Deprecated: The each() function is deprecated. This message will be suppressed on further calls in /home/zhenxiangba/zhenxiangba.com/public_html/phproxy-improved-master/index.php on line 456
JP7830705B2 - Power supply and demand adjustment system, power supply and demand adjustment method, and program - Google Patents
[go: Go Back, main page]

JP7830705B2 - Power supply and demand adjustment system, power supply and demand adjustment method, and program - Google Patents

Power supply and demand adjustment system, power supply and demand adjustment method, and program

Info

Publication number
JP7830705B2
JP7830705B2 JP2024570768A JP2024570768A JP7830705B2 JP 7830705 B2 JP7830705 B2 JP 7830705B2 JP 2024570768 A JP2024570768 A JP 2024570768A JP 2024570768 A JP2024570768 A JP 2024570768A JP 7830705 B2 JP7830705 B2 JP 7830705B2
Authority
JP
Japan
Prior art keywords
power
electricity
amount
heating
water
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
JP2024570768A
Other languages
Japanese (ja)
Other versions
JPWO2024252457A1 (en
JPWO2024252457A5 (en
Inventor
聡 中野
正之 小松
紀之 小宮
優 水城
公一 広瀬
一輝 高田
篤史 西岡
佳奈子 甫水
啓 石崎
雅文 飯塚
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Mitsubishi Electric Corp
Original Assignee
Mitsubishi Electric Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Mitsubishi Electric Corp filed Critical Mitsubishi Electric Corp
Publication of JPWO2024252457A1 publication Critical patent/JPWO2024252457A1/ja
Publication of JPWO2024252457A5 publication Critical patent/JPWO2024252457A5/ja
Application granted granted Critical
Publication of JP7830705B2 publication Critical patent/JP7830705B2/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24HFLUID HEATERS, e.g. WATER OR AIR HEATERS, HAVING HEAT-GENERATING MEANS, e.g. HEAT PUMPS, IN GENERAL
    • F24H1/00Water heaters, e.g. boilers, continuous-flow heaters or water-storage heaters
    • F24H1/18Water-storage heaters
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24HFLUID HEATERS, e.g. WATER OR AIR HEATERS, HAVING HEAT-GENERATING MEANS, e.g. HEAT PUMPS, IN GENERAL
    • F24H15/00Control of fluid heaters
    • F24H15/10Control of fluid heaters characterised by the purpose of the control
    • F24H15/16Reducing cost using the price of energy, e.g. choosing or switching between different energy sources
    • F24H15/164Reducing cost using the price of energy, e.g. choosing or switching between different energy sources where the price of the electric supply changes with time

Landscapes

  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Thermal Sciences (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Management, Administration, Business Operations System, And Electronic Commerce (AREA)
  • Heat-Pump Type And Storage Water Heaters (AREA)

Description

本開示は、電力需給調整システム、電力需給調整方法、及び、プログラムに関する。This disclosure relates to a power supply and demand adjustment system, a power supply and demand adjustment method, and a program.

電力事業者が需要家に供給する電力を調達するコストを低減するための種々の技術が知られている。例えば、特許文献1には、各電力需要者の需要予測量、電力取引情報、履歴などに基づいたポジションで入札をして電力卸市場から電力を調達し、翌日の発電計画・需給計画を生成する電力需要調達支援サーバについて記載されている。Various technologies are known to reduce the cost of electricity procurement for power companies to supply to consumers. For example, Patent Document 1 describes a power demand procurement support server that procures electricity from the wholesale electricity market by bidding based on the demand forecast amount, electricity trading information, and history of each electricity consumer, and generates a power generation plan and supply and demand plan for the following day.

特開2018-77834号公報Japanese Patent Publication No. 2018-77834

需要家には、貯湯式の給湯機を有している場合も多い。このような需要家の場合、給湯機の沸き上げ時間を工夫することで電力調達コストをさらに低減することが期待できる。引用文献1に記載の技術では、給湯機を管理するようなことについては記載がないため、このような効果を得ることはできない。Many consumers have storage-type water heaters. For such consumers, further reductions in electricity procurement costs can be expected by optimizing the water heating time of the water heater. The technology described in Reference 1 does not include any mention of managing the water heater, and therefore cannot achieve this effect.

本開示は、上記実情に鑑みてなされたものであり、電力事業者の電力調達コストをより低減することができる電力需給調整システムなどを提供することを目的とする。This disclosure is made in view of the above circumstances and aims to provide a power supply and demand adjustment system that can further reduce the power procurement costs of power companies.

上記目的を達成するため、本開示に係る電力需給調整システムは、
管内の給湯機を備える需要家への電力需給を調整する電力需給調整システムであって、
前記給湯機の消費電力量実績から未来の沸き上げ必要電力量を予測する沸き上げ電力量予測部と、
未来の一定時間毎の電力調達価格に基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間を決定し、前記沸き上げ必要電力量の少なくとも一部を前記沸き上げシフト先期間で消費する沸き上げスケジュールを作成する沸き上げ計画部と、
前記沸き上げスケジュールに従って、前記管内の前記給湯機を制御する給湯機制御部と、
前記管内の消費電力量実績から、前記管内の未来の一定時間毎の需要電力量を予測する電力需要予測部と、
前記電力需要予測部が予測した前記需要電力量と前記沸き上げ計画部が作成した前記沸き上げスケジュールとに基づいて、前記管内の未来の一定時間毎の調達必要電力量を決定する電力調達計画部と、
を備える。
To achieve the above objectives, the power supply and demand adjustment system relating to this disclosure is:
A power supply and demand adjustment system that adjusts the supply and demand of electricity to consumers equipped with hot water heaters within the pipes,
A water heating power prediction unit predicts the future amount of power required for heating water based on the actual power consumption of the aforementioned water heater,
A water heating planning unit determines the water heating shift period that minimizes electricity procurement costs based on future electricity procurement prices at regular intervals , and creates a water heating schedule that consumes at least a portion of the required water heating amount during the water heating shift period.
A water heater control unit controls the water heater in the pipe according to the aforementioned heating schedule,
A power demand forecasting unit that predicts the amount of electricity demand at regular intervals in the future within the aforementioned pipe based on the actual amount of electricity consumed within the pipe,
Based on the amount of electricity demand predicted by the electricity demand forecasting unit and the water heating schedule created by the water heating planning unit, the electricity procurement planning unit determines the amount of electricity that will need to be procured at regular intervals in the future within the service area.
It is equipped with.

本開示によれば、電力事業者の電力調達コストをより低減することが可能となる。This disclosure will make it possible to further reduce the electricity procurement costs of power companies.

本開示の実施形態に係る電力需給調整システムの全体構成を示す図A diagram showing the overall configuration of a power supply and demand adjustment system according to an embodiment of this disclosure. 本開示の実施形態に係る機器管理装置の構成を示すブロック図Block diagram showing the configuration of the equipment management device according to the embodiment of this disclosure. 本開示の実施形態に係る電力管理装置の構成を示すブロック図Block diagram showing the configuration of a power management device according to an embodiment of this disclosure. 本開示の実施形態に係る電力需給調整システムの構成を示すブロック図Block diagram showing the configuration of a power supply and demand adjustment system according to an embodiment of this disclosure. 本開示の実施形態に係る給湯機制御処理のフローチャートFlowchart of water heater control process according to an embodiment of this disclosure 本開示の実施形態に係る沸き上げ必要電力量予測処理のフローチャートFlowchart of the power generation required for water heating according to the embodiment of this disclosure 本開示の実施形態に係る沸き上げ必要電力量予測処理を説明するための図(その1)Figure (1) illustrating the power generation power prediction process according to the embodiment of this disclosure. 本開示の実施形態に係る沸き上げ必要電力量予測処理を説明するための図(その2)Figure (2) illustrating the power generation required for boiling according to the embodiment of this disclosure. 本開示の実施形態に係る沸き上げスケジュール作成処理のフローチャートFlowchart of the boiling schedule creation process according to the embodiment of this disclosure 本開示の実施形態に係る沸き上げスケジュール作成処理を説明するための図A diagram illustrating the boiling schedule creation process according to the embodiment of this disclosure. 本開示の実施形態において、電力の調達コストが最も安くなるシフト継続時間の時間帯の特定の仕方を説明するための図A diagram illustrating how to identify the time period of shift duration in which the cost of procuring electricity is lowest, according to embodiments of this disclosure.

以下、本開示の実施形態について、図面を参照しながら詳細に説明する。なお、図中同一または相当部分には同一符号を付す。The embodiments of this disclosure will be described in detail below with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals.

本開示の実施形態に係る電力需給調整システム1について説明する。電力需給調整システム1の構成を図1に示す。電力需給調整システム1は、管内の各需要家800への電力需給を調整するシステムであり、機器管理装置100と電力管理装置200とを備える。管内の全ての需要家800は、給湯機300と、電力測定器400と、コントローラ500と、を備えている。さらに、いくつかの管内の需要家800は、太陽光パネルなどの発電設備600を備えているものもある。A power supply and demand adjustment system 1 according to an embodiment of this disclosure will now be described. Figure 1 shows the configuration of the power supply and demand adjustment system 1. The power supply and demand adjustment system 1 is a system that adjusts the power supply and demand to each consumer 800 within the service area, and comprises an equipment management device 100 and a power management device 200. All consumers 800 within the service area are equipped with a water heater 300, a power meter 400, and a controller 500. Furthermore, some consumers 800 within the service area are equipped with power generation equipment 600 such as solar panels.

給湯機300は、貯湯タンク及びヒートポンプを備える貯湯式の給湯機である。給湯機300は、水を貯湯タンクに貯め、それをヒートポンプで沸き上げる。貯湯タンクには数百リットルの水を蓄えることができる。給湯機300は、沸き上げ時に貯湯タンク内の大量の水を沸き上げるため、かなりの電力を消費するが、一度沸き上げてしまえば、その後、住人は沸き上げた水(お湯)を用いることができる。The water heater 300 is a storage-type water heater equipped with a hot water storage tank and a heat pump. The water heater 300 stores water in the hot water storage tank and heats it using the heat pump. The hot water storage tank can hold several hundred liters of water. The water heater 300 consumes a considerable amount of electricity to heat the large volume of water in the storage tank during the heating process, but once the water is heated, residents can then use the heated water (hot water).

また、給湯機300は消費した電力の値を送信する通信機能を備えている。給湯機300は、例えば5分毎にその5分で消費した電力量を測定し、測定値をコントローラ500に送信している。コントローラ500は、給湯機300から電力量の値を受信する毎に、ネットワーク700を介して、機器管理装置100に送信している。Furthermore, the water heater 300 is equipped with a communication function that transmits the value of the power consumed. For example, the water heater 300 measures the amount of power consumed in a 5-minute period every 5 minutes and transmits the measured value to the controller 500. Each time the controller 500 receives a value of the amount of power from the water heater 300, it transmits it to the equipment management device 100 via the network 700.

電力測定器400は、需要家800で使用される電力を測定する機能と、測定した電力の値を送信する通信機能とを備えるスマートメータである。需要家800で使用される電力には、給湯機300が使用する電力も含まれるし、図示せぬ空調機、照明機器、調理家電機器等が使用する電力も含まれる。電力測定器400は、例えば30分毎にその30分間に需要家800内で消費された電力量を測定し、測定値をコントローラ500に送信している。The power meter 400 is a smart meter equipped with a function to measure the power used by the customer 800 and a communication function to transmit the measured power value. The power used by the customer 800 includes the power used by the water heater 300, as well as the power used by air conditioners, lighting equipment, cooking appliances, etc. (not shown). The power meter 400 measures the amount of power consumed within the customer 800 during a 30-minute period, for example, every 30 minutes, and transmits the measured value to the controller 500.

コントローラ500は、HEMS(Home Energy Management System)の規格に準拠した制御装置であり、需要家800内の各種電気機器の運転を制御する。コントローラ500は、30分毎に、需要家800で消費される電力量の値を電力測定器400から取得し、ネットワーク700を介して電力管理装置200に送信する。また、コントローラ500は、5分毎に、給湯機300で消費される電力量の値を給湯機300から取得し、ネットワーク700を介して機器管理装置100に送信する。The controller 500 is a control device compliant with HEMS (Home Energy Management System) standards and controls the operation of various electrical appliances within the customer 800. Every 30 minutes, the controller 500 acquires the amount of electricity consumed by the customer 800 from the power meter 400 and transmits it to the power management device 200 via the network 700. Additionally, every 5 minutes, the controller 500 acquires the amount of electricity consumed by the water heater 300 from the water heater 300 and transmits it to the equipment management device 100 via the network 700.

需要家800は、それぞれ一戸建ての住宅でも良いし、マンション、アパートといった集合住宅の中の一つの住戸でも良い。本実施の形態においてはどの需要家800も給湯機300、電力測定器400、コントローラ500を備えている。Each customer 800 may be a detached house or a single unit in a multi-unit building such as an apartment or condominium. In this embodiment, each customer 800 is equipped with a water heater 300, a power meter 400, and a controller 500.

機器管理装置100は、ネットワーク700を介して、需要家800内の給湯機300を監視、制御するためのコンピュータである。例えば、機器管理装置100は、ネットワーク700を介して、給湯機300の消費電力量の値を取得する。また、機器管理装置100は、ネットワーク700を介して、各給湯機300に対し、沸き上げ指令を送信することにより、各給湯機300の沸き上げ制御を行う。The equipment management device 100 is a computer for monitoring and controlling the water heaters 300 within the customer 800 via the network 700. For example, the equipment management device 100 obtains the power consumption value of the water heaters 300 via the network 700. The equipment management device 100 also controls the water heating of each water heater 300 by transmitting a heating command to each water heater 300 via the network 700.

機器管理装置100は、図2に示すように、制御部110と、記憶部120と、通信部130とを備える。制御部110は、CPU(Central Processing Unit)、ROM(Read Only Memory)、RAM(Random Access Memory)等を備え、機器管理装置100を統括制御する。記憶部120は、フラッシュメモリ、EPROM(Erasable Programmable Read Only Memory)、EEPROM(Electrically Erasable Programmable ROM)等の不揮発性の半導体メモリを備える。記憶部120は、制御部110が各種処理を実行するために使用するプログラム及びデータを記憶したり、制御部110が各種処理を実行することにより生成又は取得するデータを記憶したりする。通信部130は、ネットワーク700に接続する機能を有し、制御部110の制御に従って、ネットワーク700に接続された各機器と通信する。As shown in Figure 2, the device management device 100 comprises a control unit 110, a storage unit 120, and a communication unit 130. The control unit 110 includes a CPU (Central Processing Unit), ROM (Read Only Memory), RAM (Random Access Memory), etc., and provides overall control of the device management device 100. The storage unit 120 includes non-volatile semiconductor memory such as flash memory, EPROM (Erasable Programmable Read Only Memory), and EEPROM (Electrically Erasable Programmable ROM). The storage unit 120 stores programs and data used by the control unit 110 to execute various processes, and also stores data generated or acquired by the control unit 110 when executing various processes. The communication unit 130 has the function of connecting to the network 700 and communicates with each device connected to the network 700 according to the control of the control unit 110.

図1に戻り、電力管理装置200は、需要家800の消費電力を監視、制御するためのコンピュータである。例えば、電力管理装置200は、ネットワーク700を介して、需要家800の消費電力量の値を取得する。また、電力管理装置200は、電力市場から需要家800で必要な電力を調達するための処理を行う。Returning to Figure 1, the power management device 200 is a computer for monitoring and controlling the power consumption of the customer 800. For example, the power management device 200 obtains the power consumption value of the customer 800 via the network 700. The power management device 200 also performs processing to procure the power required by the customer 800 from the electricity market.

電力管理装置200は、図3に示すように、制御部220と、記憶部230と、通信部240とを備える。制御部220は、CPU、ROM、RAM等を備え、電力管理装置200を統括制御する。記憶部230は、フラッシュメモリ、EPROM、EEPROM等の不揮発性の半導体メモリを備える。記憶部230は、制御部220が各種処理を実行するために使用するプログラム及びデータを記憶したり、制御部220が各種処理を実行することにより生成又は取得するデータを記憶したりする。通信部240は、ネットワーク700に接続する機能を有し、制御部220の制御に従って、ネットワーク700に接続された各機器と通信する。As shown in Figure 3, the power management device 200 comprises a control unit 220, a storage unit 230, and a communication unit 240. The control unit 220 includes a CPU, ROM, RAM, etc., and provides overall control of the power management device 200. The storage unit 230 includes non-volatile semiconductor memory such as flash memory, EPROM, and EEPROM. The storage unit 230 stores programs and data used by the control unit 220 to execute various processes, and also stores data generated or acquired by the control unit 220 as it executes various processes. The communication unit 240 has the function of connecting to the network 700 and communicates with each device connected to the network 700 according to the control of the control unit 220.

ここで、図4は、電力需給調整システム1の機能的構成を示したものである。機器管理装置100は、給湯機電力収集部101と、給湯機電力履歴記憶部102と、沸き上げ電力量予測部103と、沸き上げ計画部104と、沸き上げスケジュール105と、給湯機制御部106と、沸き上げ調整部107と、給湯機固有情報記憶部108と、を備える。Here, Figure 4 shows the functional configuration of the power supply and demand adjustment system 1. The equipment management device 100 includes a water heater power collection unit 101, a water heater power history storage unit 102, a water heating power amount prediction unit 103, a water heating planning unit 104, a water heating schedule 105, a water heater control unit 106, a water heating adjustment unit 107, and a water heater specific information storage unit 108.

給湯機電力収集部101は、5分毎に、管内の各コントローラ500から各給湯機300の消費電力量の値を取得し、給湯機電力履歴記憶部102にこれまでの実績として蓄積記憶する。The water heater power collection unit 101 acquires the power consumption values of each water heater 300 from each controller 500 in the pipe every 5 minutes and stores them in the water heater power history storage unit 102 as past performance.

給湯機電力履歴記憶部102には、給湯機電力収集部101が収集した各給湯機300の電力量の実績値が直近14日間分記憶される。The water heater power history storage unit 102 stores the actual power consumption values for each water heater 300 collected by the water heater power collection unit 101 for the most recent 14 days.

沸き上げ電力量予測部103は、給湯機電力履歴記憶部102に記憶されている過去の給湯機300の電力量の実績値から、未来(翌日1日分)の沸き上げに必要な電力量を予測する。以下の説明では、沸き上げ電力量予測部103が予測した電力量を沸き上げ必要電力量とも表記する。The water heating power consumption prediction unit 103 predicts the amount of power required for water heating in the future (for one day the following day) based on past power consumption data of the water heater 300 stored in the water heater power history storage unit 102. In the following explanation, the amount of power predicted by the water heating power consumption prediction unit 103 will also be referred to as the required water heating power.

沸き上げ計画部104は、電力調達コストが小さくなるように給湯機300の運転計画を決定する。具体的には、沸き上げ計画部104は、後述する電力調達価格予測部205が予測した電力調達価格と後述する給湯機固有情報記憶部108に記憶されている各給湯機300に関する固有の情報とに基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間を決定し、沸き上げ必要電力量の少なくとも一部を沸き上げシフト先期間にシフトする沸き上げスケジュール105を作成する。The water heating planning unit 104 determines the operation plan for the water heaters 300 in a way that minimizes electricity procurement costs. Specifically, the water heating planning unit 104 determines the water heating shift period that minimizes electricity procurement costs based on the electricity procurement price predicted by the electricity procurement price forecasting unit 205 (described later) and the unique information about each water heater 300 stored in the water heater-specific information storage unit 108 (described later), and creates a water heating schedule 105 that shifts at least a portion of the required electricity for water heating to the water heating shift period.

給湯機制御部106は、沸き上げ計画部104が作成した沸き上げスケジュール105に従って、管内の各給湯機300を制御する。The water heater control unit 106 controls each water heater 300 in the pipe according to the water heating schedule 105 created by the water heating planning unit 104.

沸き上げ調整部107は、後述する調整指令部210が算出した調整電力量に相当する電力量を増減することが可能な給湯機300を特定し、特定した給湯機300に、給湯機制御部106による沸き上げスケジュール105に従った運転とは異なる沸き上げ運転をするよう指令する。The water heating adjustment unit 107 identifies a water heater 300 that can increase or decrease the amount of power equivalent to the adjustment power amount calculated by the adjustment command unit 210 (described later), and instructs the identified water heater 300 to perform a water heating operation different from the operation according to the water heating schedule 105 by the water heater control unit 106.

給湯機固有情報記憶部108には、管内の各給湯機300に固有の情報を記憶する。具体的には、給湯機固有情報記憶部108には、各給湯機300の定格消費電力、最大貯湯量、現在の湯量、加熱能力、保温効率等を示す情報が記憶されている。なお、給湯機300の定格消費電力は、その給湯機300を最大出力で運転させたときの消費電力であり、その給湯機300における消費電力の最大値に相当する。The water heater-specific information storage unit 108 stores information specific to each water heater 300 in the pipe. Specifically, the water heater-specific information storage unit 108 stores information such as the rated power consumption, maximum hot water storage capacity, current hot water volume, heating capacity, and heat retention efficiency of each water heater 300. The rated power consumption of the water heater 300 is the power consumption when the water heater 300 is operated at maximum output, and corresponds to the maximum power consumption of that water heater 300.

電力管理装置200は、電力収集部201と、電力履歴記憶部202と、電力需要予測部203と、電力調達価格実績記憶部204と、電力調達価格予測部205と、電力調達計画部206と、電力調達スケジュール207と、電力調達部208と、発電制御部209と、調整指令部210と、を備える。The power management device 200 comprises a power collection unit 201, a power history storage unit 202, a power demand forecasting unit 203, a power procurement price history storage unit 204, a power procurement price forecasting unit 205, a power procurement planning unit 206, a power procurement schedule 207, a power procurement unit 208, a power generation control unit 209, and an adjustment command unit 210.

電力収集部201は、30分毎に、管内の需要家800の各コントローラ500から各需要家800の消費電力量の値を取得し、電力履歴記憶部202にこれまでの実績として記憶する。The power collection unit 201 acquires the power consumption values of each customer 800 within its service area from each controller 500 every 30 minutes and stores them in the power history storage unit 202 as past performance.

電力履歴記憶部202には、電力収集部201が収集した各需要家800の電力量の実績値が直近14日間分記憶される。The power history storage unit 202 stores the actual power consumption values for each customer 800 collected by the power collection unit 201 for the most recent 14 days.

電力需要予測部203は、電力履歴記憶部202に記憶されている各需要家800の消費電力量の実績値に基づいて、管内の需要家800全体での未来(翌日)の一定期間毎の需要電力量を予測する。The power demand forecasting unit 203 predicts the total amount of power demand for all customers 800 in the service area for a fixed period of time in the future (the next day), based on the actual power consumption values of each customer 800 stored in the power history storage unit 202.

電力調達価格実績記憶部204には、過去に調達した電力の調達価格の実績値が記憶されている。調達価格は、例えば、単位電力量当たりの調達に要する金額で表される。The power procurement price history storage unit 204 stores the actual procurement prices of electricity procured in the past. The procurement price is expressed, for example, as the amount required to procure electricity per unit quantity.

電力調達価格予測部205は、電力調達価格実績記憶部204に記憶されている調達価格の実績値に基づいて、管内における翌日1日における30分毎の電力調達価格を予測する。The electricity procurement price forecasting unit 205 predicts the electricity procurement price for every 30 minutes for the following day within the service area, based on the actual procurement price values stored in the electricity procurement price history storage unit 204.

電力調達計画部206は、電力需要予測部203が予測した需要電力量と沸き上げ計画部104が立案した一定時間毎の沸き上げ電力量計画(沸き上げスケジュール105)とに基づき、管内の翌日の一定時間毎の調達必要電力量を決定して電力調達スケジュール207を作成する。The Power Procurement Planning Department 206 determines the amount of electricity needed to be procured at regular intervals for the following day within its service area, based on the amount of electricity demand predicted by the Power Demand Forecasting Department 203 and the electricity heating schedule (heating schedule 105) for regular intervals devised by the Heating Planning Department 104, and creates a Power Procurement Schedule 207.

電力調達部208は、電力調達スケジュール207に基づいて、調達必要電力量を電力市場または発電設備600から調達する。The power procurement department 208 procures the required amount of electricity from the electricity market or power generation facilities 600 based on the power procurement schedule 207.

発電制御部209は、管内の発電設備600に接続されており、当該発電設備600から調達する分の調達必要電力量を少なくとも発電するように当該発電設備600を制御する。The power generation control unit 209 is connected to the power generation equipment 600 within the pipe and controls the power generation equipment 600 to generate at least the amount of electricity required to be procured from the power generation equipment 600.

調整指令部210は、管内の消費電力量実績と、調達必要電力量とに差異が生ずる場合に、当該差異分を埋め合わせるための調整電力量を算出する。The adjustment command unit 210 calculates the amount of adjustment power to compensate for any discrepancy between the actual power consumption within the service area and the amount of power required for procurement.

続いて、電力需給調整システム1が実行する給湯機制御処理について説明する。電力需給調整システム1は、常に、機器管理装置100の給湯機電力収集部101が5分毎に給湯機300の消費電力量を収集して給湯機電力履歴記憶部102に記憶する処理、および、電力管理装置200の電力収集部201が30分毎に需要家800の消費電力量を収集して電力履歴記憶部202に記憶する処理が並行して実行されている。そして、これらの処理とは別スレッドで並行して、図5に示す給湯機制御処理が毎日朝7時に実行される。Next, we will explain the water heater control process executed by the power supply and demand adjustment system 1. The power supply and demand adjustment system 1 always has the following processes running in parallel: the water heater power collection unit 101 of the equipment management device 100 collects the amount of power consumed by the water heater 300 every 5 minutes and stores it in the water heater power history storage unit 102; and the power collection unit 201 of the power management device 200 collects the amount of power consumed by the customer 800 every 30 minutes and stores it in the power history storage unit 202. In parallel with these processes, in a separate thread, the water heater control process shown in Figure 5 is executed every day at 7:00 AM.

給湯機制御処理が開始されると、まず、機器管理装置100の沸き上げ電力量予測部103は、給湯機電力履歴記憶部102に記憶されている過去の各給湯機300の電力量の実績値から、翌日1日分の沸き上げ必要電力量を予測する沸き上げ必要電力量予測処理を実行する(ステップS11)。沸き上げ必要電力量予測処理の詳細について、図6のフローチャートを用いて説明する。When the water heater control process begins, the first thing the water heating power prediction unit 103 of the equipment management device 100 does is to perform a water heating power prediction process (step S11) which predicts the amount of water heating power required for the next day based on the actual values of the past power consumption of each water heater 300 stored in the water heater power history storage unit 102. The details of the water heating power prediction process will be explained using the flowchart in Figure 6.

まず、沸き上げ電力量予測部103は、給湯機電力履歴記憶部102に記憶されている直近14日分の管内の各給湯機300の電力量の履歴から、管内の給湯機300全体の1日における、30分毎の平均消費電力量を算出する(ステップS111)。First, the water heating power consumption prediction unit 103 calculates the average power consumption every 30 minutes for all water heaters 300 in the pipe over a day, based on the power consumption history of each water heater 300 in the pipe for the past 14 days, which is stored in the water heater power history storage unit 102 (step S111).

ステップS111で算出した30分毎の平均消費電力量には、昼間の時間帯(9時~19時)にシフトして沸き上げをした分が含まれている。そのため、沸き上げ電力量予測部103は、ステップS111で算出した平均消費電力量のうち、昼間の時間帯の平均消費電力量を深夜の時間帯(0時~6時)にシフトする(ステップS112)。深夜時間帯であればどのようにシフトするかは任意であるが、給湯機300全体の30分当たりの消費電力量の上限値を超えないようにする。ここでの給湯機300全体の30分当たりの消費電力量の上限値は、給湯機固有情報記憶部108に記憶されている各給湯機300の定格消費電力から求めることができる。例えば、管内に定格消費電力が1kWの給湯機300が5台、2kWの給湯機300が5台あるとすると、30分当たりの消費電力量の上限値は7.5kWhとなる。なお、沸き上げ電力量予測部103は、各給湯機300の定格消費電力の平均値を保有しておき、この平均値から1台の給湯機300の30分当たりの消費電力量の上限値を求め、これらを管内の給湯機300の台数分足し合わせることにより、給湯機300全体の30分当たりの消費電力量の上限値を求めてもよいThe average power consumption every 30 minutes calculated in step S111 includes the amount of water heated during the daytime (9:00 to 19:00). Therefore, the water heating power consumption prediction unit 103 shifts the average power consumption during the daytime from the average power consumption calculated in step S111 to the nighttime (12:00 to 6:00) (step S112). The way in which the shift occurs during the nighttime is arbitrary, but it should not exceed the upper limit of the total power consumption per 30 minutes for all water heaters 300. The upper limit of the total power consumption per 30 minutes for all water heaters 300 can be determined from the rated power consumption of each water heater 300 stored in the water heater-specific information storage unit 108. For example, if there are five water heaters 300 with a rated power consumption of 1 kW and five water heaters 300 with a rated power consumption of 2 kW in the pipe, the upper limit of the power consumption per 30 minutes will be 7.5 kWh. Alternatively, the water heating power consumption prediction unit 103 may store the average rated power consumption of each water heater 300, determine the upper limit of the power consumption per 30 minutes for one water heater 300 from this average value, and add these up for all water heaters 300 in the pipe to determine the upper limit of the power consumption per 30 minutes for all water heaters 300.

例えば、ステップS111で図7に示すように給湯機300全体の平均消費電力量が算出された場合を考える。この場合、ステップS112において、図8に示すように、上述した30分当たりの消費電力量の上限値Zを越えない範囲で、昼間の時間帯の平均消費電力量の部分Aが、夜間時間帯の部分Bにシフトされる。For example, consider the case where the average power consumption of the entire water heater 300 is calculated in step S111, as shown in Figure 7. In this case, in step S112, as shown in Figure 8, the portion A of the average power consumption during the daytime is shifted to the portion B of the nighttime, within the range that does not exceed the upper limit Z of power consumption per 30 minutes mentioned above.

図6に戻り、続いて、沸き上げ電力量予測部103は、ステップS112でシフトされた給湯機300全体の平均消費電力量から給湯機300全体の1日分の沸き上げ必要電力量を算出する(ステップS113)。なお、ステップS112のシフトをしない給湯機300全体の平均消費電力量から1日分の沸き上げ必要電力量を算出してもよい。以上で沸き上げ必要電力量予測処理は終了する。Returning to Figure 6, the water heating power prediction unit 103 then calculates the total daily power required for heating the water heater 300 from the average power consumption of the water heater 300 as shifted in step S112 (step S113). Alternatively, the daily power required for heating may be calculated from the average power consumption of the water heater 300 as a whole without the shift in step S112. This completes the water heating power required prediction process.

図5に戻り、沸き上げ必要電力量予測処理が終了すると、電力管理装置200の電力需要予測部203は、管内の需要家800全体での未来(翌日)の一定期間毎(30分毎)の需要電力量を予測する(ステップS12)。具体的には、電力需要予測部203は、電力履歴記憶部202に記憶されている各需要家800の消費電力量の実績値を平均化することで需要電力量を予測すればよい。なお、このとき電力需要予測部203は、給湯機300の沸き上げを昼間の時間帯にシフトしない場合の需要電力量を予測するのが望ましい。即ち、電力需要予測部203は、図8で説明したような、昼間の時間帯の沸き上げシフトを深夜時間帯に戻す処理(シフトを行わなかった状態に戻す処理)を行った上で、需要家800全体での未来(翌日)の一定期間毎(30分毎)の需要電力量を予測する。Returning to Figure 5, once the process for predicting the amount of electricity needed for heating is complete, the power demand forecasting unit 203 of the power management device 200 predicts the amount of electricity demand for all customers 800 in the service area at regular intervals (every 30 minutes) for the future (next day) (step S12). Specifically, the power demand forecasting unit 203 can predict the amount of electricity demand by averaging the actual electricity consumption values of each customer 800 stored in the power history storage unit 202. At this time, it is desirable for the power demand forecasting unit 203 to predict the amount of electricity demand when the heating of the water heater 300 is not shifted to daytime hours. That is, the power demand forecasting unit 203 performs the process of returning the daytime heating shift to nighttime hours (the process of returning to a state where no shift was performed), as explained in Figure 8, and then predicts the amount of electricity demand for all customers 800 at regular intervals (every 30 minutes) for the future (next day).

続いて、電力管理装置200の電力調達価格予測部205は、電力調達価格実績記憶部204に記憶されている電力調達価格の実績値に基づいて、管内における翌日1日における30分毎の電力調達価格を予測する(ステップS13)。Next, the power procurement price prediction unit 205 of the power management device 200 predicts the power procurement price for every 30 minutes for the following day within its service area, based on the actual power procurement price stored in the power procurement price history storage unit 204 (step S13).

続いて、機器管理装置100の沸き上げ計画部104は、ステップS13で予測した電力調達価格に基づいて、電力調達コストが小さくなるように給湯機300の沸き上げスケジュール105を作成する沸き上げスケジュール作成処理を実行する(ステップS14)。沸き上げスケジュール作成処理の詳細について図9を用いて説明する。Next, the water heating planning unit 104 of the equipment management device 100 executes a water heating schedule creation process (step S14) to create a water heating schedule 105 for the water heater 300 that minimizes electricity procurement costs, based on the electricity procurement price predicted in step S13. The details of the water heating schedule creation process will be explained with reference to Figure 9.

沸き上げスケジュール作成処理が開始されると、まず、沸き上げ計画部104は、給湯機300全体での夜間(0時~6時)から昼間(9時~19時)に沸き上げシフトする電力量(昼間沸き上げ電力量)を算出する(ステップS141)。When the water heating schedule creation process begins, the water heating planning unit 104 first calculates the amount of electricity (daytime water heating electricity) to be shifted from nighttime (0:00 to 6:00) to daytime (9:00 to 19:00) for the entire water heater 300 (step S141).

ここで、昼間沸き上げ電力量の算出について具体的に説明する。管内の各給湯機300は、基本的に、毎日、夜間沸き上げを開始する直前の時刻(例えば、23時頃)に、夜間から昼間にシフトする昼間沸き上げ電力量を予測し、予測に従って沸き上げ運転を行っている。例えば、各給湯機300は、23時に、過去の一定期間、例えば直近2週間の湯の使用実績、タンクの残量等から、沸き上げに必要な1日分の必要電力量を算出し、そのうちの一部、例えば30%を昼間にシフトする分として昼間沸き上げ電力量を予測している。なお、各給湯機300による昼間沸き上げ電力量の予測方法は種々の方法が考えられ、これに限定されるものではない。そのため、沸き上げ計画部104は、管内の各給湯機300から、給湯機300が直近に予測した昼間沸き上げ電力量の予測値を取得し、それらを合計することで、給湯機300全体での昼間沸き上げ電力量を算出することができる。なお、沸き上げ計画部104は、直近の予め定めた日数分(例えば、14日分)の管内の各給湯機300が予測した昼間沸き上げ電力量の予測値の平均値から、給湯機300全体での昼間沸き上げ電力量を算出してもよい。Here, we will specifically explain how to calculate the daytime heating power consumption. Each water heater 300 in the pipe basically predicts the daytime heating power consumption that will shift from nighttime to daytime, at the time just before nighttime heating begins each day (for example, around 11 PM), and operates the heating system according to the prediction. For example, at 11 PM, each water heater 300 calculates the amount of power required for one day of heating based on the hot water usage record for a certain period in the past, for example, the last two weeks, the remaining amount in the tank, etc., and predicts the daytime heating power consumption by shifting a portion of that, for example, 30%, to daytime. Note that there are various methods for predicting the daytime heating power consumption by each water heater 300, and it is not limited to this. Therefore, the heating planning unit 104 can obtain the predicted daytime heating power consumption values that each water heater 300 has most recently predicted from each water heater 300 in the pipe, and calculate the total daytime heating power consumption for all water heaters 300 by summing them up. The water heating planning unit 104 may also calculate the total daytime water heating power for all water heaters 300 from the average of the predicted daytime water heating power values predicted by each water heater 300 in the pipe for the most recent predetermined number of days (for example, 14 days).

続いて、沸き上げ計画部104は、昼間沸き上げシフトするシフト先期間の継続時間(シフト継続時間)を算出する(ステップS142)。具体的には、沸き上げ計画部104は、図10に示すように、ステップS141で算出した昼間沸き上げ電力量を、30分毎に管内の各給湯機300(給湯機A~C)に、30分当たりの消費電力量の上限分ずつ順に割り振っていく。従って、この図において、面積が給湯機A~Cの消費電力量を表す各矩形の高さは、給湯機A~Cの消費電力の上限(定格消費電力)を表す。そして、沸き上げ計画部104は、昼間沸き上げ電力量を全て割り振った場合の30分のコマ数に相当する時間をシフト継続時間として算出する。即ち、図10では、シフト継続時間は90分と算出される。Next, the water heating planning unit 104 calculates the duration of the shift period for daytime water heating (shift duration) (step S142). Specifically, as shown in Figure 10, the water heating planning unit 104 allocates the daytime water heating power calculated in step S141 to each of the water heaters 300 (water heaters A to C) in the pipe every 30 minutes, up to the upper limit of their power consumption per 30 minutes. Therefore, in this figure, the height of each rectangle whose area represents the power consumption of water heaters A to C represents the upper limit of power consumption (rated power consumption) of water heaters A to C. The water heating planning unit 104 then calculates the shift duration as the time equivalent to the number of 30-minute intervals when all of the daytime water heating power has been allocated. That is, in Figure 10, the shift duration is calculated to be 90 minutes.

続いて、沸き上げ計画部104は、ステップS13で予測した電力の調達価格に基づいて、昼間の時間帯(9時~17時)の中から、最も電力の調達コストが安くなるシフト継続時間の時間帯を特定する(ステップS143)。例えば、ステップS13で予測したシフト継続時間を90分とすると、沸き上げ計画部104は、図11に示すように、9時~17時の範囲で、9時~10時30分の時間帯t1、9時30分~11時の時間帯t2、・・・、15時30分~17時の時間帯t14のように、30分ずつシフト継続時間である90分の長さの時間帯をずらしながら、都度、予測した調達価格を参照していくことによって、時間帯t1~t14の中から電力調達コストが最小となる時間帯を特定することができる。Next, the water heating planning unit 104 identifies the time period with the lowest power procurement cost from the daytime hours (9:00 to 17:00) based on the power procurement price predicted in step S13 (step S143). For example, if the shift duration predicted in step S13 is 90 minutes, the water heating planning unit 104, as shown in Figure 11, can identify the time period with the lowest power procurement cost from among time periods t1 to t14 by referring to the predicted procurement price each time, shifting the time period by 30 minutes in the range of 9:00 to 17:00, such as time period t1 from 9:00 to 10:30, time period t2 from 9:30 to 11:00, ..., time period t14 from 15:30 to 17:00.

続いて、沸き上げ計画部104は、ステップS143で特定したシフト継続時間の時間帯に各給湯機300の沸き上げをする沸き上げスケジュール105を作成する(ステップS144)。以上で沸き上げスケジュール作成処理は終了する。Next, the water heating planning unit 104 creates a water heating schedule 105 for heating each water heater 300 during the shift duration period specified in step S143 (step S144). This completes the water heating schedule creation process.

図5に戻り、沸き上げスケジュール作成処理が終了すると、電力管理装置200の電力調達計画部206は、ステップS12で予測した管内の需要電力量と沸き上げ計画部104が作成した沸き上げスケジュール105とに基づき、管内の翌日の一定時間毎(30分毎)の調達必要電力量を決定して、電力調達スケジュール207を作成する(ステップS15)。Returning to Figure 5, once the water heating schedule creation process is complete, the power procurement planning unit 206 of the power management device 200 determines the amount of electricity that needs to be procured at regular intervals (every 30 minutes) in the pipe the following day, based on the amount of electricity demand in the pipe predicted in step S12 and the water heating schedule 105 created by the water heating planning unit 104, and creates a power procurement schedule 207 (step S15).

そして、電力調達部208は、作成した電力調達スケジュール207に従い、調達必要電力量を電力市場または管内の発電設備600から調達するための処理(例えば、電力市場への入札)を行う(ステップS16)。Then, the power procurement department 208 performs the necessary procedures (for example, bidding on the power market) to procure the required amount of electricity from the power market or the power generation facilities 600 within its service area, in accordance with the power procurement schedule 207 that it has created (step S16).

続いて、給湯機制御部106は、ステップS14で作成された沸き上げスケジュール105をスケジュール管理ツールに登録するなどして、管内の各給湯機300の給湯制御を開始する(ステップS17)。これにより、各給湯機300では、沸き上げスケジュール105で規定された時間に湯上げの処理が行われる。Next, the water heater control unit 106 registers the heating schedule 105 created in step S14 with the schedule management tool and starts controlling the hot water supply to each water heater 300 in the pipe (step S17). As a result, each water heater 300 performs the hot water supply process at the time specified in the heating schedule 105.

続いて、電力調達スケジュール207で規定された電力調達の実行時刻になると(ステップS18;Yes)、発電制御部209は、管内の発電設備600から調達する分の調達必要電力量を少なくとも発電するように当該発電設備600を制御する(ステップS19)。Next, when the time for power procurement specified in the power procurement schedule 207 arrives (step S18; Yes), the power generation control unit 209 controls the power generation equipment 600 within the service area to generate at least the required amount of power to be procured from the power generation equipment 600 (step S19).

また、電力履歴記憶部202で随時更新される管内の消費電力量の実績値と調達必要電力量とに予め定めた基準以上の差異が生じる場合(ステップS20;Yes)、調整指令部210は、当該差異分を埋め合わせるための調整電力量を算出する(ステップS21)。Furthermore, if there is a difference exceeding a predetermined standard between the actual power consumption in the service area, which is updated periodically by the power history storage unit 202, and the amount of power required for procurement (step S20; Yes), the adjustment command unit 210 calculates the amount of adjustment power to compensate for the difference (step S21).

そして、機器管理装置100の沸き上げ調整部107は、算出した調整電力量を埋め合わせることが可能な給湯機300を特定し、特定した給湯機300を個別に制御する(ステップS22)。例えば、沸き上げ調整部107は、調整電力量に応じて、特定した沸き上げ運転中又は30分以内に沸き上げ予定のある給湯機300に、電力削減指令、電力増加指令等を適宜送信して、当該給湯機300の運転を制御する。Then, the water heating adjustment unit 107 of the equipment management device 100 identifies a water heater 300 that can compensate for the calculated adjustment power amount, and controls the identified water heater 300 individually (step S22). For example, the water heating adjustment unit 107 appropriately transmits power reduction commands, power increase commands, etc., to the identified water heater 300 that is currently heating or scheduled to heat water within 30 minutes, according to the adjustment power amount, and controls the operation of the water heater 300.

そして、24時になり日付が変わったタイミングで(ステップS23;Yes)、給湯機制御処理は終了する。また、日付が変わっていない場合は(ステップS23;No)、処理はステップS18に戻る。Then, at midnight, when the date changes (Step S23; Yes), the water heater control process ends. If the date has not changed (Step S23; No), the process returns to Step S18.

このように本開示によれば、予測された一定時間毎の電力調達価格に基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間が決定され、シフト先期間に管内の各給湯機300の沸き上げが制御されるため、電力事業者の電力調達コストをより低減することが可能となる。Thus, according to this disclosure, the period for which the power procurement cost is lowest is determined based on the predicted power procurement price at regular intervals, and the power heating of each water heater 300 in the pipe is controlled during the shift period, making it possible to further reduce the power procurement costs of the power company.

(変形例)
なお、本開示は、上記実施形態に限定されず、本開示の要旨を逸脱しない範囲での種々の変更は勿論可能である。
(Variant)
This disclosure is not limited to the embodiments described above, and various modifications are, of course, possible without departing from the gist of this disclosure.

沸き上げスケジュール作成処理のステップS142において、30分毎に昼間沸き上げ電力量を消費電力量の上限分ずつ各給湯機300に割り振っていくことによってシフト継続時間を算出したが(図10)、シフト継続時間の算出方法はこれに限定されるものではない。例えば、沸き上げ計画部104は、菅内にある複数の給湯機300を同時に沸き上げ開始した場合に、複数の給湯機300の全ての沸き上げが完了するまでに必要な時間をシフト継続時間としてもよい。In step S142 of the water heating schedule creation process, the shift duration was calculated by allocating the daytime water heating power to each water heater 300 in 30-minute increments up to the upper limit of their power consumption (Figure 10). However, the method for calculating the shift duration is not limited to this. For example, the water heating planning unit 104 may use the time required for all water heaters 300 to complete heating when multiple water heaters 300 in the pipe are started heating simultaneously as the shift duration.

上記実施の形態では、1つの沸き上げシフト先期間を決定して、当該沸き上げシフト先期間に沸き上げするように給湯機300を制御したが、決定した1つの沸き上げシフト先期間を分割するなどして複数の沸き上げシフト先期間を決定して、それぞれの沸き上げシフト先期間に沸き上げをするように給湯機300を制御してもよい。In the above embodiment, one water heating shift period was determined, and the water heater 300 was controlled to heat water during that period. However, multiple water heating shift periods may be determined by dividing the single determined water heating shift period, and the water heater 300 may be controlled to heat water during each of these periods.

例えば、機器管理装置100と電力管理装置200の機能が統合された1つの装置によって、電力需給調整システム1を構成してもよい。また、このような1つの装置が実行するプログラムを、既存のコンピュータに適用することで、当該コンピュータを本開示に係る電力需給調整システム1として機能させることも可能である。For example, the power supply and demand adjustment system 1 may be configured by a single device that integrates the functions of the equipment management device 100 and the power management device 200. Furthermore, by applying a program executed by such a single device to an existing computer, it is possible to make that computer function as the power supply and demand adjustment system 1 according to this disclosure.

このようなプログラムの配布方法は任意であり、例えば、CD-ROM(Compact Disk Read-Only Memory)、DVD(Digital Versatile Disk)、MO(Magneto Optical Disk)、メモリカード等のコンピュータ読み取り可能な記録媒体に格納して配布してもよいし、インターネット等の通信ネットワークを介して配布してもよい。The distribution method for such programs is arbitrary. For example, they may be distributed by storing them on computer-readable storage media such as CD-ROMs (Compact Disk Read-Only Memory), DVDs (Digital Versatile Disks), MOs (Magneto Optical Disks), or memory cards, or they may be distributed via communication networks such as the Internet.

本開示は、本開示の広義の精神と範囲を逸脱することなく、様々な実施形態及び変形が可能とされるものである。また、上述した実施形態は、本開示を説明するためのものであり、本開示の範囲を限定するものではない。つまり、本開示の範囲は、実施形態ではなく、請求の範囲によって示される。そして、請求の範囲内及びそれと同等の開示の意義の範囲内で施される様々な変形が、本開示の範囲内とみなされる。This disclosure allows for various embodiments and modifications without departing from the broad spirit and scope of this disclosure. Furthermore, the embodiments described above are for illustrative purposes only and do not limit the scope of this disclosure. In other words, the scope of this disclosure is indicated by the claims, not by the embodiments. And any modifications made within the scope of the claims and the equivalent significance of the disclosure are considered to be within the scope of this disclosure.

1 電力需給調整システム、100 機器管理装置、200 電力管理装置、300 給湯機、400 電力測定器、500 コントローラ、600 発電設備、700 ネットワーク、800 需要家、101 給湯機電力収集部、102 給湯機電力履歴記憶部、103 沸き上げ電力量予測部、104 沸き上げ計画部、105 沸き上げスケジュール、106 給湯機制御部、107 沸き上げ調整部、108 給湯機固有情報記憶部、110,220 制御部、120,230 記憶部、130,240 通信部、201 電力収集部、202 電力履歴記憶部、203 電力需要予測部、204 電力調達価格実績記憶部、205 電力調達価格予測部、206 電力調達計画部、207 電力調達スケジュール、208 電力調達部、209 発電制御部、210 調整司令部1 Power supply and demand adjustment system, 100 Equipment management device, 200 Power management device, 300 Water heater, 400 Power meter, 500 Controller, 600 Power generation equipment, 700 Network, 800 Consumer, 101 Water heater power collection unit, 102 Water heater power history storage unit, 103 Water heating power amount forecasting unit, 104 Water heating planning unit, 105 Water heating schedule, 106 Water heater control unit, 107 Water heating adjustment unit, 108 Water heater specific information storage unit, 110, 220 Control unit, 120, 230 Storage unit, 130, 240 Communication unit, 201 Power collection unit, 202 Power history storage unit, 203 Power demand forecasting unit, 204 Power procurement price actual storage unit, 205 Power procurement price forecasting unit, 206 Power procurement planning unit, 207 Power procurement schedule, 208 Power Procurement Department, 209 Power Generation Control Department, 210 Coordination Command

Claims (8)

管内の給湯機を備える需要家への電力需給を調整する電力需給調整システムであって、
前記給湯機の消費電力量実績から未来の沸き上げ必要電力量を予測する沸き上げ電力量予測部と、
未来の一定時間毎の電力調達価格に基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間を決定し、前記沸き上げ必要電力量の少なくとも一部を前記沸き上げシフト先期間で消費する沸き上げスケジュールを作成する沸き上げ計画部と、
前記沸き上げスケジュールに従って、前記管内の前記給湯機を制御する給湯機制御部と、
前記管内の消費電力量実績から、前記管内の未来の一定時間毎の需要電力量を予測する電力需要予測部と、
前記電力需要予測部が予測した前記需要電力量と前記沸き上げ計画部が作成した前記沸き上げスケジュールとに基づいて、前記管内の未来の一定時間毎の調達必要電力量を決定する電力調達計画部と、
を備える電力需給調整システム。
A power supply and demand adjustment system that adjusts the supply and demand of electricity to consumers equipped with hot water heaters within the pipes,
A water heating power prediction unit predicts the future amount of power required for heating water based on the actual power consumption of the aforementioned water heater,
A water heating planning unit determines the water heating shift period that minimizes electricity procurement costs based on future electricity procurement prices at regular intervals , and creates a water heating schedule that consumes at least a portion of the required water heating amount during the water heating shift period.
A water heater control unit controls the water heater in the pipe according to the aforementioned heating schedule,
A power demand forecasting unit that predicts the amount of electricity demand at regular intervals in the future within the aforementioned pipe based on the actual amount of electricity consumed within the pipe,
Based on the amount of electricity demand predicted by the electricity demand forecasting unit and the water heating schedule created by the water heating planning unit, the electricity procurement planning unit determines the amount of electricity that will need to be procured at regular intervals in the future within the service area.
A power supply and demand adjustment system equipped with the following features.
記電力調達計画部が決定した前記調達必要電力量を、電力市場または前記管内の発電設備から調達する電力調達部、
さらに備える請求項1に記載の電力需給調整システム。
The Power Procurement Department, which procures the amount of electricity needed to be procured determined by the Power Procurement Planning Department from the electricity market or from power generation facilities within its jurisdiction ,
The power supply and demand adjustment system according to claim 1, further comprising:
前記電力調達部が調達する前記調達必要電力量のうち、前記管内の前記発電設備を制御して前記調達必要電力量の少なくとも一部を生成する発電制御部、
をさらに備える請求項2に記載の電力需給調整システム。
A power generation control unit that controls the power generation equipment within the pipe to generate at least a portion of the amount of electricity to be procured by the power procurement unit,
The power supply and demand adjustment system according to claim 2, further comprising:
前記沸き上げ計画部は、複数の前記沸き上げシフト先期間を決定し、前記沸き上げ必要電力量の少なくとも一部を前記複数の沸き上げシフト先期間で消費する前記沸き上げスケジュールを作成する
請求項1から3の何れか1項に記載の電力需給調整システム。
The power supply and demand adjustment system according to any one of claims 1 to 3, wherein the heating planning unit determines a plurality of heating shift destination periods and creates a heating schedule in which at least a portion of the amount of electricity required for heating is consumed during the plurality of heating shift destination periods.
前記電力需要予測部は、給湯機の沸き上げをシフトしない場合の、未来の一定時間毎の前記需要電力量を予測する、
請求項1又は2に記載の電力需給調整システム。
The aforementioned power demand forecasting unit predicts the amount of electricity demand at regular intervals in the future, assuming that the water heater does not shift its heating function.
The power supply and demand adjustment system according to claim 1 or 2.
前記管内の一定時間毎の消費電力量実績と、前記電力調達計画部が決定した前記管内の一定時間毎の前記調達必要電力量とに予め定めた基準以上の差異が生ずる場合に、前記沸き上げ計画部が決定した前記沸き上げシフト先期間内の沸き上げ電力量のうち、現在以降の少なくともいずれかの時間帯に計画された沸き上げ電力量に対する調整電力量を算出する調整指令部と、
前記調整指令部が算出した前記調整電力量に相当する電力量を増減することが可能な給湯機を特定し、特定した給湯機に、前記給湯機制御部による制御とは異なる沸き上げ運転をするよう指令する沸き上げ調整部と、
さらに備える請求項1又は2に記載の電力需給調整システム。
When there is a difference of more than a predetermined standard between the actual power consumption amount at regular intervals within the aforementioned pipe and the amount of power procurement required at regular intervals within the aforementioned pipe as determined by the power procurement planning department, the adjustment command unit calculates an adjustment amount for the amount of power to be heated during the power heating shift period determined by the power heating planning department, for the amount of power to be heated that is planned for at least one of the time periods from the present onward.
A water heating adjustment unit identifies a water heater capable of increasing or decreasing the amount of power equivalent to the adjustment power amount calculated by the adjustment command unit, and commands the identified water heater to perform a water heating operation different from the control unit of the water heater control unit.
The power supply and demand adjustment system according to claim 1 or 2, further comprising:
管内の給湯機を備える需要家への電力需給を調整する電力需給調整方法であって、
前記給湯機の消費電力量実績から未来の沸き上げ必要電力量を予測する沸き上げ電力量予測ステップと、
未来の一定時間毎の電力調達価格に基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間を決定し、前記沸き上げ必要電力量の少なくとも一部を前記沸き上げシフト先期間で消費する沸き上げスケジュールを作成する沸き上げ計画ステップと、
前記沸き上げスケジュールに従って、前記管内の前記給湯機を制御する給湯機制御ステップと、
前記管内の消費電力量実績から、前記管内の未来の一定時間毎の需要電力量を予測する電力需要予測ステップと、
前記電力需要予測ステップで予測した前記需要電力量と前記沸き上げ計画ステップで作成した前記沸き上げスケジュールとに基づいて、前記管内の未来の一定時間毎の調達必要電力量を決定する電力調達計画ステップと、
を有する電力需給調整方法。
A power supply and demand adjustment method for adjusting the supply and demand of electricity to consumers equipped with hot water heaters within a pipe,
A step of predicting the amount of electricity needed to heat water in the future, based on the actual power consumption of the aforementioned water heater,
A heating planning step involves determining the period for which the power procurement cost is lowest based on the power procurement price at regular intervals in the future , and creating a heating schedule that consumes at least a portion of the required amount of power for heating during the period for which the power procurement cost is lowest, and
A water heater control step that controls the water heater in the pipe according to the aforementioned heating schedule,
A power demand forecasting step that predicts the amount of electricity demand at regular intervals in the future within the aforementioned pipe, based on the actual amount of electricity consumed within the pipe,
A power procurement planning step that determines the amount of electricity to be procured at regular intervals in the service area in the future, based on the amount of electricity demand predicted in the power demand forecasting step and the heating schedule created in the heating planning step,
A method for adjusting the supply and demand of electricity.
管内の給湯機を備える需要家への電力需給を調整するコンピュータを、
前記給湯機の消費電力量実績から未来の沸き上げ必要電力量を予測する沸き上げ電力量予測部、
未来の一定時間毎の電力調達価格に基づいて、最も電力調達コストが小さくなる沸き上げシフト先期間を決定し、前記沸き上げ必要電力量の少なくとも一部を前記沸き上げシフト先期間で消費する沸き上げスケジュールを作成する沸き上げ計画部、
前記沸き上げスケジュールに従って、前記管内の前記給湯機を制御する給湯機制御部、
前記管内の消費電力量実績から、前記管内の未来の一定時間毎の需要電力量を予測する電力需要予測部、
前記電力需要予測部が予測した前記需要電力量と前記沸き上げ計画部が作成した前記沸き上げスケジュールとに基づいて、前記管内の未来の一定時間毎の調達必要電力量を決定する電力調達計画部、
として機能させるプログラム。
A computer that adjusts the supply and demand of electricity to customers equipped with water heaters within the pipes,
A water heating power consumption prediction unit predicts the future amount of power required for water heating based on the actual power consumption of the aforementioned water heater.
A water heating planning unit determines the period for which the power procurement cost is lowest based on the power procurement price at regular intervals in the future , and creates a water heating schedule that consumes at least a portion of the required amount of electricity for water heating during the period for which the power procurement cost is lowest.
A water heater control unit controls the water heater in the pipe according to the aforementioned heating schedule.
A power demand forecasting unit predicts the amount of electricity demand at regular intervals in the area in the future, based on the actual amount of electricity consumed within the area.
Based on the amount of electricity demand predicted by the electricity demand forecasting unit and the water heating schedule created by the water heating planning unit, the electricity procurement planning unit determines the amount of electricity that will need to be procured at regular intervals in the future within the service area.
A program that makes it function as such.
JP2024570768A 2023-06-05 2023-06-05 Power supply and demand adjustment system, power supply and demand adjustment method, and program Active JP7830705B2 (en)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/JP2023/020789 WO2024252457A1 (en) 2023-06-05 2023-06-05 Power supply-demand adjustment system, power supply-demand adjustment method, and program

Publications (3)

Publication Number Publication Date
JPWO2024252457A1 JPWO2024252457A1 (en) 2024-12-12
JPWO2024252457A5 JPWO2024252457A5 (en) 2025-05-19
JP7830705B2 true JP7830705B2 (en) 2026-03-16

Family

ID=93795251

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2024570768A Active JP7830705B2 (en) 2023-06-05 2023-06-05 Power supply and demand adjustment system, power supply and demand adjustment method, and program

Country Status (2)

Country Link
JP (1) JP7830705B2 (en)
WO (1) WO2024252457A1 (en)

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2005135266A (en) 2003-10-31 2005-05-26 Osaka Gas Co Ltd Power trading support system
JP2011175556A (en) 2010-02-25 2011-09-08 Sony Corp Power trade server, green market management server, trading management method, and green trading management method
JP2013174408A (en) 2012-02-27 2013-09-05 Daikin Industries Ltd Heat pump type water heater
JP2015028410A (en) 2013-06-28 2015-02-12 ダイキン工業株式会社 Hot water control system
WO2017009912A1 (en) 2015-07-10 2017-01-19 三菱電機株式会社 Energy management device, energy management method, and program

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2023102129A (en) * 2022-01-11 2023-07-24 出光興産株式会社 Program, control method for heat storage type device, and information processing device

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2005135266A (en) 2003-10-31 2005-05-26 Osaka Gas Co Ltd Power trading support system
JP2011175556A (en) 2010-02-25 2011-09-08 Sony Corp Power trade server, green market management server, trading management method, and green trading management method
JP2013174408A (en) 2012-02-27 2013-09-05 Daikin Industries Ltd Heat pump type water heater
JP2015028410A (en) 2013-06-28 2015-02-12 ダイキン工業株式会社 Hot water control system
WO2017009912A1 (en) 2015-07-10 2017-01-19 三菱電機株式会社 Energy management device, energy management method, and program

Also Published As

Publication number Publication date
JPWO2024252457A1 (en) 2024-12-12
WO2024252457A1 (en) 2024-12-12

Similar Documents

Publication Publication Date Title
JP4889167B2 (en) Cogeneration system operation planning method
JP5944574B2 (en) Power generation control system and method
US8224495B2 (en) Control of power generation system having thermal energy and thermodynamic engine components
US20140222225A1 (en) Energy management system and method
Alahäivälä et al. A control framework for the utilization of heating load flexibility in a day-ahead market
WO2012158211A1 (en) Electrical thermal storage with edge-of-network tailored energy delivery systems and methods
GR20190100088A (en) METHOD FOR IMPROVED ENERGY MANAGEMENT OF AN ALMOST AUTHORITY OF A BUILDING
JP5919881B2 (en) Heat pump type water heater
CN121844460A (en) Planning delivery of energy from a networked renewable energy power plant in association with an energy attribute certificate
JP7345408B2 (en) Energy management system and energy management method
JP6985090B2 (en) Charge / discharge control device
KR102592162B1 (en) Method for controlling the exchange of energy between energy sub-systems under coordinated and harmonized conditions; control center; energy system; computer program; and storage medium
JP7285492B2 (en) Hot water supply method and control device
JP2019088151A (en) Hot-water supply device control system and hot-water supply device control method
JP7830705B2 (en) Power supply and demand adjustment system, power supply and demand adjustment method, and program
JP2021117895A5 (en)
JP5779417B2 (en) Operation management apparatus, operation management method, and operation management program
KR102669411B1 (en) Thermal and Power Network Operating Systems and Operating Methods
JP2023102129A (en) Program, control method for heat storage type device, and information processing device
WO2025158860A1 (en) Information processing system, heat pump type hot water supply system, information processing method, and program
KR20210047943A (en) Method for controlling the exchange of energy in an energy system; control center; energy system; computer program and storage medium
JP7805236B2 (en) Device control device, device control system, device control method and program
GB2638779A (en) System for assessing local generation of energy installation against grid import/export constraints
WO2025181766A1 (en) System for grouping energy installations into flexibility assets
GB2638784A (en) System for grouping energy installations into flexibility assets

Legal Events

Date Code Title Description
A521 Request for written amendment filed

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20241129

A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20241129

TRDD Decision of grant or rejection written
A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20260203

A61 First payment of annual fees (during grant procedure)

Free format text: JAPANESE INTERMEDIATE CODE: A61

Effective date: 20260304

R150 Certificate of patent or registration of utility model

Ref document number: 7830705

Country of ref document: JP

Free format text: JAPANESE INTERMEDIATE CODE: R150