JP2019046359A - Control system - Google Patents

Abstract

To appropriately manage a whole used electric energy of the dedicated part of a condominium and a whole condominium.SOLUTION: In a control system 1, when a used power amount per unit time in a dedicated part 310_1 is smaller than a first threshold value, a first electricity unit rate is applied, and a second electricity unit rate is applied to the used power amount exceeding the first threshold value among the used electric power amounts per unit time. A server 100 notifies a terminal device 200_1 when the used power amount of the dedicated part 310_1 exceeds a second threshold value lower than the first threshold value in per unit time. A server 100 controls a control object device 320_1 when a control command is received from the terminal device 200_1 based on the notification. The server 100 executes a control to reduce power consumption of the control object device 320_1 when determined that there is a possibility that an average used power amount for a demand time period of a condominium 300 exceeds the predetermined value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control system and a control method.

  Businesses that supply power need to reduce power consumption by power consumers (users) in order not to concentrate power demand at one time.

  From this point of view, for example, Patent Document 1 discloses an electricity bill calculation that contributes to the suppression of power consumption by the user at the peak of power demand and further contributes to the reduction of the user's electricity bill. An apparatus is disclosed.

  In this electricity rate calculation device, each dedicated unit power meter is a dedicated unit that receives the power supplied from the power supplier for each individual user, and gives time information to the amount of power used by the user. Measure the amount of power used by the private part for each time period. Each common section power meter is a shared section that is shared by multiple users to receive power, and adds user information and time information to the amount of power used by the user, and determines the amount of power used by the shared section for each time period. measure. The computing unit was used by individual users in the dedicated and shared units based on the dedicated unit power consumption measured by each dedicated unit power meter and the shared unit power consumption measured by each shared unit power meter. Aggregate the total power consumption by time zone.

  Also, in recent years, energy management services have been effectively provided by bundling consumers' power demand. A company that provides such a service is also referred to as an “aggregator”.

JP 2013-58046 A

  In the electricity price calculation apparatus of Patent Literature 1, even if the power consumption by the user can be suppressed at the peak of power demand, the demand value of the entire apartment exceeds the contract power determined by the “demand fee system”. There is a possibility. The demand value is the average power used in the demand time period (30 minutes).

  In addition, when an aggregator is interposed between an electric power company and a customer, if the demand value of the entire apartment exceeds the demand predicted value of the aggregator, the balance of the aggregator may deteriorate.

  The present invention has been made in view of the above-described problems, and an object thereof is to provide a control system and a control method capable of appropriately managing the amount of electric power used by the exclusive part of the apartment and the entire apartment. It is in.

  According to one aspect of the present invention, the control system manages the amount of power used in a condominium having a plurality of exclusive units. The control system includes a server device, a first control target device installed in a first dedicated unit among a plurality of dedicated units, and a terminal device for remotely controlling the first control target device. In the control system, the first unit price is applied when the power consumption per unit time in the first dedicated unit is less than the first threshold, and the first power consumption per unit time is the first. The electricity rate per unit time in the first exclusive unit is calculated by applying the second unit price higher than the first unit price for the power consumption exceeding the threshold of . The server device makes a first notification to the terminal device when the power consumption of the first dedicated unit exceeds a second threshold value equal to or less than the first threshold value within a unit time. When receiving a control command from the terminal device based on the first notification, the server device controls the first control target device based on the control command. The server device executes control for reducing the power consumption of the first control target device based on the determination that the average power consumption in the demand time limit of the apartment may exceed a predetermined value.

  According to said invention, it becomes possible to manage appropriately the electric power consumption of the exclusive part of an apartment and the whole apartment.

It is a figure for demonstrating schematic structure of a control system. It is a figure for demonstrating the relationship between an electric power company, an aggregator, and a consumer. It is a figure showing the typical system configuration example of the control system. It is a figure for demonstrating a two-stage charge plan. It is a figure for demonstrating the trigger from which a server notifies an electronic mail to a terminal device. It is a figure showing the state which displayed the electronic mail in the terminal device. It is the figure showing the example of a screen displayed in a terminal device, after logging in to a server. It is a figure showing the example of a screen displayed in a terminal device, after an object is selected. It is a figure showing an example of the change of the average electric power used in the whole apartment. It is a block diagram showing the functional structure of the server. It is a figure showing the typical example of the hardware constitutions of the server. It is a figure showing the typical example of the hardware constitutions of a terminal device. It is a sequence diagram for demonstrating the flow of a process in a control system. It is a flowchart for demonstrating the flow of a process of a server.

Hereinafter, a control system according to each embodiment of the present invention will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.
[Embodiment 1]
<A. Overview>
FIG. 1 is a diagram for explaining a schematic configuration of the control system 1.

  Referring to FIG. 1, the control system 1 includes a server 100, a plurality of terminal devices 200_1, 200_2,..., 200_n, and a plurality of control target devices 320_1, 320_2,. In this example, n is a natural number of 3 or more.

  The apartment 300 includes a plurality of exclusive portions 310_1, 310_2,. In FIG. 1, for convenience of explanation, only one exclusive section is shown on each floor, but the present invention is not limited to this.

  In the following, for convenience of explanation, when each of the plurality of terminal devices 200_1, 200_2,..., 200_n is not distinguished, they are represented as “terminal device 200”. Moreover, when not distinguishing each of several control object apparatus 320_1, 320_2, ..., 320_n, it describes with "control object apparatus 320." Furthermore, when each of the plurality of exclusive parts 310_1, 310_2,..., 310_n is not distinguished, it is expressed as “exclusive part 310”. In the following, i is described as an arbitrary natural number of 1 or more and n or less.

  In the present example, the control target device 320_i is an air conditioner. The control target device 320_i is installed in the exclusive part 310_i of the apartment 300. For example, the control target device 320_1 is installed in the exclusive part 310_1 of the apartment 300. Note that the control target device 320_i may be an electric water heater that uses a heat pump technique to boil hot water with the heat of air.

  The server 100 is managed and operated by an aggregator that provides an energy management service in the apartment 300. The server 100 is configured to be able to communicate with each of the plurality of terminal devices 200 and each of the plurality of control target devices 320. The server 100 has a function as a demand monitoring device.

  The terminal device 200_i is a communication device used by a resident of the exclusive unit 310_i. For example, the terminal device 200_1 is used by a resident of the exclusive unit 310_1. The terminal device 200_i functions as a controller that remotely controls the control target device 320_i. The terminal device 200_i is, for example, a smartphone or a tablet terminal.

  1 illustrates one server 100, the control system 1 may be configured so that the functions of the server 100 are distributed and executed by a plurality of servers. Further, in FIG. 1, as an example, a state in which the terminal device 200_i is indoors is shown, but it may be outdoors.

FIG. 2 is a diagram for explaining a relationship among an electric power company, an aggregator, and a customer.
Referring to FIG. 2, aggregator 900 purchases high-voltage power from electric power company 800. The aggregator pays the power company 800 the total amount of the basic charge and the electricity charge for the metered portion of the apartment 300.

  The basic charge is a charge based on the contract power determined by the “demand charge system”. Contract power is determined by the maximum demand power (monthly) in the past year. Therefore, when the demand value exceeds the contract power, the aggregator 900 updates the contract power with the surplus demand value. Therefore, the basic fee paid by the aggregator 900 to the power company 800 is increased.

  Aggregator 900 predicts the demand value in condominium 300 and determines the value of contract power. For the aggregator 900, it is necessary to manage the power consumption of the apartment 300 so that the demand value does not exceed the contract power from the viewpoint of the balance of payments.

  The “demand value” is the average power used in the demand time period (total average power used for the operating load). The demand time period is 30 minutes from 0 to 30 minutes per hour and 30 minutes from 30 to 0 minutes (60 minutes) per hour. That is, in this embodiment, “demand value” means a 30-minute demand value.

  For example, when a 500 kW load is used for 30 minutes without change, the power consumption for 30 minutes is 250 kWh (= 500 kW × 0.5 h). In this case, the demand value is 500 kW.

The maximum demand value for 30 minutes in a month is the maximum power demand for that month.
The aggregator 900 provides a two-stage rate plan for the residents of the apartment 300 (electric power consumers). The aggregator 900 applies an additional charge unit price for the power consumption exceeding the threshold Th1 to the exclusive unit 310 whose power consumption per unit time exceeds the predetermined threshold Th1.

  As the unit time, the same 30 minutes as the demand time period is used. The unit time is the same time zone as the demand time limit. That is, 30 minutes from 0 to 30 minutes per hour and 30 minutes from 30 to 0 minutes (60 minutes) per hour.

  A resident of the exclusive section 310 of the apartment 300 pays a charge corresponding to the amount of power used to the aggregator 900 according to a two-stage charge plan. If the amount of electricity used every 30 minutes exceeds the threshold Th1, a surcharge will be charged. Therefore, it is preferable for residents to keep the amount of power used every 30 minutes below the threshold Th1 from the viewpoint of suppressing electricity charges.

  In addition, this threshold Th1 is preferably set in a range in which the demand value of the apartment 300 does not exceed the contracted power as long as the amount of power used every 30 minutes of each dedicated unit 310 is equal to or less than the threshold Th1. .

  For the aggregator 900, the difference between the revenue based on the two-stage rate plan and the total amount of the basic fee paid to the electric power company and the fee for the pay-as-you-go system is profitable. From this point of view, the aggregator 900 determines contract power, the unit price of the two-stage rate plan, the threshold value Th1, and the like.

  Referring to FIG. 1 again, as an example, when the amount of power used in the unit time (30 minutes) of the exclusive unit 310_1 exceeds a threshold value Th2 that is equal to or less than the threshold value Th1, a predetermined amount is given to the terminal device 200_1. An e-mail is transmitted (process (i) in FIG. 1).

  When the user of the terminal device 200_1 (the resident of the exclusive unit 310_1) receives the e-mail, the user can know that the amount of power used in the unit time is approaching the threshold value Th1. That is, in this state, the resident can know that the premium unit price in the two-stage rate plan is applied to the exclusive part 310_1.

  The resident operates the terminal device 200_1 (process (ii) in FIG. 1), and sends a control command for reducing power consumption to the control target device 320_1 from the terminal device 200_1 via the server 100. The data is transmitted to the device 320_1 (process (iii) in FIG. 1). The control command may be directly transmitted from the terminal device 200_1 to the control target device 320_1 without using the server 100.

  Thereby, the resident of the exclusive part 310_1 can prevent the premium unit price from being applied.

  In addition, when the server 100 determines that the demand value of the entire apartment may exceed the contract power, the server 100 automatically transmits a control command to each control target device 320 (process (iv) in FIG. 1). That is, the server 100 executes the forced control without operating the terminal device 200 by a resident of the apartment 300. Specifically, the server 100 transmits a control command for reducing the power consumption of each control target device 320.

  Therefore, it is possible to prevent the demand value of the apartment 300 from exceeding the contract power. As a result, it is possible to prevent the basic fee from increasing due to contract renewal.

  As described above, according to the control system 1, it is possible to appropriately manage the amount of power used in the exclusive part 310 of the apartment 300 and the entire apartment.

  Furthermore, since the aggregator 900 protects the contract power, the power company 800 can reduce power consumed in a time zone where the power demand is at a peak. Therefore, the power company 800 does not have to make extra capital investment.

  In the above description, the configuration in which a control command is automatically transmitted to each control target device 320 when it is determined that the demand value of the entire apartment may exceed the contract power has been described as an example. Is not to be done. The server 100 is configured to automatically transmit a control command to each control target device 320 when it is determined that the demand value of the entire apartment may exceed a value (target value) set lower than the contract power. May be configured.

Hereinafter, a detailed configuration of the control system 1 will be described.
<B. System configuration>
FIG. 3 is a diagram illustrating a typical system configuration example of the control system 1.

  Referring to FIG. 3, apartment 300 has a shared unit 350 and n dedicated units 310. In FIG. 3, the terminal device 200 is not described for convenience.

(B1. Common use part 350)
The shared unit 350 includes a power receiving / transforming facility 390, a WHM (watt-hour meter) 383, a router 351, a MEMS (apartment energy management system) 352, a distribution board 381, and a plurality of wireless adapters 363_1, 363_2, 363_3. A plurality of control target devices 360_1, 360_2, and 360_3, and a non-control target device group 365 are installed.

  In the present example, the control target devices 360_1, 360_2, and 360_3 are air conditioners. The non-control target device group 365 includes devices such as an elevator, lighting, an emergency generator, and a storage battery, for example.

  The power receiving / transforming equipment 390 is connected to the power system of the power company 800. The power receiving / transforming equipment 390 converts the power received from the power company into a voltage suitable for the load equipment.

  The WHM 383 is connected to the power receiving / transforming equipment 390. Low-voltage power is supplied to the WHM 383 from the power receiving / transforming equipment 390. The WHM 383 measures the amount of power used by a device installed in the shared unit 350.

  The WHM 383 can hold data on the amount of power used every 30 minutes for one month or more in order to calculate an electricity bill. These data are transmitted to the server 100 by the MEMS 352 via the network line (RS485 line) of the shared unit. Further, the MEMS 352 transmits the power consumption used every 15 minutes measured by the WHM 383 to the server 100 via the network line of the shared unit for demand monitoring. In addition, 15 minutes is an illustration, Comprising: It is not limited to this.

  In this way, the WHM 383 is used not only for measuring the electricity bill for the metered portion but also for demand monitoring.

  The distribution board 381 is connected to the WHM 383. The distribution board 381 is supplied with power from the power receiving / transforming equipment 390 via the WHM 383. The distribution board 381 includes a MEMS 352, a router 351, a plurality of wireless adapters 363_1, 363_2, and 363_3, a plurality of control target devices 360_1, 360_2, and 360_3, and a non-control target device via an unillustrated outlet and wiring. The group 365 is electrically connected.

  The wireless adapters 363_1, 363_2, and 363_3 are connected to the control target devices 360_1, 360_2, and 360_3, respectively. Note that when the control target devices 360_1, 360_2, and 360_3 have a wireless adapter function, the wireless adapters 363_1, 363_2, and 363_3 are not necessary.

  The MEMS 352 receives a control command from the server 100 via the router 351. The MEMS 352 can transmit a control command to the control target device 360_1 via the wireless adapter 363_1. Similarly, the MEMS 352 can transmit a control command to the control target devices 360_2 and 360_3 via the wireless adapters 363_2 and 363_3, respectively.

(B2. Exclusive section 310)
In the exclusive part 310_i, a WHM 343_i, a HEMS (Home Energy Management System) 332_i, a distribution board 341_i, a wireless adapter 323_i, a control target device 320_i, and a non-control target device group 325_i are installed.

  The non-control target device group 325_i includes devices such as a lighting fixture, a television, and a dishwasher.

  The WHM 343 — i is connected to the power receiving / transforming equipment 390. WHM 343 — i is supplied with low-voltage power from the power receiving / transforming equipment 390. WHM343_i measures the electric power consumption of the apparatus installed in the exclusive part 310_i.

  The WHM 343_i can hold data on the amount of power used every 30 minutes for one month or more in order to calculate an electricity bill. These data are transmitted to the server 100 by the MEMS 352 via the network line of the shared unit. In addition, the MEMS 352 installed in the shared unit 350 transmits the power consumption used every 15 minutes measured by the WHM 343_i to the server 100 via the network line of the shared unit for demand monitoring. In addition, 15 minutes is an illustration, Comprising: It is not limited to this.

  In this way, the WHM 343_i is used not only for measuring the electricity rate of the metered portion but also for demand monitoring.

  Distribution board 341_i is connected to WHM343_i. Power is supplied to the distribution board 341_i from the power receiving / transforming equipment 390 via the WHM 343_i. The distribution board 341_i is electrically connected to the HEMS 332_i, the wireless adapter 323_i, the control target device 320_i, and the non-control target device group 325_i through an unillustrated outlet and wiring.

  The wireless adapter 323_i is connected to the control target device 320_i. Note that when the control target device 320_i has a function of a wireless adapter, the wireless adapter 323_i is not necessary.

  The HEMS 332 — i receives a control command from the server 100 via the router 351. The HEMS 332 — i can transmit a control command to the control target device 320 — i via the wireless adapter 323 — i. Note that the HEMS 332 — i may be configured to receive a control command from the server 100 via a router (not shown) provided in each.

  Hereinafter, when each of the plurality of watt-hour meters 343_1, 343_2,..., 343_n is not distinguished, it is expressed as “watt-hour meter 343”.

<C. Details of processing>
(C1. Proprietary fee system)
FIG. 4 is a diagram for explaining a two-stage rate plan.

  Referring to FIG. 4, when the amount of power used for 30 minutes exceeds 0.6 kWh, a surcharge unit price is applied to the amount of power used exceeding 0.6 kWh. In this example, 0.6 kWh corresponds to the threshold value Th1 described above.

  For example, assume that the amount of power used from 22:00 to 22:30 on April 30 was 0.75 kWh. Further, it is assumed that the standard unit price per kWh is C1, and the premium unit price per kWh is C2 (C2> C1). In this case, the electricity bill P for 30 minutes from 22:00 to 22:30 is as shown in the following formula (1).

P = C1 * 0.6 + C2 * (0.75-0.6) (1)
(C2. Notification service)
FIG. 5 is a diagram for explaining a trigger for the server 100 to notify the terminal device 200_i of an electronic mail.

  Referring to FIG. 5, when the power consumption in the unit time (30 minutes) of the dedicated unit 310 — i exceeds 0.5 kWh that is equal to or less than 0.6 kWh (threshold value Th1), the server 100 determines a predetermined value for the terminal device 200 — i. Send an email. Typically, based on the power consumption for every 15 minutes acquired from WHM343_i, the server 100 is set to 0. 0 when the power consumption for the unit time (30 minutes) of the dedicated unit 310_i has passed 15 minutes from the start of measurement. When it is determined that it exceeds 5 kWh, a predetermined electronic mail is transmitted to the terminal device 200_i.

  For example, in the case of the plot V1 in FIG. On the other hand, in the case of the plot V2, the server 100 transmits an e-mail. In the above example, 0.5 kWh corresponds to the threshold value Th2 described above.

  The value of the threshold Th2 is configured to be appropriately set by the resident of the exclusive part 310_i. The resident can change the value of the threshold Th2 by logging in to the server 100 using the terminal device 200_i.

  The server 100 notifies the terminal device 200_i of an e-mail every time the power consumption exceeds 0.5 kWh.

  FIG. 6 is a diagram illustrating a state in which an electronic mail is displayed on the terminal device 200_i. Referring to FIG. 6, a screen 290 that displays an e-mail describes that the amount of power used in 30 minutes has exceeded 0.5 kWh. Thereby, the resident of the exclusive part 310_i can know that there is a possibility that the premium charge unit price in the two-stage charge plan may be applied.

  The e-mail describes an address 291 for displaying an operation screen for controlling the control target device 320 as a link destination address. Specifically, a URL (Uniform Resource Locator) is described as the address.

  When the resident of the exclusive unit 310_i selects the URL displayed on the terminal device 200_i, the screen changes to a screen for logging in to the server 100.

(C3. Home Appliance Control Service)
FIG. 7 is a diagram illustrating a screen example displayed on the terminal device 200 — i after logging in to the server 100.

  With reference to FIG. 7, the terminal device 200 — i displays an operation screen for controlling the control target device. This operation screen is typically a Web page and includes a plurality of selectable objects 281 to 287. For example, the object 281 is associated with the living air conditioner of the exclusive part 310_i. When the object 286 is selected, the screen transitions to the next page, and objects associated with other devices to be controlled are displayed.

  FIG. 8 is a diagram illustrating a screen example displayed on the terminal device 200_i after the object 281 is selected.

  Referring to FIG. 8, terminal device 200_i displays an operation screen for controlling the air conditioner in the living room. This operation screen is typically a Web page and includes a plurality of selectable objects 271 to 276.

  The object 271 is for operating the air conditioner. The object 272 is for stopping the air conditioner.

  An object 273 is a pull-down menu for selecting an operation mode. The operation mode includes cooling operation, heating operation, air blowing operation, and dehumidifying operation.

  The object 274 displays the current set temperature. The object 274 includes an object that raises or lowers the set temperature. The resident can change the set temperature by selecting the object.

  The object 275 is for instructing the server 100 to execute control based on the content selected or input by the resident. The object 276 is for returning to the operation screen of FIG.

  In the example of FIG. 8, the resident who uses the terminal device 200_i can reduce the power consumption of the exclusive part 310_i by increasing the set temperature. Therefore, it is possible to prevent the premium unit price from being applied.

(C4. Automatic control system)
With the passage of time, the average power consumption of the entire apartment increases. Therefore, the server 100 determines whether there is a possibility that the demand value (the average power consumption of the apartment 300 in 30 minutes) exceeds the contract power (kW), for example, every 15 minutes. Specifically, when the server 100 determines that the amount of power used (kWh) in the demand time limit of the apartment 300 exceeds the amount of power calculated from the contract power (contract power (kW) × 0.5 h), It is determined that the value may exceed the contract power.

  FIG. 9 is a diagram illustrating an example of average power consumption in the entire apartment. In FIG. 9, two cases are represented using plots V3 and V4.

  When 15 minutes have elapsed from the start time, the server 100 determines whether or not there is a possibility that the contracted power may be exceeded by the time the demand value reaches 30 minutes, based on the average power consumption for 15 minutes acquired from the WHM 343_i.

  When the average power used for 15 minutes is the value indicated by plot V3, even if the line segment L3 connecting the plot V3 and the origin is extended, the average power used at 30 minutes does not exceed the contract power (dashed line). Min L8). In this case, the server 100 determines that there is no possibility of exceeding the contract power before the demand value has passed 30 minutes.

  On the other hand, when the average power used for 15 minutes is the value indicated by the plot V4, if the line segment L4 connecting the plot V4 and the origin is extended, the average power used at 30 minutes exceeds the contract power (the broken line segment). L9). In this case, the server 100 determines that there is a possibility that the demand value exceeds the contracted power before 30 minutes elapses.

  When determining that there is a possibility of exceeding the contract power, the server 100 executes control for reducing the power consumption of each control target device 320 in each dedicated unit 310. Specifically, the server 100 automatically transmits a control command to each control target device 320. That is, the server 100 executes forced control.

  As described above, in this example, the server 100 determines whether or not the demand value exceeds the contract power based on the average power consumption (kW) for 15 minutes (particularly, 0 to 15 minutes). When the demand value exceeds the contracted power, the server 100 automatically transmits a control command to each control target device 320 as described with reference to FIG. 1 (process (iv)).

  According to such a configuration, it is possible to prevent the demand value of the apartment 300 from exceeding the contract power.

  As described above, when it is determined that the value (target value) set lower than the contract power may be exceeded instead of the contract power, a control command is automatically issued to each control target device 320. The server 100 may be configured to transmit.

(C5. Functional configuration)
FIG. 10 is a block diagram illustrating a functional configuration of the server 100.

  Referring to FIG. 10, server 100 includes a control unit 110, a storage unit 120, and a communication processing unit 130. The control unit 110 includes a notification control unit 111, a demand control unit 112, and an electricity rate calculation unit 113. The storage unit 120 stores two-stage price plan data.

  The communication processing unit 130 is a communication interface for performing communication with other devices. The server 100 communicates with the terminal device 200 by the communication processing unit 130. The communication processing unit 130 causes the server 100 to communicate with the watt-hour meter 383 of the shared unit 350 and the watt-hour meters 343 of the dedicated units 310 via the router 351 and the MEMS 352 as illustrated in FIG. Further, the server 100 communicates with the control target device 320_i via the router 351 and the HEMS 332_i by the communication processing unit 130.

  The control unit 110 acquires information on the amount of power used in each dedicated unit 310 from each power meter 343. In addition, the control unit 110 acquires information on the power consumption of the shared unit 350 from the watt-hour meter 383.

  The notification control unit 111 of the control unit 110 determines whether or not the power consumption for 30 minutes exceeds the threshold value Th2 (0.5 kWh in the example of FIG. 5) for each dedicated unit 310.

  When the notification control unit 111 determines that the power consumption for 30 minutes in the exclusive unit 310_i exceeds the threshold Th2, the notification control unit 111 transmits an e-mail to the terminal device 200_i as described above.

  When receiving a control command for controlling the control target device 320_i from the terminal device 200_i that has received the e-mail, the control unit 110 controls the operation of the control target device 320_i according to the control command. Thereby, it is possible to reduce the amount of power used by the exclusive unit 310_i.

  The electricity charge calculation unit 113 refers to the data of the two-stage charge plan stored in the storage unit 120 and calculates the electricity charge corresponding to the amount of power used in the exclusive unit 310.

  Based on the total amount of power used acquired from each watt hour meter 343 of each dedicated unit 310 and the amount of power used acquired from the watt hour meter 383 of the shared unit 350, the demand control unit 112 determines the demand time limit of the apartment 300. It is determined whether there is a possibility that the power consumption (kWh) exceeds the contract power (kW).

  When the demand control unit 112 determines that there is a possibility of exceeding the contract power, the demand control unit 112 executes control for reducing the power consumption of each control target device 320 in each dedicated unit 310. Specifically, the demand control unit 112 automatically transmits a control command to each control target device 320. That is, the server 100 executes forced control.

  As described above, the control system 1 may be configured so that the functions of the server 100 are distributed and executed by a plurality of servers. For example, the control system 1 may be configured so that the calculation of the electricity bill is performed by a server different from the server that executes processing related to demand control and the like.

<D. Hardware configuration>
(D1. Server 100)
FIG. 11 is a diagram illustrating a typical example of the hardware configuration of the server 100. Referring to FIG. 11, server 100 includes, as main components, a processor 151 that executes a program, a ROM 152 that stores data in a nonvolatile manner, data generated by execution of the program by processor 151, or an input device. A RAM 153 that stores data input via the volatile memory, an HDD 154 that stores data in a nonvolatile manner, a communication IF (Interface) 155, an operation key 156, a power supply circuit 157, and a display 158. Each component is connected to each other by a data bus. The communication IF 155 is an interface for performing communication with other devices.

  The processing in the server 100 is realized by each hardware and software executed by the processor 151. Such software may be stored in the HDD 154 in advance. The software may be stored in other storage media and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the so-called Internet. Such software is read from the storage medium by the reading device or downloaded via the communication IF 155 or the like and then temporarily stored in the HDD 154. The software is read from the HDD 154 by the processor 151 and stored in the RAM 153 in the form of an executable program. CPU 151 executes the program.

  Each component which comprises the server 100 shown by the figure is general. Therefore, it can be said that the essential part of the present invention is the RAM 153, the HDD 154, software stored in a storage medium, or software downloadable via a network. Since the operation of each hardware of server 100 is well known, detailed description will not be repeated.

  Note that the control unit 110 illustrated in FIG. 10 is typically realized by the processor 151 executing a program stored in the HDD 154 or the like.

(D2. Terminal device 200)
FIG. 12 is a diagram illustrating a typical example of the hardware configuration of the terminal device 200. Referring to FIG. 12, terminal device 200 includes, as main components, a processor 251 that executes a program, a ROM 252 that stores data in a nonvolatile manner, data generated by execution of the program by processor 251, or an input device. RAM 253 for storing data input via volatile, flash memory 254 for storing data in a nonvolatile manner, communication IF 255, power supply circuit 256, touch screen 257, operation key 258, antenna 259, including. The components 251 to 258 are connected to each other by a data bus.

  The touch screen 257 includes a display 2571 and a touch panel 2572. The antenna 259 is an antenna for the communication IF 255. Communication IF 255 performs, for example, data transmission processing to server 100 and data reception processing transmitted from server 100. The touch screen 257 is a device for displaying various data and receiving operation inputs.

  The processing in the terminal device 200 is realized by each hardware and software executed by the processor 251. Such software may be stored in advance in the flash memory 254. The software may be stored in other storage media and distributed as a program product. Alternatively, the software may be provided as a program product that can be downloaded by an information provider connected to the so-called Internet. Such software is read from the storage medium by the reading device or downloaded via the communication IF 255 or the like and then temporarily stored in the flash memory 254. The software is read from the flash memory 254 by the processor 251 and stored in the RAM 253 in the form of an executable program. The processor 251 executes the program.

  Each component which comprises the terminal device 200 shown by the figure is general. Therefore, it can be said that the essential part of the present invention is the RAM 253, the flash memory 254, software stored in a storage medium, or software downloadable via a network. Since the operation of each hardware of terminal device 200 is well known, detailed description will not be repeated.

<E. Control structure>
FIG. 13 is a sequence diagram for explaining the flow of processing in the control system 1.

  As shown in FIG. 13, in sequence SQ2, the watt-hour meter 383 of the shared unit 350 notifies the server 100 of the power consumption for 15 minutes. In sequence SQ4, each watt hour meter 343 of each dedicated unit 310 notifies the server 100 of the power consumption for 15 minutes.

  In sequence SQ <b> 6, the server 100 determines whether or not notification by e-mail is necessary for each terminal device 200 based on the power consumption amount notified from each watt hour meter 343 of each dedicated unit 310. In sequence SQ8, server 100 transmits an e-mail to terminal apparatus 200 that has determined that notification by e-mail is necessary.

  When terminal device 200 accepts an input operation for controlling controlled device 320 in sequence SQ10, terminal device 200 transmits a control command based on the input operation to server 100 in sequence SQ12.

  In sequence SQ <b> 14, server 100 transmits the control command received from terminal device 200 to control target device 320 that is remotely controlled by terminal device 200.

  In sequence SQ16, the server 100 determines whether or not the average power consumption (demand value) in the demand time limit of the apartment 300 may exceed the contract power. If it is determined that there is a possibility of exceeding the contract power, in sequence SQ18, the server 100 automatically transmits a control command for reducing the power consumption of each control target device 320 to each control target device 320.

FIG. 14 is a flowchart for explaining the processing flow of the server 100.
Referring to FIG. 14, in step S <b> 2, server 100 obtains a power usage amount every 15 minutes from power meter 383 of shared unit 350 and each power meter 343 of each dedicated unit 310. In step S <b> 4, the server 100 determines whether or not there is a dedicated unit 310 whose power consumption exceeds a threshold Th <b> 2 (for example, 0.5 kWh).

  If the server 100 determines that there is a dedicated unit 310 whose power consumption exceeds the threshold Th2 (YES in step S2), the terminal that controls the control target device 320 installed in the dedicated unit 310 in step S6 Notification to the device 200 is made by e-mail.

  If server 100 determines that there is no dedicated unit 310 whose power consumption exceeds threshold value Th2 (NO in step S2), the process proceeds to step S12.

  When the server 100 receives the control command from the terminal device 200 that is the destination of the e-mail in step S8, the server 100 transmits the control command to the control target device 320 in step S10. For example, when receiving the control command from the terminal device 200_1, the server 100 transmits the control command to the control target device 320_1.

  In step S12, the server 100 determines whether or not the demand value may exceed the contract power. If server 100 determines that there is a possibility that the contracted power may be exceeded (YES in step S12), it sends a control command to each control target device 320 of each exclusive unit 310 in step S14. As a result, the power consumption of the entire apartment is reduced so that the demand value does not exceed the contract power.

  When server 100 determines that there is no possibility of exceeding the contract power (NO in step S12), the process proceeds to step S2.

<F. Modification>
(F1. First modification)
When the server 100 determines that the demand value (the average power used in the demand time limit of the apartment 300) exceeds the contract power, the server 100 predicts the excess amount of the average power used with respect to the contract power. This prediction is also obtained from the broken line segments L8 and L9 shown in FIG. The server 100 determines the control content for each control target device 320 based on the predicted excess amount.

  For example, the server 100 determines the set temperature for cooling based on the excess amount. When the excess amount is larger than the reference value, the server 100 sets the cooling set temperature higher than the case where the excess temperature is equal to or lower than the reference value. Alternatively, when the excess amount is greater than the reference value, the server 100 performs control to switch the operation mode of each control target device 320 from the cooling operation to the air blowing operation. The reference value is stored in advance in the server 100 by the aggregator 900.

  As described above, the server 100 predicts the excess amount of the demand value with respect to the contract power, and determines the control content for each control target device 320 based on the predicted excess amount. According to such a configuration, it is possible to prevent the demand value of the apartment 300 from exceeding the contract power.

  In the above, the excess amount of the average power consumption (kW) in the demand time period with respect to the contract power (kW) is predicted, but the present invention is not limited to this. The amount of power used (kWh) in the demand time limit of the apartment 300 with respect to the amount of power calculated from the contracted power (contracted power (kW) × 0.5h) is predicted, and each control target device 320 is based on the excess amount. The server 100 may be configured to determine the control content for. The same applies to the configuration of “(f2. Second modification)” below.

(F2. Second modification)
In the above description, the configuration has been described in which the server 100 controls the operation of each control target device 320 of each dedicated unit 310 when it is determined that the demand value exceeds the contract power. However, it is not always necessary to control all the control target devices 320. When the server 100 determines that the demand value exceeds the contract power, the server 100 may determine the control target device 320 that executes control based on the predicted excess amount.

  For example, the server 100 may group each of the plurality of control target devices 320 according to the number of floors of the exclusive unit 310 in which each of the devices to be controlled 320 is installed. For example, the server 100 can group the control target devices installed in the exclusive unit 310 on the same floor into the same group. Or the server 100 can also make the control object apparatus installed in the exclusive part 310 of a higher floor into the same group, and make the control object apparatus installed in the exclusive part 310 of a lower floor into the same group.

  In such a case, in one aspect, when the predicted excess amount is smaller than the reference value, the server 100 reduces the power consumption of the plurality of control target devices 320 belonging to the first group among the plurality of groups. Execute control. In addition, the server 100 belongs to the second group among the plurality of control target devices 320 belonging to the first group and the plurality of groups on the condition that the predicted excess amount is larger than the reference value. Control for reducing power consumption with a plurality of control target devices 320 is executed.

  Typically, the control target device 320 of the first group is a device installed in the exclusive unit 310 on a higher floor than the control target device 320 of the second group.

  (1) For example, when attention is paid to the exclusive unit 310_1, the exclusive unit 310_2, the control target device 320_1, and the control target device 320_2 shown in FIG.

  The server 100 predicts an excess amount of the demand value with respect to the contract power, and when the predicted excess amount is smaller than the reference value, executes control for reducing the power consumption of the control target device 320_1. The server 100 executes control for further reducing the power consumption of the control target device 320_2 on condition that the predicted excess amount is larger than the reference value. According to such a configuration, it is possible to limit the range of forced control.

  (2) Further, when attention is paid to the exclusive unit 310_1, the exclusive unit 310_2, the exclusive unit 310_n, the control target device 320_1, the control target device 320_2, and the control target device 320_n illustrated in FIG. . Note that the control target device 320_1 and the control target device 320_2 are in the same group.

  The server 100 predicts an excess amount of the demand value with respect to the contract power, and when the predicted excess amount is smaller than the reference value, executes control for reducing the power consumption of the control target device 320_1. The server 100 calculates the power consumption of the control target device 320_2 in the same group as the control target device 320_1 among the control target device 320_2 and the control target device 320_n on the condition that the predicted excess amount is larger than the reference value. Further reduction control is executed. According to such a configuration, forced control for each group is possible.

(F3. Third modification)
In the above description, the configuration has been described in which the server 100 controls the operation of each control target device 320 of each dedicated unit 310 when it is determined that the demand value exceeds the contract power. However, the present invention is not limited to this, and control for reducing power consumption may be performed on the control target devices 360_1, 360_2, and 360_3 of the shared unit 350.

  According to such a configuration, it is possible to further prevent the demand value of the condominium 300 from exceeding the contract power compared to a configuration in which only each control target device 320 of each exclusive unit 310 is controlled.

(F4. Fourth modification)
The server 100 may be configured to further include a function of predicting the average power consumption (each demand value) in each demand time period on the day after the next day (for example, several days later).

  The server 100 having such a configuration stores, for example, demand values for the past 35 days in demand time limit units (30 minute units). Further, the server 100 stores temperature and weather information in association with each demand value. The server 100 predicts the average electric power used in each demand time period on the day after the next day based on this information and the weather forecast and temperature forecast for the day after the next day.

  The server 100 analyzes whether each predicted demand value exceeds the contract power by a program having a predetermined algorithm. When it is determined that one of the predicted demand values exceeds the contract power, the server 100 notifies the terminal devices 200 in advance. The server 100 notifies that there is a possibility that the demand value may exceed the contract power, for example, from * am **** am to * am ** m on the * month ** day. The server 100 preferably includes a message prompting to save power at this date and time in the notification. According to such a configuration, it is possible to notify the resident in advance that the demand value exceeds the contract power. Therefore, the possibility that the demand value can be prevented from exceeding the contract power increases.

  In the above description, the server 100 has been described by taking as an example a configuration having a function of predicting the average power consumption (demand value) in each demand period on the day after the next day. The server 100 may be configured to predict power.

  As described above, the server 100 stores at least the average power used (actual value) in the past demand time period in association with the past date and time. Based on the past average power consumption (actual value), the server 100 predicts the average power consumption in each demand time period on the current day or the day after the next day. When the predicted average power consumption is higher than the contract power, the server 100 makes a predetermined notification to each terminal device 200 at a predetermined timing.

  In the above description, the configuration for transmitting a message for promoting power saving has been described as an example. However, the configuration is not limited thereto. Forcible control for reducing the power consumption of the control target device 320 may be performed on the date and time when it is determined that the contract power is exceeded. For example, the server 100 may stop the operation of all or part of the electric water heaters described above in the apartment 300.

  As described above, the server 100 automatically controls the control target device 320 in order to reduce the amount of power used in the demand time period in which the predicted average power consumption is predicted to be higher than the contract power.

(F5. Fifth modification)
Some residents of the apartment 300 do not agree with the forced control of the control target device 320 (process (iv) in FIG. 1). In such a case, even if the server 100 determines that there is a possibility that the demand value of the whole apartment exceeds the contract power for the control target device 320 of the resident exclusive unit 310, each control target A control command is not automatically transmitted to the device 320.

  On the other hand, it is preferable that the server 100 performs a process such as discounting of an electricity bill and giving a predetermined point to a resident who has agreed to the forced control of the control target device 320.

(F6. Sixth Modification)
In the above description, the two-stage rate plan has been described as an example, but the present invention is not limited to this. For example, a three-stage rate plan may be used. In this case, when a preset threshold value (for example, 0.5 kWh, 0.8 kWh) or less that is less than or equal to the amount of power used (for example, 0.6 kWh, 0.9 kWh) to move to the next stage, notification by e-mail The server 100 may be configured to do so.

  The embodiment disclosed this time is an exemplification, and the present invention is not limited to the above contents. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  1 control system, 100 server, 110 control unit, 111 notification control unit, 112 demand control unit, 113 electricity charge calculation unit, 120 storage unit, 130 communication processing unit, 151,251 processor, 152,252 ROM, 153,253 RAM 156, 258 operation keys, 157, 256 power supply circuit, 158, 2571 display, 200 terminal device, 254 flash memory, 257 touch screen, 259 antenna, 271-276, 281, 286, 287 object, 290 screen, 291 address, 300 condominium, 310 exclusive part, 320, 360 control target device, 323, 363 wireless adapter, 325, 365 non-control target device group, 332 HEMS, 341, 381 distribution board, 343, 383 watt hour meter, 350 common part, 351 router, 352 MEMS, 390 power receiving and transformation equipment, 800 electric power company, 900 aggregator, 2572 touch panel, 155,255 communication IF.

Claims (10)

A control system for managing the amount of power used in a condominium having a plurality of exclusive sections,
A server device;
A first control target device installed in a first exclusive part of the plurality of exclusive parts;
A terminal device for remotely controlling the first device to be controlled,
In the control system, when the power consumption per unit time in the first dedicated unit is less than the first threshold, the first unit price is applied, and the power consumption per unit time is Of these, the second unit price higher than the first unit price is applied to the amount of power used that exceeds the first threshold, so that the unit time per unit time in the first exclusive unit The electricity bill for
The server device
When the amount of power used by the first exclusive unit exceeds a second threshold value that is equal to or less than the first threshold value within the unit time, a first notification is given to the terminal device,
Upon receiving a control command from the terminal device based on the first notification, the first control target device is controlled based on the control command,
The control system which performs control which reduces the power consumption of a said 1st control object apparatus based on having determined that the average electric power used in the demand time limit of the said apartment may exceed a predetermined value.   The control system according to claim 1, wherein the unit time is set in the same time zone as the demand time period. The first notification is an email notification,
The control system according to claim 1 or 2, wherein an address for displaying an operation screen for controlling the first control target device is described in the electronic mail as a link destination address. The server device
Predicting the excess amount of power used in the demand period of the apartment with respect to the amount of power calculated from the predetermined value,
The control system according to any one of claims 1 to 3, wherein a control content for the first control target device is determined based on the predicted excess amount. A second control target device installed in a second exclusive part of the plurality of exclusive parts;
The server device
Predicting the excess amount of power used in the demand period of the apartment with respect to the amount of power calculated from the predetermined value,
4. The control according to claim 1, further executing control for reducing power consumption of the second control target device on condition that the predicted excess amount is larger than a reference value. 5. Control system. A second control target device installed in a second exclusive part of the plurality of exclusive parts;
A third controlled device installed in a third exclusive part of the plurality of exclusive parts;
In the server device, the first control target device and the third control target device are grouped into the same group,
The server device determines that the average power consumption may exceed the predetermined value, and the first of the second control target device and the third control target device. The control system according to any one of claims 1 to 3, further executing control for reducing power consumption of the third control target device in the same group as the control target device. The condominium further has a shared part,
The control system further includes a second control target device installed in the sharing unit,
The said server apparatus further performs control which reduces the power consumption of a said 2nd control object apparatus based on having determined that the said average electric power consumption may exceed the said predetermined value. The control system according to any one of 1 to 3. The server device
The past average power consumption is stored in association with the past date and time,
Based on the past average power usage, predict each average power usage on the day of the current day or the following day,
8. The device according to claim 1, wherein when the predicted average power consumption is higher than the predetermined value, a second notification is given to the terminal device at a predetermined timing. The described control system.   The server device automatically controls the first control target device in order to reduce the amount of power used in the demand time period in which the predicted average power consumption is predicted to be higher than the predetermined value; The control system according to claim 8. A control method for managing the amount of power used in a condominium having a plurality of exclusive parts,
The first unit price is applied when the amount of power used per unit time in the predetermined exclusive unit among the plurality of exclusive units is less than the first threshold, and the use per unit time A second unit price higher than the first unit price is applied to the amount of power used that exceeds the first threshold in the amount of power, so that in the predetermined dedicated unit Calculating the electricity rate per unit time;
When the power consumption of the predetermined exclusive unit exceeds the second threshold value equal to or less than the first threshold within the unit time, the control target device installed in the predetermined exclusive unit is remotely controlled. A predetermined notification to a terminal device for
Receiving a control command from the terminal device based on the predetermined notification;
Controlling the device to be controlled based on the control command;
A control method comprising: executing control for reducing power consumption of the control target device based on the determination that the average power consumption in the demand time limit of the apartment may exceed a predetermined value. .

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