JP2017038501A - Energy management device, energy management method, and energy management program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an energy management device capable of efficiently controlling incoming power of devices at a building having a residence area and a non-residence area, an energy management method, and an energy management program.SOLUTION: The energy management device includes: a communication section; and a control section. The communication section communicates with a control device for controlling devices in a residential area of a building. The control section controls devices at a non-residential area, which is a part of the building other than the residential area, on the basis of a signal acquired by the communication section through communication with the control device.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to an energy management apparatus, an energy management method, and an energy management program.

  BEMS (Building Energy Management System) is a system for controlling the energy of equipment in a building having a commercial department or office area such as a rental store and a common department such as a passage or an event plaza. A HEMS (Home Energy Management System) is generally a system for controlling the energy of a single house device. The dwelling part may further have a common part such as a corridor or stairs. A BEMS device (energy management device) controls equipment in a building. However, the conventional energy management apparatus may not be able to efficiently control the received power of equipment in a building (composite building) having a residential part and a non-residential part.

JP 2015-35917 A JP2015-35157A JP 2014-14237 A

  The problem to be solved by the present invention is to provide an energy management device, an energy management method, and an energy management program capable of efficiently controlling the received power of equipment in a building having a residential part and a non-residential part. is there.

  The energy management apparatus according to the embodiment includes a communication unit and a control unit. A communication part communicates with the control apparatus which controls the apparatus in the residence part of a building. A control part controls the apparatus in the non-residential part which is parts other than the residential part of a building based on the signal which the communication part acquired by communication with a control apparatus.

The figure which shows the example of a structure of the energy management system in 1st Embodiment. The figure which shows the example of the predicted value of the received power in the building in 1st Embodiment. The flowchart which shows the procedure which determines the plan of demand response control in 1st Embodiment. The flowchart which shows the procedure which determines the plan of the demand response control at the time of acquiring a demand response signal from a provider apparatus in 1st Embodiment. The flowchart which shows the procedure which determines the plan of the demand response control at the time of acquiring a demand response signal from a BEMS apparatus in 1st Embodiment. The flowchart which shows the procedure in which BEMS apparatus in 1st Embodiment estimates the received power of a 1st apparatus and a 2nd apparatus. The flowchart which shows the procedure in which the apparatus etc. of a some building share the information which shows received power in 1st Embodiment. The flowchart which shows the procedure in which equipment of a building etc. in 1st Embodiment performs a business continuity plan. The flowchart which shows the procedure in which the apparatus etc. of a some building perform a business continuity plan in 1st Embodiment. The figure which shows the example of a structure of the energy management system in 2nd Embodiment. The flowchart which shows the procedure which displays the information which shows received electric power on a display apparatus in 2nd Embodiment. The figure which shows the example of a structure of the energy management system in 3rd Embodiment. The flowchart which shows the procedure which displays the information which shows the received power of each building in a 3rd Embodiment on a display apparatus. The figure which shows the example of a structure of the energy management system in 4th Embodiment.

Hereinafter, an energy management device, an energy management method, and an energy management program according to embodiments will be described with reference to the drawings.
(First embodiment)
Hereinafter, HEMS of an embodiment is a system for controlling the energy of the apparatus in the dwelling part (collective house) which has a plurality of dwelling units. When the shared part of the building managed by the BEMS of the embodiment includes the shared part of the residential part, the BEMS of the embodiment manages the shared part such as the passage of the building and the event plaza and the shared part of the residential part. May be.

  Demand management is load adjustment so that the received power does not exceed the contract power or the target power upper limit value. Demand management methods include demand control and demand response control. The demand control is to forcibly cut off the power supplied to the load facility so that the received power does not exceed the contract power or the target power upper limit value. The demand control may be to forcibly reduce the output of the load facility so that the received power does not exceed the contract power or the target power upper limit value.

  The demand response control is to request the load facility user to reduce the power consumption of the load facility so that the received power does not exceed the contract power or the target power upper limit value. The demand response control means that the energy management device transmits a signal to a device owned or managed by the user of the load facility, so that the device receiving the signal reduces the power consumption of the load facility or stops the load facility. It may be.

  The demand response control includes self-demand response control and external request demand response control. In the self-demand response control, load adjustment is performed so as not to exceed the contract power or the target power upper limit value even when not requested by the power supplier. In the external request demand response control, load adjustment is performed according to a request from an electric power supplier. Hereinafter, both the self-demand response control and the external request demand response control are referred to as “demand response control”.

  FIG. 1 is a diagram illustrating an example of the configuration of the energy management system 1. In the first embodiment, the energy management system 1 is referred to as an “energy management system 1a”. The energy management system 1a (EMS: Energy Management System) includes a HEMS device 10 (control device) and a BEMS device 20 (energy management device).

  The HEMS device 10 is an information processing device such as a server device. The BEMS device 20 is an information processing device such as a server device. The energy management system 1a may further include a relay device 30 and relay devices 40-1 to 40-M (M is an integer of 1 or more). The relay device 30 and the relay device 40 are devices that relay communication.

  The equipment group provided in the buildings 50-1 to 50-M collectively receives power from the electric power company. Even when the buildings 50-1 to 50-M are separated from each other by a distance greater than or equal to the threshold distance, the device groups provided in the buildings 50-1 to 50-M can receive power from a power provider virtually collectively. Good. That is, the electric power company may consider that the device groups provided in the buildings 50-1 to 50-M are collectively receiving power from the electric power company.

  Hereinafter, with respect to matters common to the building 50-1 to the building 50-M, a part of the reference numerals are omitted and described as “building 50”. The building 50 is a complex building (composite facility) having a housing part 51 (collective housing) having a plurality of dwelling units and a part (non-residential part) other than the housing part.

  The dwelling unit 51 includes N (N is an integer of 1 or more) dwelling units and a common unit. The dwelling unit of the dwelling unit 51 includes an HGW 510 (home gateway) and a HEMS terminal 511 for each dwelling unit. The HGW 510 is a communication device. The HGW 510 relays communication between the HEMS device 10 and the HEMS terminal 511.

  The HEMS terminal 511 is an information terminal such as a computer device. The HEMS terminal 511 communicates with the HEMS device 10 via the HGW 510. The HEMS terminal 511 may communicate with the BEMS device 20 via the HGW 510. The HEMS terminal 511 receives from the HEMS device 10 or the BEMS device 20 a signal requesting reduction of received power (hereinafter referred to as “request signal”). The request signal includes, for example, information indicating an e-mail or an automatic demand response (ADR) command.

  The HEMS terminal 511 controls the received power (electric power load) of the device in the dwelling unit. Thereby, the HEMS terminal 511 can control the received power (energy) of the device in the dwelling unit. The HEMS terminal 511 may control the device in the dwelling unit based on the request signal received by the HGW 510.

  The shared part of the residence part 51 is a facility shared by users of the residence part 51. The common part is, for example, a hallway or a staircase. The common part of the dwelling unit 51 includes a first device 512 as a device (load facility) that consumes power. The first device 512 is, for example, a lighting device or an air conditioning device. The first device 512 may be, for example, a power generation device. Hereinafter, the power generator is, for example, an emergency generator.

  Hereinafter, the part (non-residential part) other than the residential part 51 in the building 50 is the commercial part 52. The commercial section 52 is a facility used for commerce. The commercial unit 52 is, for example, a rental store (tenant) or an office. The commercial unit 52 includes a second device 520 as a device (load facility) that consumes power. The second device 520 is, for example, a lighting device or an air conditioning device. For example, the second device 520 may include a power generation device.

  The energy management system 1a may further include a relay device 70 and a relay device 80. The relay device 70 and the relay device 80 are devices that relay communication. The business entity apparatus 60 and the relay apparatus 70 are provided outside the energy management system 1a.

  The business entity apparatus 60 is an information processing apparatus such as a server apparatus. The business operator device 60 operates in response to an operation by the power business operator. The provider device 60 communicates with the HEMS device 10 via the relay device 70, the communication line 100, and the relay device 30. The business entity device 60 transmits a demand response signal to the HEMS device 10 via the relay device 70 in response to an operation by the power business operator. The demand response signal is a signal for temporarily reducing the received power in the building 50.

  The communication line 100 is, for example, an internet line. The communication line 100 may include a local network.

  The HEMS device 10 communicates with the HGW 510 and the HEMS terminal 511 of the building 50 via the relay device 30, the communication line 100, and the relay device 40. Thereby, the HEMS device 10 can control a device group in each dwelling unit of the dwelling unit 51. The HEMS device 10 communicates with the BEMS device 20 via the relay device 30, the communication line 100, and the relay device 80.

  The BEMS apparatus 20 controls the 2nd apparatus 520 in the commercial part 52 via a local network. As a result, the BEMS device 20 can control the second device 520 in the commercial section 52. The BEMS device 20 may control the first device 512 in the shared part of the residence 51 via the relay device 80, the communication line 100, and the relay device 40. Thereby, the BEMS device 20 can control the first device 512 in the shared part of the residence part 51. In addition, the BEMS apparatus 20 may control the 1st apparatus 512 in the common part of the residence part 51 via a local network.

A configuration example of the HEMS device 10 will be described.
The HEMS device 10 includes a first communication unit 11, a storage unit 12, a control unit 13, and a first control unit 14. Some or all of the first communication unit 11, the control unit 13, and the first control unit 14 are executed by a processor such as a CPU (Central Processing Unit) executing a program stored in the storage unit. This is a software function unit that functions according to the above. Some or all of these functional units may be hardware functional units such as LSI (Large Scale Integration) and ASIC (Application Specific Integrated Circuit).

  The first communication unit 11 communicates with the provider device 60 via the relay device 30. For example, the first communication unit 11 receives a demand response signal. The first communication unit 11 communicates with the HGW 510 and the HEMS terminal 511 via the relay device 30. For example, the first communication unit 11 receives compliance information indicating whether or not to respond to a demand response request (power saving request) from the HEMS terminal 511. The first communication unit 11 communicates with the BEMS device 20 via the relay device 30. The first communication unit 11 stores the received information in the storage unit 12.

The storage unit 12 includes, for example, a nonvolatile storage medium (non-temporary recording medium) such as a ROM, a flash memory, or an HDD. The storage unit 12 may include a volatile storage medium such as a RAM or a register, for example. The storage unit 12 stores, for example, a program for causing the software function unit to function.
The control unit 13 controls each unit of the HEMS device 10.

  When the first communication unit 11 receives the demand response signal, the first control unit 14 transmits a request signal to each HEMS terminal 511 via the first communication unit 11. The 1st control part 14 totals the total value (DR total amount) of the received electric power which can reduce a dwelling unit based on compliance information. The first control unit 14 transmits the total value of received power that can be reduced by the dwelling unit to the BEMS device 20 via the first communication unit 11.

A configuration example of the BEMS device 20 will be described.
The BEMS device 20 includes a second communication unit 21, a storage unit 22, a control unit 23, and a second control unit 24. Some or all of the second communication unit 21, the control unit 23, and the second control unit 24 are software functions that function when, for example, a processor such as a CPU executes a program stored in the storage unit Part. Some or all of these functional units may be hardware functional units such as an LSI or an ASIC.

  The second communication unit 21 communicates with the HEMS device 10 via the relay device 80. For example, the second communication unit 21 receives a total value of received power that can be reduced by dwelling units. The second communication unit 21 communicates with the second device 520. The second communication unit 21 may communicate with the HGW 510 and the HEMS terminal 511 of the residence unit 51 via the relay device 80. The second communication unit 21 may communicate with the first device 512 of the residence unit 51 via the relay device 80. The second communication unit 21 stores the received information in the storage unit 22.

The storage unit 22 includes, for example, a nonvolatile storage medium (non-temporary recording medium) such as a ROM, a flash memory, and an HDD. The storage unit 22 may include a volatile storage medium such as a RAM or a register, for example. The storage unit 22 stores, for example, a program for causing the software function unit to function.
The control unit 23 controls each unit of the BEMS device 20.

  The second control unit 24 determines a predicted value (demand prediction) of the total value of the received power of the first device 512 and the second device 520. The second control unit 24 estimates the shortage of the received power that is insufficient based on the total value of the received power of the first device 512 and the second device 520. That is, the second control unit 24 estimates a total value of received power that should be covered by power saving or power generation.

  The second control unit 24 may determine a predicted value of the total value of the received power of the devices in the dwelling unit 51, the first device 512, and the second device 520. The second control unit 24 may estimate the total value of the received power that is insufficient based on the total value of the received power of the devices in the dwelling unit 51, the first device 512, and the second device 520.

  FIG. 2 is a diagram illustrating an example of a predicted value of received power in a building. The horizontal axis indicates the time at 24 hours. The vertical axis represents the predicted value of the received power in the building (the predicted value of the total value of the received power of each device). The horizontal line indicates contract power. The second control unit 24 determines a predicted value of the peak of received power in the building 50 based on prediction data such as weather and a prediction model. The prediction model is a demand prediction model using a neural network, for example. The second control unit 24 determines a predicted value of the total value of the received power of the first device 512 and the second device 520. The second control unit 24 determines the expected time (time series data) of the time when the received power of the first device 512 and the second device 520 peaks. The second control unit 24 may determine an expected time period (time series data) in which the received power of the first device 512 and the second device 520 exceeds the contract power.

  Note that the predicted value of the total value of the received power of the first device 512 and the second device 520 and the predicted time of the peak time of the received power are determined by the second control unit 24 of the BEMS device 20 instead of being determined. , May be determined by the first control unit 14 of the HEMS device 10. The first control unit 14 of the HEMS device 10 may transmit the determined predicted value (demand prediction), predicted time information, and predicted time zone information to the BEMS device 20.

  FIG. 3 is a flowchart showing a procedure for determining a demand response control plan (predictive type demand management). The second communication unit 21 acquires forecast data such as weather (step S101). The second control unit 24 acquires data representing the prediction model of the received power from the storage unit 12 (step S102). The second control unit 24 determines a predicted value of received power peak and predicted data (time-series data) of received power based on the received power prediction model (step S103). The second control unit 24 determines a demand response control plan (step S104). The second control unit 24 transmits a control signal to the device group to be controlled by demand response control (step S105).

  FIG. 4 is a flowchart showing a procedure for determining a demand response control plan when a demand response signal is acquired from the provider device 60 (in the case of an external DR). The business entity apparatus 60 transmits a demand response signal to the HEMS apparatus 10 (step S201). The first control unit 14 of the HEMS device 10 acquires a demand response signal from the business entity device 60 (step S202). The first control unit 14 of the HEMS device 10 transmits a request signal (demand response request) to each HEMS terminal 511 (step S203).

  The first control unit 14 of the HEMS device 10 acquires compliance information indicating whether or not to respond to the demand response request from each HEMS terminal 511 (step S204). The first control unit 14 of the HEMS device 10 estimates a total value (demand response total amount) of received power that can be reduced by dwelling units (step S205). The first control unit 14 of the HEMS device 10 transmits the total received power that can be reduced by the dwelling unit to the BEMS device 20 via the first communication unit 11 (step S206).

  The second control unit 24 of the BEMS device 20 estimates the total value of the received power that is insufficient for the demand response request even if the dwelling unit group has reduced the received power (step S207). The second control unit 24 of the BEMS device 20 transmits a demand response signal or control signal including information representing an automatic demand response command to the first device 512. The second control unit 24 of the BEMS device 20 transmits a control signal to the second device 520 such as a store terminal (step S208).

  FIG. 5 is a flowchart illustrating a procedure for determining a demand response control plan when a demand response signal is acquired from the BEMS device 20 (in the case of an internal DR). In FIG. 5, unlike the case shown in FIG. 4, the BEMS device 20 transmits a demand response signal (load adjustment request signal) to the HEMS device 10.

  The second control unit 24 of the BEMS device 20 determines a predicted value of the total value of the received power of the first device 512 and the second device 520 (step S301). The second control unit 24 of the BEMS device 20 estimates the received power exceeding the contract power of the first device 512 and the second device 520, that is, the received power that needs to be reduced by demand response control. The second control unit 24 of the BEMS device 20 transmits a demand response signal (load adjustment request signal) to the HEMS device 10 via the second communication unit 21 (step S302).

  The first control unit 14 of the HEMS device 10 transmits a request signal (demand response request) to each HEMS terminal 511. The request signal is, for example, a signal including an email or an automatic demand response command (step S303). The first control unit 14 of the HEMS device 10 acquires compliance information indicating whether or not to respond to the demand response request from each HEMS terminal 511 (step S304). The first control unit 14 of the HEMS device 10 estimates a total value (demand response total amount) of received power that can be reduced by dwelling units (step S305). The first control unit 14 of the HEMS device 10 transmits the total value of the received power that can be reduced by the dwelling unit to the BEMS device 20 via the first communication unit 11 (step S306).

  The second control unit 24 of the BEMS device 20 estimates the total value of the received power that is insufficient with respect to the received power based on the demand response request (step S307). The second control unit 24 of the BEMS device 20 transmits a demand response signal or control signal including information representing an automatic demand response command to the first device 512. The second control unit 24 of the BEMS device 20 transmits a control signal to the second device 520 such as a store terminal (step S308).

  FIG. 6 is a flowchart illustrating a procedure in which the BEMS device 20 predicts the received power of the first device 512 and the second device 520. That is, FIG. 6 is a flowchart showing prediction cooperation. The HEMS terminal 511 measures the received power of the dwelling unit. The HEMS terminal 511 transmits information indicating the received power of the dwelling unit to the HEMS device 10 (step S401). The 1st control part 14 of HEMS device 10 acquires information which shows receiving power of a dwelling unit from each HEMS terminal 511 (Step S402).

  The 1st control part 14 of HEMS device 10 totals the value of receiving electric power of a dwelling unit. The first control unit 14 of the HEMS device 10 transmits the total value of the received power of the dwelling unit to the BEMS device 20 (step S403). The second control unit 24 of the BEMS device 20 sums the received power values of the first device 512 and the second device 520 (step S404). The second control unit 24 of the BEMS device 20 determines a predicted value of the total value of the received power of each dwelling unit, the first device 512, and the second device 520 in the building 50 (step S405). The second control unit 24 of the BEMS device 20 advances the processing to step S302 illustrated in FIG.

  FIG. 7 is a flowchart illustrating a procedure in which information indicating received power is shared by a plurality of building devices and the like. That is, FIG. 7 is a flowchart showing a procedure of demand response control by cooperation of a plurality of buildings. In each building 50, each HEMS terminal 511 transmits information indicating the received power of the dwelling unit to the HEMS device 10 (step S501). The 1st control part 14 of HEMS device 10 acquires information which shows receiving power of a dwelling unit from each HEMS terminal 511 for every building 50 (Step S502).

  The 1st control part 14 of HEMS device 10 totals the value of receiving electric power of a dwelling unit. The first control unit 14 of the HEMS device 10 transmits the total value of the received power of the dwelling unit to the BEMS device 20 (step S503). The second control unit 24 of the BEMS device 20 sums the received power values of the first device 512 and the second device 520 (step S504). The second control unit 24 of the BEMS device 20 determines a predicted value of the total value of the received power of each dwelling unit, the first device 512, and the second device 520 in the building 50. The devices of the plurality of buildings 50 share the predicted value of the total value of the received power in the building 50 (step S505). The second control unit 24 of the BEMS device 20 advances the processing to step S302 illustrated in FIG.

  FIG. 8 is a flowchart showing a procedure in which the equipment of the building 50 executes a business continuity planning (BCP). The procedure shown in FIG. 8 is executed, for example, when commercial power is interrupted due to a wide area disaster. When a wide-area disaster occurs, some functions of the communication line 100 may stop. Even when the commercial power fails, the energy management system 1a can efficiently execute the business continuity plan (BCP) in the commercial section 52. The energy management system 1a can improve the continuation performance (LCP: Life Continuity Performance) of the building 50.

  The second control unit 24 of the BEMS device 20 transmits information indicating the value of received power (the power load in the building 50) of the first device 512 and the second device 520 to the first device 512 and the second device via the local network. Obtained from the device 520 (step S601). The second control unit 24 of the BEMS device 20 transmits a demand response signal (load adjustment request signal) to each HEMS terminal 511 (step S602). The second control unit 24 of the BEMS device 20 transmits a control signal to the first device 512 to be controlled by demand response control and the second device 520 to be controlled by demand control. The second control unit 24 of the BEMS device 20 may cause the power generation device as the second device 520 to generate power (step S603).

  FIG. 9 is a flowchart showing a procedure for executing a business continuity plan (BCP) by devices of a plurality of buildings 50. The second control unit 24 of the BEMS device 20 transmits information indicating the received power (the power load in the building 50) of the first device 512 and the second device 520 of the building 50-1 via the local network. From the first device 512 and the second device 520 (step S701).

  The second control unit 24 of the BEMS device 20 transmits information indicating the received power (power load in the building 50) of the first device 512 and the second device 520 other than the building 50-1 via the local network to the building 50-. Obtained from the first device 512 and the second device 520 other than 1 (step S702).

  The second control unit 24 of the BEMS device 20 transmits a demand response signal (load adjustment request signal) to each HEMS terminal 511 of the building 50-1 (step S703). The second control unit 24 of the BEMS device 20 transmits a request signal to each HEMS terminal 511 other than the building 50-1 (step S704). The second control unit 24 of the BEMS device 20 transmits a control signal to the first device 512 to be controlled by the demand response control of the building 50-1 and the second device 520 to be controlled by the demand control (Step S705). The second control unit 24 of the BEMS device 20 transmits a control signal to the first device 512 to be controlled by demand response control and the second device 520 to be controlled by demand control other than the building 50-1. The second control unit 24 of the BEMS device 20 may cause the power generation device as the second device 520 to generate power (step S706).

  As described above, the energy management system 1 a according to the first embodiment includes the HEMS device 10 and the BEMS device 20. The HEMS device 10 includes a first communication unit 11 and a first control unit 14. The first communication unit 11 communicates with devices other than the HEMS device 10. The 1st control part 14 controls the apparatus in the residence part 51 of a building. The BEMS device 20 includes a second communication unit 21 and a second control unit 24. The second communication unit 21 communicates with the first communication unit 11. The second control unit 24 controls equipment in a non-residential part that is a part other than the residential part 51 of the building 50 based on a signal acquired by the second communication part 21 through communication with the first communication part 11.

  Thereby, the BEMS apparatus 20 (energy management apparatus) of 1st Embodiment is the energy of the apparatus in the building 50 which has the dwelling part 51 (a housing complex) which has several dwelling units, and the commercial parts 52, such as a tenant. It becomes possible to control efficiently.

  That is, the BEMS device 20 according to the first embodiment efficiently receives the received power of the equipment in the building 50 by the HEMS device 10 and the BEMS device 20 in the building 50 (complex building, complex facility) communicating with each other. It becomes possible to control.

  The energy management system 1a of the first embodiment can efficiently control the received power of the equipment in the building 50 even when the load characteristics of the electric power of the residential section and the commercial section are different. The energy management system 1a of the first embodiment can execute power control in cooperation with a plurality of buildings 50. In the energy management system 1a of the first embodiment, when a plurality of buildings 50 are requested to perform demand response control, the energy management system 1a is shorter than a case where a resident of a residential section or a user of a commercial section suppresses the power load of the device. It is possible to efficiently control the received power over time.

  The energy management system 1a of the first embodiment adjusts the power load by demand management that keeps the received power in the building 50 below the contract power even when the received power in the building 50 is likely to exceed the contract power. Can do.

  The energy management system 1a of the first embodiment can improve the continuation performance (LCP) in the dwelling unit 51 by the power generation by the power generation device as the second device 520. The energy management system 1a of the first embodiment can execute a business continuity plan (BCP) in the commercial department 52 by power generation by a power generation device as the second device 520. The energy management system 1a of 1st Embodiment can perform the demand response control in the building 50 because the HEMS apparatus 10 and the BEMS apparatus 20 share electric power data.

  The HEMS device 10 and the BEMS device 20 of the first embodiment determine the predicted value of the received power peak of the plurality of buildings 50. The HEMS device 10 and the BEMS device 20 execute at least one of demand control and demand response control as a demand management method based on the predicted value of the received power peak of the plurality of buildings 50. Thereby, the energy management system 1a of the first embodiment can improve the accuracy of demand management.

  The BEMS device 20 according to the first embodiment issues a demand response signal to the first device 512 in order to perform demand response control of the first device 512 in the building 50. The BEMS device 20 according to the first embodiment issues a control signal to the second device 520 in order to perform demand control on the second device 520 in the building 50. Thereby, the energy management system 1a of 1st Embodiment can adjust the electric power load in the residence part 51 and the commercial part 52 similarly to the case where the provider apparatus 60 issues the demand response signal.

  The energy management system 1a of the first embodiment can adjust a large power load in the building 50. The energy management system 1a of the first embodiment can execute demand management with high accuracy. In the energy management system 1a of the first embodiment, the contract power is lower than that in the case where the demand management is not executed, and the basic charge of the power contract can be reduced.

  The HEMS device 10 according to the first embodiment notifies the BEMS device 20 of the energy consumption data of each dwelling unit, so that the BEMS device 20 according to the first embodiment predicts the received power in the building 50 (demand prediction). Can be improved.

  The BEMS device 20 of the first embodiment transmits a demand response signal to the HEMS device 10 of the first embodiment for demand response control in the building 50. The HEMS device 10 of the first embodiment notifies the request signal to the HEMS terminal 511 of each dwelling unit based on the demand response signal, so that the BEMS device 20 of the first embodiment reduces the power load of the dwelling unit 51. Can be adjusted.

  The BEMS device 20 according to the first embodiment issues a demand response signal in the building 50 to cause the power generation device as the second device 520 to generate power when the commercial power fails. That is, the BEMS device 20 of the first embodiment performs demand response control itself even when not requested by the power supply company. The BEMS device 20 according to the first embodiment transmits a demand response signal to the HEMS device 10 in order to adjust the power load. The HEMS apparatus 10 of 1st Embodiment transmits a request signal to the HEMS terminal 511 of each dwelling unit.

  The energy management system 1a of 1st Embodiment can cover the electric power load in the building 50 with a power generator, and can continue the business in a commercial space. The dwelling unit 51 of the first embodiment can ensure the dwelling performance. The commercial unit 52 of the first embodiment can execute a business continuity plan.

(Second Embodiment)
The second embodiment is different from the first embodiment in that energy information such as the value of received power is visualized (visualized) for a specific building 50. In the second embodiment, only differences from the first embodiment will be described.

  FIG. 10 is a diagram illustrating an example of the configuration of the energy management system 1. In the second embodiment, the energy management system 1 is referred to as an “energy management system 1b”. The energy management system 1b further includes a display device 90 (signage terminal) as compared with the energy management system 1a shown in the first embodiment. The second control unit 24 of the BEMS device 20 visualizes the information indicating the received power by displaying the information indicating the received power on the display device 90 (signage terminal). The display device 90 may include a communication unit that can communicate with a personal computer or a smartphone terminal.

  The second control unit 24 of the BEMS device 20 confirms the consistency between the information indicating the received power of the dwelling unit and the information indicating the received power of the first device 512 and the second device 520. The second control unit 24 of the BEMS device 20 may correct the information indicating the received power. For example, the 2nd control part 24 measures directly, when the received power (power consumption) measured about the residence part 51 and the commercial part 52 and the received power measured about the whole building 50 do not correspond. In consideration of power loss that cannot be performed, the received power measured for the residential unit 51 and the commercial unit 52 may be multiplied by a constant value. Thus, the second control unit 24 can match the received power measured for the residential unit 51 and the commercial unit 52 with the received power measured for the entire building 50. The second control unit 24 can correct the error in the received power data caused by power loss due to the transformer.

  FIG. 11 is a flowchart illustrating a procedure for displaying information indicating the received power on the display device 90. The 1st control part 14 of HEMS device 10 acquires information (HEMS data) which shows receiving power of a dwelling unit from each HEMS terminal 511 (Step S801). The first control unit 14 of the HEMS device 10 transmits information indicating the received power of the dwelling unit to the BEMS device 20 via the first communication unit 11 (step S802).

  The second control unit 24 of the BEMS device 20 uses the first device 512 and the second device 520 as information (power receiving facility data, shared unit data, commercial facility data) indicating the received power of the first device 512 and the second device 520. (Step S803). The second control unit 24 of the BEMS device 20 confirms the consistency between the information indicating the received power of the dwelling unit and the information indicating the received power of the first device 512 and the second device 520. The second control unit 24 of the BEMS device 20 may correct the information indicating the received power (step S804).

  The second control unit 24 of the BEMS device 20 visualizes the information indicating the received power by displaying the information indicating the received power on the display device 90 (signage terminal) (step S805). The second control unit 24 of the BEMS device 20 transfers information indicating the received power to the HEMS device 10. The HEMS device 10 converts information indicating received power into Web data. For example, the HEMS device 10 converts information indicating the received power into an HTML (HyperText Markup Language) format (step S806).

  As described above, the first control unit 14 or the second control unit 24 of the second embodiment includes information (for example, a graph) based on the value of the received power of the device in the residence unit 51 and devices other than the residence unit 51. The information based on the value of the received power is displayed on the display device 90.

  As a result, the BEMS device 20 (energy management device) of the second embodiment has, for a specific building 50, a building 50 having a residential part 51 (collective housing) having a plurality of dwelling units and a commercial part 52 such as a tenant. It is possible to efficiently control the energy of the equipment in

  The user (customer) of the residential section 51 or the commercial section 52 of each building 50 can browse the energy information displayed on the display devices 90-1 to 90-M using a personal computer, a smartphone terminal, or the like. it can.

  In the energy management system 1b of the second embodiment, the HEMS device 10 and the BEMS device 20 cooperate with each other in the building 50 for the residential unit 51 and the commercial unit 52 (commercial space) having the dwelling unit and the common unit. Visualization of energy is realized.

  A user (customer) of the residential unit 51 or the commercial unit 52 of the building 50 can browse the energy information that is centrally managed by the building 50 using a personal computer, a smartphone terminal, or the like.

  The user of the residential unit 51 or the commercial unit 52 of each building 50 can save power in the plurality of buildings 50 by energy visualization based on the relationship between the energy consumption of his / her power load equipment and the energy consumption of the plurality of buildings 50. It can contribute to power saving.

(Third embodiment)
The third embodiment is different from the second embodiment in that energy information such as values of received power is visualized (visualized) for a plurality of buildings 50. In the third embodiment, only differences from the second embodiment will be described.

  FIG. 12 is a diagram illustrating an example of the configuration of the energy management system 1. In the third embodiment, the energy management system 1 is referred to as an “energy management system 1c”. The energy management system 1c further includes display devices 90-2 to 90-M as compared with the energy management system 1b shown in the second embodiment. The second control unit 24 of the BEMS device 20 visualizes the information indicating the received power by displaying the information indicating the received power on the display devices 90-1 to 90-M (signage terminals).

  The second control unit 24 of the BEMS device 20 confirms the consistency between the information indicating the received power of the dwelling unit and the information indicating the received power of the first device 512 and the second device 520 for the group of buildings 50. The second control unit 24 of the BEMS device 20 may correct information indicating received power for the group of buildings 50. For example, the 2nd control part 24 measures directly, when the received power (power consumption) measured about the residence part 51 and the commercial part 52 and the received power measured about the whole building 50 do not correspond. In consideration of power loss that cannot be performed, the received power measured for the residential unit 51 and the commercial unit 52 may be multiplied by a constant value. Thereby, the 2nd control part 24 can make the received power measured about the residence part 51 and the commercial part 52, and the received power measured about the whole building 50 about the building 50 group. The second control unit 24 can correct an error in received power data caused by power loss due to a transformer or the like for the group of buildings 50.

  FIG. 13 is a flowchart illustrating a procedure for displaying information indicating the received power of each building 50 on the display devices 90-1 to 90-M. The 1st control part 14 of HEMS device 10 acquires information (HEMS data) which shows receiving power of a dwelling unit from each HEMS terminal 511 about each building 50 (Step S901). The first control unit 14 of the HEMS device 10 transmits information indicating the received power of the dwelling unit to the BEMS device 20 via the first communication unit 11 (step S902).

  The second control unit 24 of the BEMS device 20 uses, for each building 50, information (power receiving facility data, common unit data, commercial facility data) indicating power received by the first device 512 and the second device 520 for the first device 512. And it acquires from the 2nd apparatus 520 (step S903). The second control unit 24 of the BEMS device 20 confirms the consistency between the information indicating the received power of the dwelling unit and the information indicating the received power of the first device 512 and the second device 520. The second control unit 24 of the BEMS device 20 may correct the information indicating the received power (step S904).

  The second control unit 24 of the BEMS device 20 visualizes the information indicating the received power by displaying the information indicating the received power on the display devices 90-1 to 90-M for each building 50 (step S905). The second control unit 24 of the BEMS device 20 transfers information indicating the received power to the HEMS device 10. The HEMS device 10 converts information indicating received power into Web data. For example, the HEMS device 10 converts information indicating the received power into an HTML format (step S906).

  As described above, the first control unit 14 or the second control unit 24 of the third embodiment is based on information based on the value of the received power of the device in the residential unit 51 and the value of the received power of the device other than the residential unit 51. Are displayed on the display devices 90-1 to 90-M.

  As a result, the BEMS device 20 (energy management device) of the third embodiment, for a plurality of buildings 50, is a device in the building 50 having a residential part (collective housing) having a plurality of dwelling units and a commercial part such as a tenant. It is possible to efficiently control the energy of.

  The user (customer) of the residential section 51 or the commercial section 52 of each building 50 can browse the energy information displayed on the display devices 90-1 to 90-M using a personal computer, a smartphone terminal, or the like. it can.

  The HEMS device 10 of the third embodiment shares the energy information of the devices in the dwelling unit 51 of each building 50 with the BEMS device 20. The BEMS device 20 of the third embodiment shares energy information of devices in the commercial section 52 of each building 50 with the HEMS device 10. The HEMS device 10 and the BEMS device 20 of the third embodiment can visualize energy information of a plurality of buildings 50.

  The user of the residential unit 51 or the commercial unit 52 of each building 50 can save power in the plurality of buildings 50 by energy visualization based on the relationship between the energy consumption of his / her power load equipment and the energy consumption of the plurality of buildings 50. It can contribute to power saving.

(Fourth embodiment)
The fourth embodiment is different from the third embodiment in that the energy management system 1 includes the BEMS device 20 for each building 50. In the fourth embodiment, only differences from the third embodiment will be described.

  FIG. 14 is a diagram illustrating an example of the configuration of the energy management system. In the fourth embodiment, the energy management system 1 is referred to as an “energy management system 1d”. The energy management system 1d further includes BEMS devices 20-2 to 20-M, as compared with the energy management system 1c shown in the third embodiment. The second control unit 24-m of the BEMS device 20-m (m is any one of 1 to M) displays the received power by displaying information indicating the received power on the display device 90-m (signage terminal). Visualize the information shown.

  The second control unit 24-m of the BEMS device 20-m determines the consistency between the information indicating the received power of the dwelling unit and the information indicating the received power of the first device 512 and the second device 520 for the building 50-m. Check. The second control unit 24-m of the BEMS device 20-m may correct the information indicating the received power for the building 50-m. For example, the second control unit 24 directly measures when the received power (power consumption) measured for the residential unit 51 and the commercial unit 52 does not match the received power measured for the entire building 50-m. In consideration of power loss that cannot be performed, the received power measured for the residential unit 51 and the commercial unit 52 may be multiplied by a constant value. Thus, the second control unit 24-m can match the received power measured for the residential unit 51 and the commercial unit 52 with the received power measured for the entire building 50 for the building 50-m. . The second control unit 24-m can correct an error in received power data caused by power loss or the like due to a transformer for the building 50-m.

  As described above, the BEMS devices 20-1 to 20 -M of the fourth embodiment are information (for example, graphs) based on the value of the received power of the devices in the dwelling unit 51 for the buildings 50-1 to 50 -M. And the information based on the value of the received electric power of the apparatus other than the residence part 51 is displayed on the display devices 90-1 to 90-M.

  As a result, the BEMS device 20 (energy management device) of the fourth embodiment includes, for a plurality of buildings 50, equipment in the building 50 having a residential part (multi-family house) having a plurality of dwelling units and a commercial part such as a tenant. It is possible to more efficiently control the energy.

  The user (customer) of the residential section 51 or the commercial section 52 of each building 50 can browse the energy information displayed on the display devices 90-1 to 90-M using a personal computer, a smartphone terminal, or the like. it can.

  According to at least one embodiment described above, based on a communication unit that communicates with a control device that controls equipment in a dwelling unit of a building, and a signal acquired by the communication unit through communication with the control device, the dwelling unit of the building By having the control unit that controls the device in the non-residential part, which is a part other than the above, it is possible to efficiently control the received power of the device in the building having the residential part and the non-residential part.

  As mentioned above, although some embodiment of this invention was described, these embodiment is shown as an example and is not intending limiting the range of invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1a ... Energy management system, 1b ... Energy management system, 1c ... Energy management system, 1d ... Energy management system, 10 ... HEMS apparatus, 11 ... 1st communication part, 12 ... Memory | storage part, 13 ... Control part, 14 ... 1st Control unit, 20 ... BEMS device, 21 ... second communication unit, 22 ... storage unit, 23 ... control unit, 24 ... second control unit, 30 ... relay device, 50 ... building, 51 ... residential unit, 52 ... commercial department , 60 ... operator device, 70 ... relay device, 80 ... relay device, 90 ... display device, 100 ... communication line, 510 ... HGW, 511 ... HEMS terminal, 512 ... first device, 520 ... second device

Claims (9)

A communication unit that communicates with a control device that controls equipment in a residential part of the building;
Based on a signal acquired by the communication unit through communication with the control device, a control unit that controls equipment in a non-residential part that is a part other than the residential part of the building;
An energy management device comprising:   The control unit, based on the predicted value of the total received power of the device in the residential unit and the predicted value of the total received power of the device in the non-residential unit, the device in the residential unit and the non-residential The energy management apparatus of Claim 1 which controls the apparatus in a part. The communication unit obtains a total value of received power of devices in the residence unit from the control device,
The energy control device according to claim 2, wherein the control unit determines a predicted value of the total value of the received power of the device in the residential unit based on the total value of the received power of the device in the residential unit. The communication unit transmits a demand response signal, which is a signal for temporarily reducing received power, to the control device,
The energy management device according to claim 1, wherein the control device controls equipment in the dwelling unit based on the demand response signal.   The energy management device according to claim 1, wherein the control unit controls the power generation device based on a predicted value of a total value of received power of the device in the residential unit and the device in the non-residential unit.   2. The energy management according to claim 1, wherein the control unit causes a display device to display information based on a value of received power of a device in the residential unit and information based on a value of received power of the device in the non-residential unit. apparatus.   The energy management device according to claim 1, wherein the control unit controls equipment in the non-residential part of the plurality of buildings. An energy management method in an energy management device,
Communicating with a control device for controlling equipment in a residential part of the building;
Based on a signal acquired by communication with the control device, controlling a device in a non-residential part that is a part other than the residential part of the building
Including energy management methods. On the computer,
A procedure for communicating with a control device for controlling equipment in a residential part of the building;
Based on a signal acquired by communication with the control device, a procedure for controlling equipment in a non-residential part that is a part other than the residential part of the building;
An energy management program to make it run.

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