes the private power generation output control device 100a to create an output control instruction signal including information indicating the PV output upper limit and information indicating the slope control.
However, when demand creation is performed based on the increase in the derived power consumption, the application 122a sends the derived power consumption to the private power generation output control device 100a when the output upper limit of the PCS 200C exceeds 100%. Based on the amount of increase in power, demand creation is divided and performed so as to gradually become the amount of increase in power consumption. Furthermore, the application 122a allows the private power generation output control device 100a to provide information indicating an output upper limit of 100% or less of PV as information indicating the output upper limit of PV, and slope control when the output upper limit of the PCS 200C exceeds 100%. And an output control instruction signal including information indicating.

The information processing unit 130a is, for example, a software function unit that is realized by a processor such as a CPU executing the program 121 stored in the storage unit 120a or the application 122a. Note that all or part of the information processing unit 130a may be realized by hardware such as LSI, ASIC, or FPGA, or may be realized by a combination of a software function unit and hardware.
The information processing unit 130a includes, for example, an acquisition unit 131, an output power deriving unit 132, a power consumption deriving unit 133, and a creating unit 134a.

The creation unit 134a can apply the creation unit 134 of the first embodiment. However, the creation unit 134a determines whether or not the upper limit value of the generated power of the PV exceeds the output upper limit of the PCS 200C when slope control is not performed for the increased demand. When the upper limit value of the PV generated power does not exceed the output upper limit of the PCS 200C, the creation unit 134 of the first embodiment can be applied.
When the upper limit value of the generated power of the PV exceeds the output upper limit (maximum output) of the PCS 200C, the creation unit 134a creates a power consumption instruction signal for gradually increasing demand, and the created power consumption instruction signal Is output to the communication unit 110. Here, when the demand is gradually increased, the demand may be monotonously increased or may be increased stepwise. Here, as an example, the description will be continued for a case where the demand is divided into a plurality of steps and increased step by step. The creation unit 134a creates a power consumption instruction signal destined for the HEMS server 300 based on the information indicating the power consumption for one step when the demand is increased step by step, and communicates the created power consumption instruction signal with the communication Output to the unit 110.
In addition, when the upper limit value of the PV generated power exceeds the output upper limit (maximum output) of the PCS 200C, the creation unit 134a outputs the output below the PCS 200C output upper limit (maximum output) as information indicating the PV output upper limit. As the information indicating the slope control, an output control instruction signal including information indicating the time change of the upper limit value of the power output by the PCS 200C is generated while the demand is generated by the information indicating the power consumption for one stage. . The creation unit 134a outputs the created output control instruction signal to the communication unit 110.

Here, the processing for performing the slope control will be described in detail with respect to the case where the private power generation output control device 100a increases the demand and the slope control is not performed.
FIG. 18 is a diagram illustrating an example (part 1) of the operation of the power management system according to the second embodiment.
The case where the output upper limit changes from a3 to A (a3> A) as shown in (1) will be described. Here, the decrease from the output upper limit a3 to the output upper limit A is the decrease from the output upper limit a3 to the output upper limit a1 (a3>A> a1) by the output control signal from the server of the general power transmission and distribution company, and from a1 An increase due to an increase in demand for A (A> a1) is included.

As illustrated in (2), the creation unit 134a, at time t1, information indicating that the output upper limit of the PCS 200C is controlled from a3 to X1 (a3 <X1), and from X1 to X2 (X2 <X1). An output control instruction signal including information indicating that slope control is performed is output to communication unit 110. Specifically, the creation unit 134a displays “X1” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a3 to X1 at time t1 as information indicating the slope control (slope control). Output information between the time t1 and the time t11 as information indicating slope control and “X2” as information indicating the output upper limit of PV. An output control instruction signal including second output control instruction information including information indicating that the upper limit changes from X1 to X2 (information indicating that slope control is performed) is created.
In addition, the creation unit 134a includes “X1” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from a3 to X1 at time t1” as information indicating the slope control. The output control instruction signal, “X2” as information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from X1 to X2 between time t1 and time t11” as information indicating the slope control, A second output control instruction signal including
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t1. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b11 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t1 to time t11, the sudden change of the residual demand does not occur.

As illustrated in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from X2 to X1 (X2 <X1) and slope control from X1 to X2 at time t11. An output control instruction signal including information indicating “” is output to the communication unit 110. Specifically, the creation unit 134a displays “X1” as information indicating the PV output upper limit, and “information indicating that the output upper limit changes from X2 to X1 at time t11” (slope control) as information indicating the slope control. Output information between the time t11 and the time t12 as information indicating the slope control and “X2” as information indicating the output upper limit of the PV. An output control instruction signal including second output control instruction information including “information indicating that the upper limit changes from X1 to X2 (information indicating that slope control is performed)” is created.
The creation unit 134a also includes “X1” as information indicating the PV output upper limit and “information indicating that the output upper limit changes from X2 to X1 at time t11” as information indicating the slope control. The output control instruction signal, “X2” as information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from X1 to X2 between time t11 and time t12” as information indicating the slope control, A second output control instruction signal including
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t11. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b11 to b12 at time t11 according to the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t11 to time t12, the residual demand does not change sharply.

The creation unit 134a, as shown in (2), at time t12, information indicating that the output upper limit of the PCS 200C is controlled from X2 to X3 (X2 <X3), and from X3 to A (X3> A). An output control instruction signal including information indicating that slope control is performed is output to communication unit 110. Specifically, the creation unit 134a displays “X3” as information indicating the PV output upper limit and “information indicating that the output upper limit changes from X2 to X3 at time t12” (slope control) as information indicating the slope control. Output information between the time t12 and the time t2 as information indicating the slope control and “A” as the information indicating the output upper limit of the PV. An output control instruction signal including second output control instruction information including information indicating that the upper limit changes from X3 to A (information indicating that slope control is performed) is created.
The creation unit 134a also includes “X3” as information indicating the PV output upper limit and “information indicating that the output upper limit changes from X2 to X3 at time t12” as information indicating the slope control. The output control instruction signal, “A” as information indicating the output upper limit of PV, and “information indicating that the output upper limit changes from X3 to A between time t12 and time t2” as information indicating the slope control, A second output control instruction signal including
In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t12. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t12.
As shown in (3), the HEMS server 300 increases the demand from b12 to b2 at time t12 in accordance with the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t12 to time t2, there is no sharp change in the residual demand.

(Operation of private power generation output control device)
FIG. 19 is a flowchart illustrating an example of the operation of the private power generation output control device included in the power management system of the second embodiment.
FIG. 20 is a diagram illustrating an example of the operation of the power management system according to the second embodiment. FIG. 20 is a view similar to FIG. 18, but is used here to describe each symbol shown in the flowchart of FIG. 19.
As shown in FIG. 20, a (t) is the output upper limit of the PCS 200C at time t, and is the maximum output considering the slope control. a (t) is expressed as a percentage [%]. X1 is a first threshold value, and is controlled so that a (t) does not exceed X1. X1 is expressed as a percentage [%]. X2 is a second threshold value, and a demand is additionally created when a (t) is X2 or less. X2 is expressed as a percentage [%].

A is a target value for the output of the PCS 200C, and is a final target value for the output of the PCS 200C. A is expressed as a percentage [%]. YA is the total amount (target) of demand creation and is the final target value for demand creation. YA is expressed in watts [W]. Y1 (t) is a demand creation amount that can change the output upper limit of the PCS 200C by [X1-a (t)] [%], and is the total installed capacity of the target PV × [X1-a (t)]. Y1 (t) is expressed in watts [W]. YR (t) is the remaining amount of demand creation and is YA- [total actual demand creation]. YR (t) is expressed in watts [W]. AR (t) is a PCS control instruction value when YR (t) demand is created. AR (t) is expressed as a percentage [%]. Returning to FIG. 19, the operation of the private power generation output control apparatus 100a will be described.
(Step S11)
The creation unit 134a determines whether or not a (t) <X1.
(Step S12)
If the creation unit 134a determines that a (t) <X1, it determines whether Y1 (t) ≦ YR (t).
(Step S13)
If the creation unit 134a determines that Y1 (t) ≦ YR (t), the creation unit 134a generates a power consumption instruction signal addressed to the HEMS server 300 based on the information indicating the increase in power consumption for Y1 (t). The generated power consumption instruction signal is output to the communication unit 110. The communication unit 110 transmits the power consumption instruction signal output from the creation unit 134 a to the HEMS server 300.
(Step S14)
If the creation unit 134a determines that Y1 (t) ≦ YR (t), the creation unit 134a creates a power consumption instruction signal destined for the HEMS server 300 based on the information indicating the increase in power consumption for YR (t). Then, the generated power consumption instruction signal is output to the communication unit 110. The communication unit 110 transmits the power consumption instruction signal output from the creation unit 134 a to the HEMS server 300.
(Step S15)
The creation unit 134a creates an output control instruction signal including “X1” as information indicating the PV output upper limit and information indicating that slope control is not performed as information indicating the slope control, and the generated output control instruction The signal is output to the communication unit 110. The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C.

(Step S16)
The creation unit 134a creates and creates an output control instruction signal including “AR (t)” as information indicating the PV output upper limit and information indicating that slope control is not performed as information indicating slope control. An output control instruction signal is output to the communication unit 110. The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C.
(Step S17)
When the process of step S15 is completed, when the process of step S16 is completed, or when the creation unit 134a determines in step S11 that a (t) <X1, the creation unit 134a sets the PV output upper limit. An output control instruction signal including “A” as information indicating and information indicating that slope control is performed as information indicating slope control is generated, and the generated output control instruction signal is output to the communication unit 110. The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C.
(Step S18)
The creation unit 134a determines whether the creation of demand is completed by determining whether YR (t) is zero. When the creation of demand is completed, the process ends.
(Step S19)
If the creation of demand has not been completed, the creation unit 134a determines whether a (t) ≦ X2. If a (t) ≦ X2, the process proceeds to step S12.
(Step S20)
When it is determined that a (t) ≦ X2, the creating unit 134a determines whether or not a (t) ≦ A. If a (t) ≦ A, the process proceeds to step S12. If a (t) ≦ A is not satisfied, the process proceeds to step S19.

FIG. 21 is a diagram illustrating an example (part 2) of the operation of the power management system according to the second embodiment. In the example shown in FIG. 21, the slope control is not performed for the increased demand. In FIG. 21, as an example, X1 = 90, X2 = 70, the output upper limit is reduced from 60% to 10% by the control command, and 40% is relaxed by demand creation, and the target PCS output is 50% ( 10% + 40%) will be described.
The case where the output upper limit changes from 60% to 50% as shown in (1) will be described. Here, the decrease from the output upper limit 60% to the output upper limit 50% is the decrease from the output upper limit 60% to the output upper limit 10% by the output control signal from the server of the general power transmission and distribution company, and 10% to 50%. % Increase due to demand creation.

As shown in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from 60% to 90% and slope control from 90% to 70% at time t1. An output control instruction signal including the information shown is output to the communication unit 110. Specifically, the creation unit 134a includes first output control instruction information including 90% as information indicating an output upper limit of PV, and information indicating that slope control is not performed as information indicating slope control, and PV An output control instruction signal including 70% as information indicating the output upper limit and second output control instruction information including information indicating that slope control is performed as information indicating slope control is created.
In addition, the creation unit 134a includes a first output control instruction signal including 90% as information indicating the PV output upper limit and information indicating that slope control is performed as information indicating the slope control, and an output upper limit of PV. A second output control instruction signal including 70% as information indicating the slope control and information indicating that the slope control is performed as the information indicating the slope control may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t1. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b11 at time t1, according to the power consumption instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t1 to time t11, the sudden change of the residual demand does not occur.

As illustrated in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from 70% to 80% and slope control from 80% to 50% at time t11. An output control instruction signal including the information shown is output to the communication unit 110. Specifically, the creation unit 134a includes first output control instruction information including 80% as information indicating the output upper limit of PV, and information indicating that slope control is not performed as information indicating slope control, and PV An output control instruction signal including 50% as information indicating the output upper limit and second output control instruction information including information indicating that slope control is performed as information indicating slope control is created.
The creation unit 134a also includes a first output control instruction signal including 80% as information indicating the PV output upper limit and information indicating that slope control is not performed as information indicating slope control, and PV output. A second output control instruction signal including 50% as information indicating the upper limit and information indicating that slope control is performed as information indicating slope control may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t11. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t11.
As shown in (3), the HEMS server 300 increases the demand from b11 to b2 at time t11 according to the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t11 to time t2, there is no sharp change in the residual demand.

FIG. 22 is a diagram illustrating an example (part 3) of the operation of the power management system according to the second embodiment. In the example shown in FIG. 22, the slope control is not performed for the increased demand. In FIG. 22, as an example, X1 = 90, X2 = 70, the output upper limit is reduced from 90% to 10% by the control command, 40% is relaxed by demand creation, and the target PCS output is 50% ( The case of 10% + 40%) will be described.
A case where the output upper limit changes from 90% to 50% as shown in (1) will be described. Here, the decrease from the output upper limit of 90% to the output upper limit of 50% is the decrease by the output control signal from the general power transmission and distribution company of the output upper limit of 90% to the output upper limit of 10% and the demand of 10% to 50%. This includes the increase due to the increase in creation.

As shown in (2), the creation unit 134a outputs an output control instruction signal including information indicating that slope control is performed from 90% to 70% of the output upper limit of the PCS 200C to the communication unit 110 at time t1. To do. Specifically, the creation unit 134a creates an output control instruction signal including 70% as information indicating the PV output upper limit and information indicating that slope control is performed as information indicating slope control.
In this case, the communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 does not increase the demand until time t11 according to the power consumption instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t1 to time t11, the sudden change of the residual demand does not occur.

As shown in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from 70% to 90% and slope control from 90% to 70% at time t11. An output control instruction signal including the information shown is output to the communication unit 110. Specifically, the creation unit 134a includes first output control instruction information including 90% as information indicating an output upper limit of PV, and information indicating that slope control is not performed as information indicating slope control, and PV An output control instruction signal including 70% as information indicating the output upper limit and second output control instruction information including information indicating that slope control is performed as information indicating slope control is created.
The creation unit 134a also includes a first output control instruction signal including 90% as information indicating the PV output upper limit, and information indicating that slope control is not performed as information indicating slope control, and PV output. A second output control instruction signal including 70% as information indicating the upper limit and information indicating that slope control is performed as information indicating slope control may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t11. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t11.
As shown in (3), the HEMS server 300 increases the demand from b1 to b11 at time t11 according to the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the remaining demand changes gently from time t11 to time t12, there is no sharp change in the remaining demand.

As shown in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from 70% to 90% and slope control from 90% to 50% at time t12. An output control instruction signal including the information shown is output to the communication unit 110. Specifically, the creation unit 134a includes first output control instruction information including 90% as information indicating an output upper limit of PV, and information indicating that slope control is not performed as information indicating slope control, and PV An output control instruction signal including 50% as information indicating the output upper limit and second output control instruction information including information indicating that slope control is performed as information indicating slope control is created.
The creation unit 134a also includes a first output control instruction signal including 90% as information indicating the PV output upper limit, and information indicating that slope control is not performed as information indicating slope control, and PV output. A second output control instruction signal including 50% as information indicating the upper limit and information indicating that slope control is performed as information indicating slope control may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t12. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t12.
As shown in (3), the HEMS server 300 increases the demand from b11 to b2 at time t12 in accordance with the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t12 to time t2, there is no sharp change in the residual demand.

FIG. 23 is a diagram illustrating an example (part 4) of the operation of the power management system according to the second embodiment. In the example shown in FIG. 23, the slope control is not performed for the increased demand. In FIG. 23, as an example, X1 = 90, X2 = 70, the output upper limit is reduced from 50% to 10% by the control command, and 40% is relaxed by demand creation, and the target PCS output is 50% ( The case of 10% + 40%) will be described.
The case where the output upper limit is maintained from 50% to 50% as shown in (1) will be described. Here, the maintenance from the output upper limit of 50% to the output upper limit of 50% is the decrease by the output control signal from the general power transmission / distribution company from the output upper limit of 50% to the output upper limit of 10% and the demand of 10% to 50%. This includes the increase due to the increase in creation.

As shown in (2), the creation unit 134a performs information indicating that the output upper limit of the PCS 200C is controlled from 50% to 90% and slope control from 90% to 50% at time t1. An output control instruction signal including the information shown is output to the communication unit 110. Specifically, the creation unit 134a includes first output control instruction information including 90% as information indicating an output upper limit of PV, and information indicating that slope control is not performed as information indicating slope control, and PV An output control instruction signal including 50% as information indicating the output upper limit and second output control instruction information including information indicating that slope control is performed as information indicating slope control is created.
The creation unit 134a also includes a first output control instruction signal including 90% as information indicating the PV output upper limit, and information indicating that slope control is not performed as information indicating slope control, and PV output. A second output control instruction signal including 50% as information indicating the upper limit and information indicating that slope control is performed as information indicating slope control may be created.
The communication unit 110 transmits the output control instruction signal output from the creation unit 134a to the PCS 200C at time t1. In addition, the communication unit 110 may transmit the first output control instruction signal and the second output control instruction signal output from the creation unit 134a to the PCS 200C at time t1.
As shown in (3), the HEMS server 300 increases the demand from b1 to b2 at time t1, in accordance with the output control instruction signal transmitted by the private power generation output control device 100a.
In this case, as shown in (4), since the residual demand changes gently from time t1 to time t2, there is no sharp change in the residual demand.

(Operation when communication error occurs)
An operation when a communication abnormality occurs between the private power generation output control device 100a and the PCS 200C will be described.
FIG. 24 is a diagram illustrating an example of the operation of the power management system according to the second embodiment.
When a communication abnormality or the like occurs, the output control unit 232 of the PCS 200C causes the storage unit 220 to store in advance the state where there is no output control instruction signal to be processed for the first time due to the absence of the acquired update schedule. The stored second schedule is acquired, and the output upper limit of private power generation is controlled according to the acquired second schedule. In the acquired second schedule, information indicating a preset output upper limit (hereinafter referred to as “second output upper limit control information”) and information indicating slope control are preset as information indicating the PV output upper limit. Information indicating the rate of change in power (hereinafter referred to as “second power change rate information”) is included. An example of the second power change rate information is 0%. In this case, as shown by the solid line in FIG. 24, the output of the PCS 200C is slope-controlled from 100% to 0% according to the second power change rate information.
When communication abnormality is large-scale and continues for a long period of time, a large number of PCSs may shift to a fixed schedule all at once. The second power change rate is smaller than the normal power change rate. In this case, a large-scale demand change occurs, but the slope is controlled more gently than in normal times.

In the above-described second embodiment, the case where the power management system 10a includes the four HEMS servers 300 has been described. For example, the power management system 10a may include one to three HEMS servers 300, or may include five or more HEMS servers 300.
In the above-described second embodiment, the case where the power management system 10a includes one PCS 200C has been described. For example, the power management system 10a may include two or more PCSs.
In the above-described second embodiment, the case where the power management system 10a includes one private power generation output control device 100a has been described. For example, the power management system 10a may include two or more private power generation output control devices.
In the above-described second embodiment, the case where the HEMS server 300 and the private power generation output control device 100a are connected has been described. For example, a HEMS controller having a controller function and the private power generation output control device 100a may be connected together with the HEMS server 300 or instead of the HEMS server 300.
In the above-described second embodiment, the case where the HEMS server 300 includes the load M has been described. For example, a load having a function that can be directly connected to the network 50 instead of the load M may be connected to the private power generation output control device 100a.
In 2nd Embodiment mentioned above, although PV was demonstrated as an example of private power generation, it is not this limitation. For example, the present invention can be applied not only to PV but also to private power generation other than PV, such as a fuel cell.
In the second embodiment described above, the private power generation output control device 100a of the power management system 10a includes the first output control instruction information including the information indicating the PV output upper limit and the information indicating the slope control, the PV output upper limit. In the above description, the output control instruction signal including the second output control instruction information including the information indicating the slope control and the information indicating the slope control has been described. The private power generation output control device 100a includes a first output control instruction signal including information indicating the PV output upper limit, information indicating the slope control, information indicating the PV output upper limit, and information indicating the slope control. The case where the second output control instruction signal including the above is generated has been described. That is, although the case where the private power generation output control apparatus 100 can create two types of signals has been described, the present invention is not limited to this. For example, the private power generation output control device 100a may generate any one of the signals described above.
In the second embodiment described above, the case where the private power generation output control device 100a of the power management system 10a creates an output control instruction signal including information indicating the PV output upper limit and information indicating slope control has been described. However, this is not the case. For example, the private power generation output control device 100a may transmit an output control instruction signal including information indicating information indicating the PV output upper limit. In this case, the PCS 200C stores power ratio information, which is information indicating slope control, in the storage unit 220a. The PCS 200C performs control based on information indicating the PV output upper limit included in the output control instruction signal transmitted by the private power generation output control device 100a and the power ratio information stored in the storage unit 220a. With this configuration, the amount of information included in the output control instruction signal can be reduced.
In the second embodiment described above, the case where the PCS 200C operates according to the second schedule when a communication abnormality occurs between the private power generation output control device 100a and the PCS 200C has been described. For example, the present invention can be applied to a case where a communication abnormality occurs between the private power generation output control device 100 and the PCS 200C.

According to the power management system of the second embodiment, the slope of the output of the PCS 200C is changed by the output control instruction signal transmitted by the private power generation output control device 100a. By comprising in this way, it can prevent giving a load suddenly to a general power transmission and distribution company. Specifically, when the private power generation output control device 100a transmits an output control instruction signal to the PCS 200C, a case such as a case where the PV output is alleviated due to demand creation and a system such as a general power transmission and distribution company In some cases, it is caused by a control command from the operator.
When transmitting the output control instruction signal, the private power generation output control device 100a transmits the information including information indicating that the slope control is not performed when the output of the PV is reduced. Further, when transmitting the output control instruction signal, the private power generation output control device 100a transmits the information including information indicating that the slope control is performed when the control command is caused. The PCS 200C performs output control according to information indicating the PV output upper limit included in the output control instruction signal transmitted by the private power generation output control device 100a and information indicating slope control.
Furthermore, the private power generation output control device 100a divides demand creation when the output of the PCS 200C is assumed to exceed the maximum output (100%) of the PCS 200C when the output upper limit of PV is indicated. By configuring in this way, the private power generation output control device 100a can reduce the indicated value when the output control instruction signal transmitted to the PCS 200C indicates the PV output upper limit.

<Configuration example>
As a configuration example, a power control device (in the embodiment, PCS200C) that controls the upper limit value of the power generated by a private power generation consumer who is a consumer (in the embodiment, customer C) that performs private power generation. A communication unit that receives an output control instruction signal including power change ratio information (information indicating slope control in the embodiment) that is information indicating a time change of the upper limit value of the power output from the private power generation; and output control. The power control device includes an output control unit that controls an output upper limit of private power generation based on power change rate information included in the instruction signal.
As an example of the configuration, in the power control apparatus, the output control instruction signal includes output upper limit control information (information indicating the PV output upper limit in the embodiment) that is information for controlling the upper limit value of the power generated by the private power generation. The communication unit receives a plurality of output control instruction signals, and the output control unit outputs the output upper limit of private power generation based on the output upper limit control information and the power change rate information included in each of the plurality of output control instruction signals. To control.
As an example of the configuration, in the power control apparatus, the output control unit controls the output upper limit of private power generation according to the latest output control instruction signal among the plurality of output control instruction signals received by the communication unit.
As an example of the configuration, in the power control apparatus, when the output control instruction signal does not include power change ratio information, the output control unit includes preset first power change ratio information and an output included in the output control instruction signal. Based on the upper limit control information, the output upper limit of private power generation is controlled.
As an example of the configuration, in the power control apparatus, the output control unit, when there is no output control instruction signal to be processed, continues for the first time, the preset second output upper limit control information and the preset second Based on the power change rate information, the output upper limit of private power generation is controlled.

As one configuration example, power that is information indicating time variation of the upper limit value of the power output by the power control device that adjusts the upper limit value of the power output from the private power generation that the private power generation consumer who is the consumer who performs the private power generation outputs An in-house power generation output control device (in the embodiment, an in-house power generation output control device) includes: a creation unit that creates an output control instruction signal including change rate information; and a communication unit that transmits the output control instruction signal created by the creation unit to the power control device. Power generation output control device 100, private power generation output control device 100a).
As one configuration example, a power control device that controls the upper limit value of the power generated by the private power generation that the private power generation consumer who is the consumer who performs the private power generation, and the upper limit value of the generated power of the private power generation of the power control device are controlled. A power management system comprising a private power generation output control device, wherein the private power generation output control device includes an output control instruction signal including power change rate information that is information indicating a temporal change in the upper limit value of power output by the power control device. And a private power generation output control device communication unit (in the embodiment, communication unit 110) that transmits the output control instruction signal created by the creation unit to the power control device. Based on the power control device communication unit (in the embodiment, the communication unit 210) that receives the control instruction signal and the power change rate information included in the output control instruction signal, the output upper limit for controlling the output of private power generation is controlled. And a control unit, a power management system.

  As mentioned above, although embodiment was described, these embodiment was shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, changes, and combinations can be made without departing from the scope of the invention. These embodiments are included in the scope and gist of the invention, and at the same time, are included in the invention described in the claims and the equivalent scope thereof.

In addition, you may make it implement | achieve the private power generation output control apparatus 100 mentioned above, the private power generation output control apparatus 100a, and PCS200C. In that case, a program for realizing the function of each functional block is recorded on a computer-readable recording medium. The program recorded on the recording medium may be read by a computer system and executed by the CPU. The “computer system” here includes hardware such as an OS (Operating System) and peripheral devices.
The “computer-readable recording medium” refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, and a CD-ROM. The “computer-readable recording medium” includes a storage device such as a hard disk built in the computer system.

Furthermore, the “computer-readable recording medium” may include a medium that dynamically holds a program for a short time. What holds the program dynamically for a short time is, for example, a communication line when the program is transmitted via a network such as the Internet or a communication line such as a telephone line.
Further, the “computer-readable recording medium” may include a medium that holds a program for a certain period of time, such as a volatile memory inside a computer system serving as a server or a client. The program may be for realizing a part of the functions described above. Further, the program may be a program that can realize the above-described functions in combination with a program already recorded in the computer system. The program may be realized using a programmable logic device. The programmable logic device is, for example, an FPGA (Field Programmable Gate Array).

The above-mentioned private power generation output control device 100, private power generation output control device 100a, and PCS 200C have a computer inside. The processes of the above-described private power generation output control device 100, private power generation output control device 100a, and PCS 200C are stored in a computer-readable recording medium in the form of a program, and the computer reads and executes this program. Thus, the above process is performed.
Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Further, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.
The program may be for realizing a part of the functions described above.
Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.

DESCRIPTION OF SYMBOLS 10, 10a ... Power management system, 50 ... Network, 100, 100a ... Private power generation output control apparatus, 110 ... Communication part, 120, 120a ... Storage part, 121 ... Program, 122, 122a ... Application, 123 ... Load information, 124 Power generation facility capacity information, 130, 130a ... Information processing unit, 131 ... Acquisition unit, 132 ... Output power deriving unit, 133 ... Power consumption deriving unit, 134, 134a ... Creation unit, 200C ... PCS, 210 ... Communication unit, 220 ... Storage unit, 221 ... Program, 222 ... App, 230 ... Information processing unit, 231 ... Acquisition unit, 232 ... Output control unit, 300A, 300B, 300C, 300D ... HEMS server

Claims (10)

A power control device that controls an upper limit value of power generated by a private power generation consumer who is a consumer who performs private power generation,
A communication unit that receives an output control instruction signal including power change rate information that is information indicating a time change of the upper limit value of the power output by the private power generation;
A power control apparatus comprising: an output control unit that controls an upper limit of output of the private power generation based on the power change rate information included in the output control instruction signal. The output control instruction signal includes output upper limit control information that is information for controlling the upper limit value of the generated power of the private power generation,
The communication unit receives a plurality of the output control instruction signals,
2. The power control according to claim 1, wherein the output control unit controls the output upper limit of the private power generation based on output upper limit control information and power change rate information included in each of the plurality of output control instruction signals. apparatus.   The said output control part controls the output upper limit of the said private power generation according to the newest output control instruction signal among the several said output control instruction signals which the said communication part received. Power control device.   When the output control instruction signal does not include the power change ratio information, the output control unit, based on preset first power change ratio information and output upper limit control information included in the output control instruction signal The power control apparatus according to any one of claims 1 to 3, which controls an upper limit of output of the private power generation.   When the state without the output control instruction signal to be processed continues for the first time, the output control unit, based on the preset second output upper limit control information and preset second power change rate information, The power control apparatus according to any one of claims 1 to 4, which controls an output upper limit of the private power generation. The power change rate information, which is information indicating the time change of the upper limit value of the power output by the power control device that adjusts the upper limit value of the power output from the private power generation that the private power generation consumer who is the consumer who performs the private power generation has. A creation unit for creating an output control instruction signal including:
A private power generation output control device comprising: a communication unit that transmits the output control instruction signal created by the creation unit to the power control device. A power control device that controls the upper limit value of the power generated by the private power generation of a private power generation consumer that is a consumer that performs private power generation, and the private power generation that controls the upper limit value of the power generated by the private power generation of the power control device A power management system comprising an output control device,
The private power generation output control device is:
A creation unit that creates an output control instruction signal including power change rate information that is information indicating a time change of the upper limit value of the power output by the power control device;
A private power generation output control device communication unit that transmits the output control instruction signal created by the creation unit to the power control device;
The power control device
A power control device communication unit that receives the output control instruction signal;
An output control unit comprising: an output control unit that controls an upper limit of output of the private power generation based on the power change rate information included in the output control instruction signal. A power control method executed by a power control apparatus that controls an upper limit value of the power generated by a private power generation consumer who is a consumer who performs private power generation,
Receiving an output control instruction signal including power change ratio information, which is information indicating a time change of the upper limit value of the power output from the private power generation;
Controlling the output upper limit of the private power generation based on the power change rate information included in the output control instruction signal. The power change rate information, which is information indicating the time change of the upper limit value of the power output by the power control device that adjusts the upper limit value of the power output from the private power generation that the private power generation consumer who is the consumer who performs the private power generation has. Creating an output control instruction signal including:
Transmitting the output control instruction signal created in the creating step to the power control device. A power control method executed by a private power generation output control device. A power control method executed by a power management system,
Information indicating the time change of the upper limit value of the electric power output by the electric power control apparatus that adjusts the upper limit value of the electric power output by the private electric power generation consumer possessed by the private electric power generation consumer, the private electric power generation output control apparatus Creating an output control instruction signal including power change rate information that is:
The private power generation output control device performs the step of transmitting the output control instruction signal created in the creating step to the power control device,
The power control device receiving an output control instruction signal including power change rate information, which is information indicating a time change of the upper limit value of the power output by the private power generation;
The power control device executes a step of controlling an output upper limit of the private power generation based on the power change rate information included in the output control instruction signal.

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