JP5758763B2 - Power control system, overall power control device, individual power control device, and power control method - Google Patents

Description

  The present invention relates to a technique for performing power interchange between individual power control apparatuses.

  In recent years, demand control, which is a technology for controlling power consumption in buildings and factories, has been attracting attention for the purpose of power saving measures. For example, consider a case where power consumption is reduced in a building in which a plurality of tenants are occupying. The system described in Patent Literature 1 sets an upper limit value of power consumption for the entire building and an upper limit value of power consumption for each tenant, and there is a possibility that the power consumption amount of the entire building may reach the upper limit value. Reduce the upper limit of power consumption for each tenant.

Japanese Patent No. 4032903

  However, in the technique disclosed in Patent Document 1, the entire building and each tenant occupying the building each determine an upper limit value of power consumption that is a constant value so that the upper limit value is not exceeded individually. The power consumption was controlled. For this reason, during the time elapse, such as when the tenant's power consumption control (load control), the entire building's power consumption control (decrease in the upper limit of the tenant's power consumption) is performed and the control collides. Appropriate control of power consumption that fluctuates with it is difficult.

  The present invention has been made under the circumstances described above, and provides a power control system, an overall power control device, an individual power control device, and a power control method that appropriately control power consumption that varies with time. For the purpose.

In order to achieve the above object, a power control system according to the present invention includes:
A power control system comprising: a plurality of individual power control devices that control power consumption of subordinate loads; and an overall power control device that controls power consumption of an entire group consisting of subordinate loads of the individual power control devices. There,
The individual power control device includes:
An individual upper limit setting means for setting an individual upper limit value indicating an upper limit of power consumption for each time period in the subordinate load;
Individual upper limit notification means for notifying the overall power control device of the individual upper limit for each set time period;
With
The overall power control device is:
An overall upper limit setting means for setting an overall upper limit value indicating an upper limit of the power consumption of the entire group;
Individual upper limit value acquisition means for acquiring an individual upper limit value for each time period from each individual power control device;
A change request for notifying the individual power control device of a request for changing the individual upper limit value in the predetermined time period when the total value of the individual upper limit values in the acquired predetermined time period exceeds the overall upper limit value Notification means;
With
The individual power control device includes:
Change request acquisition means for acquiring a request for changing the individual upper limit value in the predetermined time period from the overall power control device;
In response to a request for changing the individual upper limit value in the predetermined time zone, individual upper limit value changing means for changing the individual upper limit value in the predetermined time zone;
It is characterized by providing.

  According to the present invention, it is possible to appropriately control power consumption that varies with time.

It is a figure showing composition of an electric power control system concerning one embodiment. It is a sequence diagram which shows operation | movement of the electric power system which concerns on one Embodiment. It is a figure which shows the time transition of the local upper limit according to time zone, and the whole upper limit. It is a figure which shows an example of power consumption amount change.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating a configuration of a power control system 1 according to an embodiment. The power control system 1 controls the amount of power consumption in the building where the tenant A and the tenant B are occupying. The local demand control device 100 and the local demand control device 200 as individual power control devices, and the overall power control device The overall demand control device 300 is provided. The local demand control device 100, the local demand control device 200, and the overall demand control device 300 are communicably connected via a communication line 400 such as a wired or wireless LAN (Local Area Network).

  The local demand control device 100 is installed in the tenant A and controls the power consumption of the equipment devices 108-1 to 108-3 that are subordinate loads. The local demand control device 200 is installed in the tenant B and controls the power consumption of the facility devices 208-1 to 208-2 that are subordinate loads. The overall demand control device 300 controls the power consumption of the entire building, that is, the power consumption of the entire group consisting of the equipment 108-1 to 108-3 and the equipment 208-1 to 208-2.

  The local demand control device 100 includes a control unit 102, a memory 104, and a communication unit 105.

  The control unit 102 is configured by, for example, a CPU (Central Processing Unit). The control unit 102 executes software processing according to a program stored in the memory 104 (for example, a program for controlling the power consumption of the equipment devices 108-1 to 108-3 by the local demand control device 100). Various functions provided in the local demand control apparatus 100 are realized. In the present embodiment, the control unit 102 realizes the functions of the local upper limit value setting unit 122, the power comparison unit 124, and the load control unit 126. The control unit 102 is connected to a watt hour meter 106 for measuring the power consumption (local power amount) of the facility devices 108-1 to 108-3.

  The memory 104 is, for example, a RAM (Random Access Memory) or a ROM (Read Only Memory). The memory 104 stores various information (program, local power amount described above, tenant A local upper limit value by time zone described later, and the like) used for control and the like in the local demand control apparatus 100. The communication unit 105 transmits and receives various data to and from the overall demand control device 300 via the communication line 400.

  The local demand control device 200 has the same configuration as the local demand control device 100. That is, the local demand control device 200 includes a control unit 202, a memory 204, and a communication unit 205.

  Similar to the control unit 102, the control unit 202 is configured by a CPU, for example. The control unit 202 executes software processing according to a program stored in the memory 204 (for example, a program for controlling the power consumption of the facility devices 208-1 to 208-3 by the local demand control device 200), Various functions of the local demand control device 200 are realized. In the present embodiment, the control unit 202 realizes the functions of the local upper limit value setting unit 222, the power comparison unit 224, and the load control unit 226. The control unit 202 is connected with a watt hour meter 206 that measures the power consumption (local power amount) of the facility devices 208-1 to 208-3. The memory 204 is, for example, a RAM or a ROM. The memory 204 stores various information (program, local power amount, tenant B local upper limit value by time zone described later, etc.) used for control and the like in the local demand control device 200. The communication unit 205 transmits and receives various data to and from the overall demand control device 300 via the communication line 400.

  The overall demand control apparatus 300 includes a control unit 302, a memory 304, and a communication unit 305.

  The control unit 302 is configured by a CPU, for example. The control unit 302 includes the overall demand control device 300 by executing software processing according to a program stored in the memory 304 (for example, a program for controlling the power consumption of the entire building by the overall demand control device 300). Implement various functions. In the present embodiment, the control unit 302 realizes the functions of the overall upper limit setting unit 322 and the upper limit changing unit 324. The control unit 302 is connected to a power meter 306 that measures the sum of the power consumption of the facility devices 108-1 to 108-3 and the power consumption of the facility devices 208-1 to 208-3.

  The memory 304 is, for example, a RAM or a ROM. The memory 304 stores various types of information (program, total power amount described above, total upper limit value described later, etc.) used for control and the like in the total demand control apparatus 300. The communication unit 305 transmits / receives various data to / from the local demand control device 100 and the local demand device 200 via the communication line 400.

  Next, the operation of the power control system 1 will be described. FIG. 2 is a sequence diagram showing the operation of the power control system 1.

  The local demand control apparatus 100 sets the upper limit value (tenant A local upper limit value for each time zone) of the power consumption of the facility devices 108-1 to 108-3 in the tenant A for each time zone (for example, every 30 minutes). (Step S101). Specifically, the local upper limit value setting unit 122 in the control unit 102 generates a tenant A local upper limit value for each time period and stores it in the memory 104 in accordance with an operation of an operation unit (not shown) by an operator. The memory 104 stores a local power amount that is an actual value of the power consumption amount of the facility devices 108-1 to 108-3. For this reason, the worker can determine an appropriate tenant A local upper limit for each time zone based on the actual value.

  Similarly, the local demand control apparatus 200 sets the upper limit value (tenant B local upper limit value for each time zone) of the power consumption of the facility devices 208-1 to 208-3 in the tenant B for each time zone (step S102). ). Specifically, the local upper limit value setting unit 222 in the control unit 202 generates a tenant B local upper limit value for each time period in accordance with an operation of an operation unit (not shown) by the operator and stores the tenant B local upper limit value in the memory 204. The memory 204 stores a local power amount that is an actual value of the power consumption amount of the facility devices 208-1 to 208-3. For this reason, the worker can determine an appropriate tenant B local upper limit for each time zone based on the actual value. Hereinafter, the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone are collectively referred to as “local upper limit value by time zone” as appropriate.

  The overall demand control apparatus 300 is the upper limit value of the power consumption of the entire building, that is, the power consumption of the equipment devices 108-1 to 108-3 in the tenant A and the equipment devices 208-1 to 208-3 in the tenant B. An upper limit value (overall upper limit value) of the total power consumption amount is set (step S103). Specifically, the overall upper limit setting unit 322 in the control unit 302 generates an overall upper limit value according to the operation of an operation unit (not shown) by the operator and stores the generated upper limit value in the memory 304. The memory 304 stores the total power amount that is the actual value of the power consumption amount of the facility devices 108-1 to 108-3 and the facility devices 208-1 to 208-3. For this reason, the worker can determine an appropriate overall upper limit value based on the actual value. Similar to the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone, the overall upper limit value may be an upper limit value for each time zone, or may be a constant upper limit value regardless of the time zone.

  The local demand control device 100 transmits the tenant A local upper limit value by time zone at a predetermined timing (for example, a predetermined timing in one day). The overall demand control apparatus 300 receives the tenant A local upper limit value by time zone (step S104).

  Specifically, the control unit 102 in the local demand control apparatus 100 reads out the tenant A local upper limit value by time zone from the memory 104 and outputs it to the communication unit 105. The communication unit 105 adds the IP address or MAC address assigned to the communication unit 305 in the overall demand control device 300 to the tenant A local upper limit value by time zone as a destination, and is assigned to the communication unit 105. An IP address or MAC address is added as a transmission source. Further, the communication unit 105 outputs the tenant A local upper limit value by time zone to which the destination and the transmission source are added to the communication line 400. On the other hand, the communication unit 305 in the overall demand control apparatus 300 acquires the tenant A local upper limit value by time zone in which the destination is itself. The communication unit 305 outputs the acquired tenant A local upper limit value by time zone to the control unit 302.

  The local demand control device 200 transmits the tenant B local upper limit value by time zone at a predetermined timing. The overall demand control device 300 receives the tenant B local upper limit value by time zone (step S105). Specific processing is the same as that in step S104. That is, the control unit 202 in the local demand control device 200 reads the tenant B local upper limit value by time zone from the memory 204 and outputs it to the communication unit 205. The communication unit 205 adds the IP address or MAC address assigned to the communication unit 305 in the overall demand control device 300 to the tenant B local upper limit value by time zone as a destination, and is assigned to the communication unit 205. An IP address or MAC address is added as a transmission source. Further, the communication unit 205 outputs the tenant B local upper limit value by time zone to which the destination and the transmission source are added to the communication line 400. On the other hand, the communication unit 305 in the overall demand control apparatus 300 acquires the tenant B local upper limit value by time zone in which the destination is itself. The communication unit 305 outputs the acquired tenant B local upper limit value by time zone to the control unit 302.

  The overall demand control device 300 determines, for each time zone, whether the total value of the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone exceeds the overall upper limit value (excess judgment). Is performed (step S106).

  Specifically, the upper limit value changing unit 324 in the control unit 302 calculates the total value of the tenant A local upper limit value by time zone received in step S104 and the tenant B local upper limit value by time zone received in step S105. To do. Next, the upper limit changing unit 324 reads the entire upper limit from the memory 304. Furthermore, the upper limit changing unit 324 compares the total value corresponding to the time zone with the overall upper limit value for each time zone, and determines whether the total value exceeds the overall upper limit value.

  FIG. 3 is a diagram illustrating time transition of the local upper limit value and the overall upper limit value for each time zone. As shown in FIG. 3A, in each of the time zones T1 to T6, the tenant A local upper limit value (LA) for each time zone is set, and as shown in FIG. Consider a case where a tenant B local upper limit (LB) for each time period is set in each of T6.

  As shown in FIG. 3C, when a constant overall upper limit (LT) is set regardless of the time zone, the tenant A local upper limit value (LA) by time zone and the tenant B local upper limit value by time zone The total value (LA + LB) with (LB) exceeds the overall upper limit (LT) in the time zone T4. In addition, as shown in FIG. 3D, when an overall upper limit value (LT) is set for each time zone, the tenant A local upper limit value (LA) by time zone and the tenant B local upper limit value by time zone ( LB) and the total value (LA + LB) exceed the overall upper limit (LT) in the time period T4.

  When there is a time zone (excess time zone) in which the total value of the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone exceeds the overall upper limit value, the overall demand control device 300 In at least one of the demand control device 100 and the local demand control device 200, a reduction value indicating a reduction amount of the local upper limit value for each time zone in the excess time zone is set (step S107).

  Specifically, the upper limit value changing unit 324 in the control unit 302 is a value obtained by subtracting the overall upper limit value from the total value of the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone in the excess time zone. (Reduction value) is calculated. Next, the upper limit value changing unit 324 distributes the reduction value to the local demand control device 100 and the local demand control device 200. Here, the upper limit value changing unit 324 identifies the larger one of the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone in the excess time zone, and the identified local upper limit value by time zone All reduction values may be distributed only to the local demand control device corresponding to the above. Alternatively, the upper limit value changing unit 324 sends the reduction value to the local demand control device 100 and the local demand control device 200 according to the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone in the excess time zone. Proportional proportional distribution may be used.

  For example, consider a case where the tenant A local upper limit value by time zone in the excess time zone is 40 kWh, the tenant B local upper limit value by time zone is 80 kWh, and the reduction value is 10 kWh. In this case, the upper limit value changing unit 324 determines the tenant B local upper limit value by time zone, which is the larger of the tenant A local upper limit value 40 kWh by time zone and the tenant B local upper limit value 80 kWh by time zone in the excess time zone. 80 kWh is specified, and all reduction values of 10 kWh are allocated only to the corresponding total demand control device 200. Alternatively, the upper limit value changing unit 324 proportionally apportions the reduction value 10 kWh according to the tenant A local upper limit value 40 kWh by time zone and the tenant B local upper limit value 80 kWh by time zone in the excess time zone, and the local demand control device 100 3.3 kWh is allocated to the local demand control apparatus 200 and 6.7 kWh is allocated to the local demand control apparatus 200.

  When the reduction value is allocated to the local demand control device 100 as a result of the setting of the reduction value, the overall demand control device 300 gives the local demand control device 100 the tenant A local upper limit value by time zone in the excess time zone. Change request (local upper limit change request information) is transmitted. The local demand control device 100 receives the local upper limit value change request (step S108).

  Specifically, the upper limit value changing unit 324 in the control unit 302 of the overall demand control device 300 changes the local upper limit value including the information on the excess time period and the reduction value allocated to the local demand control device 100. Request information is generated and output to the communication unit 305. The communication unit 305 adds the IP address or MAC address assigned to the communication unit 105 in the local demand control device 100 to the local upper limit value change request information as a destination, and the IP address assigned to the communication unit 305. Or a MAC address as a transmission source. Further, the communication unit 305 outputs the local upper limit value change request information to which the destination and the transmission source are added to the communication line 400. On the other hand, the communication unit 105 in the local demand control apparatus 100 acquires the local upper limit value change request information whose destination is itself and outputs it to the control unit 102.

  When the reduction value is allocated to the local demand control device 200 as a result of the setting of the reduction value, the overall demand control device 300 provides the local demand control device 200 with the tenant B local by time zone in the excess time zone. An upper limit change request (local upper limit change request information) is transmitted. The local demand control device 200 receives the local upper limit value change request (step S109).

  Specific processing is the same as that in step S108. That is, the upper limit value changing unit 324 in the control unit 302 of the overall demand control device 300 receives the local upper limit value change request information including the information on the excess time period and the reduction value allocated to the local demand control device 200. Generate and output to the communication unit 305. The communication unit 305 adds the IP address or MAC address assigned to the communication unit 205 in the local demand control device 200 to the local upper limit value change request information as a destination and the IP address assigned to the communication unit 305. Or a MAC address as a transmission source. Further, the communication unit 305 outputs the local upper limit value change request information to which the destination and the transmission source are added to the communication line 400. On the other hand, the communication unit 205 in the local demand control device 200 acquires the local upper limit value change request information whose destination is itself and outputs it to the control unit 202.

  Based on the received local upper limit value change request information, the local demand control device 100 changes the tenant A local upper limit value for each time zone in the excess time zone (step S110). Specifically, the local upper limit value setting unit 122 in the control unit 102 recognizes the excess time zone and the reduction value based on the local upper limit value change request information. Next, the local upper limit value setting unit 122 updates the tenant A local upper limit value for each time zone in the excess time zone stored in the memory 104 to a value obtained by reducing the reduction value.

  Based on the received local upper limit value change request information, the local demand control device 200 changes the tenant B local upper limit value for each time zone in the excess time zone (step S111). The specific process is the same as that in step S110. That is, the local upper limit value setting unit 222 in the control unit 202 recognizes the excess time zone and the reduction value based on the local upper limit value change request information. Next, the local upper limit value setting unit 222 updates the tenant B local upper limit value for each time period in the excess time period stored in the memory 204 to a value that is reduced by the reduction value.

  FIG. 4 is a diagram illustrating an example of the power consumption change. 4A and 4B show a case where the time zone T4 is an excess time zone and the excess amount is 10 kWh. FIG. 4 (A) shows that the overall demand control device 300 is the tenant by time zone, which is the larger one of the tenant A local upper limit value 40 kWh by time zone and the tenant B local upper limit value 80 kWh by time zone in the excess time zone. In this example, local upper limit change request information including a reduction value of 10 kWh is transmitted only to the local demand control device 200 corresponding to the B local upper limit. In this case, the local upper limit value setting unit 222 in the control unit 202 of the local demand control device 200 changes the tenant B local upper limit value by time zone from 80 kWh to 70 kWh.

  On the other hand, FIG. 4B shows that the overall demand control device 300 proportionally apportions the reduction value according to the tenant A local upper limit value 40 kWh by time zone and the tenant B local upper limit value 80 kWh by time zone in the excess time zone. The local upper limit value change request information including the reduction value 3.3 kWh is transmitted to the demand control apparatus 100, and the local upper limit value change request information including the reduction value 6.7 kWh is transmitted to the local demand control apparatus 200. This is an example of transmission. In this case, the local upper limit value setting unit 122 in the control unit 102 of the local demand control device 100 changes the tenant A local upper limit value by time zone from 40 kWh to 36.7 kWh. Further, the local upper limit value setting unit 222 in the control unit 202 of the local demand control device 200 changes the tenant B local upper limit value by time zone from 80 kWh to 73.3 kWh.

  Thereafter, the local demand control device 100 controls the power consumption of the equipment devices 108-1 to 108-3 (step S112). Specifically, the power comparison unit 124 in the control unit 102 consumes the facility devices 108-1 to 108-3 in a predetermined future time zone based on the time transition of the local power amount stored in the memory 104. Predict the amount of power. Next, the power comparison unit 124 compares the predicted value in the future predetermined time zone with the tenant A local upper limit value for each time zone stored in the memory 104 in the future predetermined time zone. When the predicted value in the future predetermined time zone exceeds the tenant A local upper limit value by time zone, the load control unit 126 consumes the facility devices 108-1 to 108-3 when the future predetermined time zone arrives. The power supplied to the equipment devices 108-1 to 108-3 is reduced or cut off so that the amount of power falls below the tenant A local upper limit for each time zone in a predetermined time zone in the future. At this time, the load control unit 126 may control supply power only to the equipment determined according to a predetermined priority.

  In addition, the local demand control device 200 controls the power consumption of the equipment devices 208-1 to 208-3 (step S113). Specific processing is the same as that in step S113. That is, the power comparison unit 224 in the control unit 202 calculates the power consumption of the facility devices 208-1 to 208-3 in a predetermined future time zone based on the time transition of the local power amount stored in the memory 204. Predict. Next, the power comparison unit 224 compares the predicted value in the future predetermined time zone with the tenant B local upper limit value for each time zone stored in the memory 204 in the future predetermined time zone. When the predicted value in the future predetermined time zone exceeds the tenant B local upper limit value by time zone, the load control unit 226 consumes the facility devices 208-1 to 208-3 when the future predetermined time zone arrives. The power supplied to the facility devices 208-1 to 208-3 is reduced or cut off so that the amount of power falls below the tenant B local upper limit value by time zone in a predetermined time zone in the future. At this time, the load control unit 226 may control the supply power only for the equipment that is determined according to a predetermined priority.

  As described above, in the power control system 1 according to the present embodiment, the local demand control device 100 includes the tenant A local by time zone that is the upper limit value of the power consumption for each time zone of the subordinate equipment 108-1 to 108-3. The upper limit value is set and notified to the overall demand control device 300, and the local demand control device 200 is the tenant B by time zone, which is the upper limit value of power consumption for each time zone of the subordinate equipment 208-1 to 208-3. The local upper limit value is set and notified to the overall demand control device 300. On the other hand, the overall demand control device 300 sets an overall upper limit value indicating the upper limit of the power consumption of the entire group consisting of the equipment devices 108-1 to 108-3 and the equipment devices 208-1 to 208-3, and the time zone Acquires another tenant A local upper limit value and tenant B local upper limit value by time zone, and the total value of tenant A local upper limit value by time zone and tenant B local upper limit value by time zone in the specified time zone exceeds the overall upper limit value When doing so, the local demand control device 100 and the local demand control device 200 are requested to change the local upper limit value in a predetermined time zone. In response to this request, at least one of the local demand control device 100 and the local demand control device 200 decreases the local upper limit value for each time zone in a predetermined time zone.

  Therefore, by changing the upper limit value of power consumption of each tenant to an appropriate value in advance according to the upper limit value of power consumption of the entire building, the local upper limit value by time zone varies with time, Furthermore, control is performed so that the total value of the local upper limit values for each time zone does not exceed the overall upper limit value. This eliminates the need to control the power consumption of the entire building, so that the tenant power consumption control and the power consumption control of the entire building do not collide with each other as in the past. Therefore, it is possible to appropriately control power consumption that fluctuates.

  In addition, the overall demand control device 300 sets all the reduction values only to the local demand control device corresponding to the larger one of the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone in the excess time zone. By allocating, the prominent local upper limit for each time zone can be lowered. Further, the overall demand control device 300 sends a reduction value to the local demand control device 100 and the local demand control device 200 according to the tenant A local upper limit value by time zone and the tenant B local upper limit value by time zone in the excess time zone. Proportionally prorated to distribute the reduction value fairly to each tenant.

  Further, the local demand control devices 100 and 200 predict the power consumption for each time zone of the subordinate equipment, and the predicted value in the predetermined time zone exceeds the local upper limit for each time zone in the predetermined time zone. The power consumption is controlled by reducing or shutting off the power supply to the subordinate equipment and preventing the power consumption of the equipment from exceeding the local upper limit for each time zone in advance. Can do.

  As mentioned above, although embodiment of this invention was described, this invention is not limited by embodiment. The present invention includes a combination of the embodiments and the following modifications as appropriate, and includes equivalents thereof.

  For example, in the above-described embodiment, the case where there are two tenants has been described. However, there are three or more tenants, and each tenant is provided with a local demand control device and equipment equipment under the local demand control device. Even in such a case, the present invention can be similarly applied.

  In the above-described embodiment, power consumption control for the entire building and power consumption control for each tenant in the building have been described. However, power consumption control for the entire factory and power consumption control for each small factory in the factory are performed. In this case, the present invention can be similarly applied.

100, 200 Local demand control device 102, 202, 302 Control unit 104, 204, 304 Memory 105, 205, 305 Communication unit 106, 206, 306 Electricity meter 108-1 to 108-3, 208-1 to 208-3 Equipment 122, 222 Local upper limit setting unit 124, 224 Power comparison unit 126, 226 Load control unit 200 Local demand control device 300 Overall demand control device 322 Overall upper limit value setting unit 324 Upper limit value changing unit 400 Communication line

Claims (9)

A power control system comprising: a plurality of individual power control devices that control power consumption of subordinate loads; and an overall power control device that controls power consumption of an entire group consisting of subordinate loads of the individual power control devices. There,
The individual power control device includes:
An individual upper limit setting means for setting an individual upper limit value indicating an upper limit of power consumption for each time period in the subordinate load;
Individual upper limit notification means for notifying the overall power control device of the individual upper limit for each set time period;
With
The overall power control device is:
An overall upper limit setting means for setting an overall upper limit value indicating an upper limit of the power consumption of the entire group;
Individual upper limit value acquisition means for acquiring an individual upper limit value for each time period from each individual power control device;
A change request for notifying the individual power control device of a request for changing the individual upper limit value in the predetermined time period when the total value of the individual upper limit values in the acquired predetermined time period exceeds the overall upper limit value Notification means;
With
The individual power control device includes:
Change request acquisition means for acquiring a request for changing the individual upper limit value in the predetermined time period from the overall power control device;
In response to a request for changing the individual upper limit value in the predetermined time zone, individual upper limit value changing means for changing the individual upper limit value in the predetermined time zone;
A power control system comprising: The change request notification means notifies a change request for an individual upper limit value in the predetermined time period including a reduction value of power consumption in the predetermined time period,
The individual upper limit value changing means sets the value obtained by subtracting the power consumption reduction value in the predetermined time period from the individual upper limit value in the set predetermined time period as the individual upper limit value in the changed predetermined time period. The power control system according to claim 1.   The change request notifying unit includes a power consumption reduction value in the predetermined time period for the individual power control apparatus having the maximum individual upper limit value in the predetermined time period among the plurality of individual power control apparatuses. The power control system according to claim 2, wherein a request for changing the individual upper limit value in the predetermined time period is notified.   The change request notifying unit includes the predetermined power including a value obtained by proportionally apportioning a reduction value of power consumption in the predetermined time period according to an individual upper limit value in the predetermined time period for the plurality of individual power control devices. The power control system according to claim 2, wherein a request for changing the individual upper limit value in a time zone is notified. The individual power control device includes:
A predicting means for obtaining a predicted value of power consumption for each time zone of the subordinate load;
Controls the power consumption of the subordinate load when the predicted value in the predetermined time zone acquired by the prediction means exceeds the individual upper limit value in the predetermined time zone changed by the individual upper limit value changing means. Load control means;
The power control system according to any one of claims 1 to 4, further comprising: An overall power control device that controls power consumption of the entire group consisting of loads under each of a plurality of individual power control devices,
An overall upper limit setting means for setting an overall upper limit value indicating an upper limit of the power consumption of the entire group;
Individual upper limit value acquisition means for acquiring an individual upper limit value indicating an upper limit of power consumption for each time period in a load under control of the individual power control device from each individual power control device;
A change request for notifying the individual power control device of a request for changing the individual upper limit value in the predetermined time period when the total value of the individual upper limit values in the acquired predetermined time period exceeds the overall upper limit value Notification means;
An overall power control device comprising: An individual power control device that controls the power consumption of a subordinate load,
Individual upper limit setting means for setting an individual upper limit value indicating the upper limit of the power consumption for each time zone of the subordinate load;
Individual upper limit value notifying means for notifying the individual upper limit value for each set time zone to the overall power control device that controls the power consumption of the entire group consisting of the loads under each of the plurality of individual power control devices;
An individual power control device comprising: An individual power control device that controls the power consumption of a subordinate load,
Individual upper limit setting means for setting an individual upper limit value indicating the upper limit of the power consumption for each time zone of the subordinate load;
Change request acquisition means for acquiring an individual upper limit value change request in a predetermined time period from the overall power control device that controls the power consumption of the entire group consisting of the loads under each of the plurality of individual power control devices;
In response to a request for changing the individual upper limit value in the predetermined time zone, individual upper limit value changing means for changing the individual upper limit value in the predetermined time zone;
An individual power control device comprising: A power control method for controlling power consumption of an entire group consisting of loads under each of a plurality of individual power control devices,
Set an overall upper limit value indicating an upper limit of power consumption for each time zone of the entire group,
Obtaining an individual upper limit value indicating an upper limit of power consumption for each time zone in a load under control of the individual power control device from each individual power control device;
When the total value of the individual upper limit values in the acquired predetermined time period exceeds the overall upper limit value, a request for changing the individual upper limit value in the predetermined time period is notified to the individual power control device. A power control method.

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