JP5986945B2 - Gas and electricity supply system and method - Google Patents

Description

  The present invention relates to a method of manufacturing and supplying city gas and generating and supplying electric power. In particular, the present invention relates to a supply method capable of temporarily reducing the supply amount.

  The demand for city gas varies greatly depending on the season, day of the week, time zone, temperature, and water temperature. For example, there is a tendency for demand to increase in the evening and to decrease significantly at midnight. For this reason, gas produced at midnight with low demand is stored in a holder and sent out in the evening.

  In the technique described in Patent Document 1, the gas demand is predicted so that the gas pressure changes within a pressure range allowed for the supply line, and the gas production amount for each time unit in the gas factory. Has been set up. In addition, in the technique described in Patent Document 2, when there is a difference between the predicted gas demand and the actual demand, it is necessary to correct the gas production so that the gas production becomes the actual demand. Has been done.

JP 2004-189998 A Japanese Patent Laid-Open No. 2002-81600

  In gas supply, if the difference between the demand forecast and the actual demand, that is, the difference between the quantity that can be planned and manufactured based on the forecast and the actual demand is small, the gas holders installed in the pipeline network The high-voltage trunk serves as a buffer. However, when the construction of the gas holder is insufficient, the gas supply pressure cannot be properly maintained, and problems such as an increase in disaster risk due to an abnormality in the supply pressure and an increase in gas transportation cost may occur. As long-term demand for gas increases in the future, there is a problem that the supply pressure must be maintained with a small number of gas holders.

  In view of the above-mentioned problems, the present invention provides a supply method and system for stably supplying gas and electricity that a consumer does not feel uncomfortable with a limited holder, a limited gas production apparatus, and a power generation apparatus. It is to provide.

In order to solve the above problems, one embodiment of the present invention provides:
(1) Gas and electricity supply method and system, wherein an integrated supply and demand adjustment device that temporarily restricts gas demand when supply capacity for gas supply is temporarily insufficient with respect to gas demand It provides a gas and electricity supply system.

(2) In the gas and electricity supply system of (1) above, the gas central commanding device for commanding the production of gas is:
Gas demand forecasting means to predict gas demand from the season, day of the week, time zone, temperature, water temperature, actual usage value by gas meter, etc., gas production planning means to plan the production volume based on demand forecast, midnight with low demand, etc. Gas storage planning means for planning the amount of gas to be stored in the holder and the gas conduit, etc., and sent out in the evening when demand increases and the gas pressure in the conduit for storage;
Gas supply deficiency estimation means for estimating the gas supply deficiency from the predicted gas demand, the gas production amount, and the storage gas delivery amount is provided.

(3) In the gas and electricity supply system of (1) and (2) above, the power central commanding device for commanding power generation is:
Electricity demand forecasting means to predict electricity demand from the season, day of the week, time zone, temperature, water temperature, actual usage value by electricity meter, etc., and generator start / stop planning means to plan generator start / stop based on demand forecast And a power generation reserve amount calculation means for calculating a power generation amount that can be increased from the electricity demand prediction information and the information on the start and stop of the generator.

  (4) In the gas and electricity supply system described in (1) to (3) above, the EMS device that commands the operation and stop of the CHP that uses the gas to supply hot water and generate electricity is used for the season, day of the week, and time zone. , Power demand forecasting means in the consumer that predicts the demand for electricity from the customer from the temperature, water temperature, actual usage value by the electric meter, etc., CHP power generation monitoring means that monitors the amount of power generated by the CHP, and operation that can stop or enable the CHP And a means for calculating the required amount of external electric power when CHP is stopped, which calculates the amount of electric power that needs to be newly supplied from the outside when it is suppressed.

  (5) In the gas and electricity supply system according to (1) to (3) above, the integrated supply and demand adjustment device uses the information on the shortage of gas supply to stop the operation of the CHP or suppress the operation of the EMS device. Power demand control command means for instructing power demand suppression, and power generation of a generator that is started or started from information such as information on the amount of electric supply that needs to be supplied from the outside when the CHP is stopped or possible operation is suppressed Power generation increase command means for instructing an increase in amount.

  ADVANTAGE OF THE INVENTION According to this invention, the supply system of the gas and electricity which performs the stable supply of the gas which avoided the discomfort of a consumer irrespective of the demand of gas and the quantity of a holder can be constructed | assembled.

It is a hardware block diagram of the supply system of gas and electricity in a first embodiment. It is a lineblock diagram of the information processor of the supply system of gas and electricity in a first embodiment. It is a figure which shows the process of the supply system of gas and electricity in 1st embodiment. It is a figure which shows the gas production amount and electric power generation amount when not using the integrated supply-and-demand adjustment apparatus in 1st embodiment. It is a figure which shows the gas production amount and the electric power generation amount at the time of processing of the gas and electricity supply system in 1st embodiment. It is a hardware block diagram of the information processing apparatus of the supply system of gas and electricity in 2nd embodiment. It is a figure which shows the process of the supply system of gas and electricity in 2nd embodiment. It is a figure which shows the flow of a process of S214 in 2nd embodiment.

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

FIG. 1 is a diagram illustrating a hardware configuration of a gas and electricity supply system according to the present embodiment. A gas company manufactures gas with the gas manufacturing apparatus 104, and sends it out to the high voltage | pressure main line 21 with which the high voltage | pressure state (1 Mpa or more) was maintained. The delivery amount X (Nm ³ / h) of the gas production device 104 is controlled by the gas central command device 102. In addition, the gas manufacturing apparatus 104 communicates various data, which will be described later, to the gas central command apparatus 102 via the communication network 11.

  The high-pressure main line 21 is connected to the medium-pressure A gas conduit 22 via a governor station 105 that lowers the sent high pressure to a medium pressure A (less than 0.3 to 1 MPa) by the gas production apparatus 104. In addition, gas is supplied to the power generation device 108 through a valve station 106 installed on the high-pressure main line 21.

  Further, the pressure control station 107 includes a holder 171 and an intermediate pressure A governor 174 that connects the intermediate pressure gas conduit 22 and the intermediate pressure B gas conduit 23, typically an intermediate pressure B (less than 0.1 to 0.3 MPa). Valves 173 and 175 are provided. The holder 171 can store the gas from the intermediate pressure gas A conduit 22 and release it to the intermediate pressure B gas conduit 23 by opening and closing the valve.

  The medium pressure B gas conduit 23 is connected to the low pressure gas conduit 24 via a medium pressure B governor (district governor) 180 that lowers the medium pressure B to a low pressure (less than 0.1 MPa).

  The gas is supplied and consumed from the medium-pressure B gas conduit to the industrial consumer 111 and the condominium consumer 112. Further, the gas is supplied and consumed from the low-pressure gas conduit 24 to the commercial consumer 113 and the household consumer 114. Gas consumption is measured by gas meters (GM) 1111, 1121, 1131, 1141. Further, the gas supplied to the power generation device 108 is measured by a gas meter 1081.

  The electric power company generates power with the power generator 108 and transmits the power to the ultra high voltage system 31 with an ultra high voltage (reference voltage 77 kV). The power generation amount (kW) of the power generation device 108 is controlled by the power central command device 103. In addition, the power generation device 108 communicates various data, which will be described later, to the power central command device 103 via the communication network 12.

  The ultra high voltage system 31 is connected to the high voltage system 32 via a substation 109 that steps down the ultra high voltage to a high voltage (reference voltage 6.6 kV).

  The high-voltage system 32 is connected to the low-voltage distribution line 33 via a pole transformer 110 that steps down the high voltage to a low voltage (reference voltage 200 V).

  Electricity is sent from the high-voltage system 32 to the industrial consumer 111 and the condominium consumer 112, and is also consumed from the low-voltage distribution line 33 to the commercial consumer 113 and the household consumer 114. The amount of electricity consumed by each consumer from the high-voltage system 32 and the low-voltage distribution line 33 (the amount of power received) is measured by electric meters (EM) 1112, 1122, 1132, and 1142.

  The industrial customers 111, the condominium customers 112, the commercial customers 113, and the household customers 114 are EMS (Energy Management System) 1114, 1124, 1134, and 1144, respectively. (Combined Heat Power, also called a combined heat and power system) 1113, 1123, 1133, 1143 are controlled. The CHPs 1113, 1123, 1133, and 1143 generate electricity and heat simultaneously with the supplied gas. The generated electricity is supplied to electric equipment (not shown) in the consumer. On the other hand, the generated heat is used for heating or hot water supply in a customer, heating or hot water supply by driving a heat pump (not shown) by heat, or cooling or water supply by driving an adsorption refrigeration machine (not shown) by heat. Is done.

  The energy aggregator uses the integrated supply and demand adjustment device 101 to supply the gas production amount, the power generation amount, and the gas consumption at the customer to each of the gas central command device 102, the power central command device 103, and the EMSs 1114, 1124, 1134, and 1144. Directs adjustments for quantity and generation of electricity and heat. In addition, the gas central command device 102, the power central command device 103, and the EMSs 1114, 1124, 1134, and 1144 communicate various data, which will be described later, via the common communication network 1 to the integrated supply and demand adjustment device 101.

  The power transmission manager uses the consignment management device 200 to send information (actual amount and scheduled amount) on the total amount of power received by the energy aggregator from the integrated supply and demand adjustment device 101 of the energy aggregator to the common communication network 1. Through the common communication network 1 from the power central command device 103 of the electric power company through the common communication network 1, and whether the total amount of power received and the amount of power generation are the same amount, Confirmation is made in each time zone (a time zone is a time zone in increments of 30 minutes, for example, and there is a time segment from 12:00 to 12:30). If the amount is not the same, an imbalance adjustment fee according to the difference between the total amount of power received and the amount of power generation is calculated. The above power transmission manager charges an imbalance adjustment fee to the electric utility.

  FIG. 2 is a diagram illustrating a hardware configuration of the information processing apparatus of the gas and electricity supply system. This is composed of an integrated supply and demand adjustment device 101, a gas central command device 102, a power central command device 103, and EMSs 1141 to 1144, which are connected by a common communication network 1 or the like.

  The integrated supply and demand adjustment apparatus 101 includes a CPU 1011, a main memory 1012, an input / output interface 1013, a network interface 1014, and a storage device 1015, which are connected by a bus or the like.

  The storage device 1015 is configured by an HDD or the like, and stores programs that realize the functions of the gas demand suppression command unit 211 and the power generation increase command unit 212.

  The gas central command device 102 includes a CPU 1021, a main memory 1022, an input / output interface 1023, a network interface 1024, and a storage device 1025, which are connected by a bus.

  The storage device 1025 is configured by an HDD or the like, and stores programs that realize the functions of the gas demand prediction unit 221, the gas production planning unit 222, the gas storage planning unit 223, and the gas supply shortage estimation unit 224.

  The power central commanding device 103 includes a CPU 1031, a main memory 1032, an input / output interface 1033, a network interface 1034, and a storage device 1035, which are connected by a bus.

  The storage device 1035 is configured by an HDD or the like, and stores programs that realize the functions of the electricity demand prediction unit 231, the generator stop planning unit 232, the power generation reserve amount calculation unit 233, and the power generation increase control command unit 234.

  The EMS 1114 includes a CPU 1441, a main memory 1442, an input / output interface 1443, a network interface 1444, and a storage device 1445, which are connected by a bus. The EMS 1121, 1134, and 1144 have the same configuration as the EMS 1114.

  The storage device 1445 is configured by a flash memory, an HDD, or the like, and realizes the functions of an in-customer electricity demand prediction unit 241, a CHP power generation monitoring unit 242, an external electricity supply required amount calculation unit 243, and a CHP gas use suppression control command unit 244. The program is stored.

  The consignment management device 200 (not shown) includes a CPU, a main memory, an input / output interface, a communication unit network interface, and a storage device, which are connected by a bus or the like. The storage device stores a program that realizes the function of the imbalance fee calculation unit 251.

  FIG. 3 shows the processing of the gas and electricity supply system. This figure is a sequence diagram showing processing of the integrated supply and demand adjustment device 101, the gas central command device 102, the power central command device 103, the EMS 1141, and the consignment management device 200.

  The gas central command device 102 predicts the gas demand at each time in a predetermined period (for example, 48 hours in the future) (S221), creates a gas production plan (S221), and stores it in the holder at midnight and stores the maximum in the morning and evening. A storage plan for the gas released at the time of demand is created (S223). In particular, the gas central command device 102 determines the high-pressure trunk line and the gas at each time from the predicted amount and actual amount of gas demand at each time, the gas production amount at each time, the gas discharge amount, and the storage amount. Find the supply pressure of the conduit by the Hardy Cross method. Further, the gas central command device 102 calculates the amount of gas that is insufficient to maintain the supply pressure and transmits it to the integrated supply and demand adjustment device 101 (S224).

  The power central commanding device 103 predicts electricity demand at each time in a predetermined period (for example, 48 hours in the future) (S231), and creates a power generation plan by starting or stopping the generator (S232). Next, the power central commanding device 103 determines at each time from the predicted amount and actual amount of electricity demand at each time and the power generation amount at each time (synonymous with the planned power generation possible amount). The power generation reserve for increasing power generation is obtained and transmitted to the integrated supply and demand adjustment apparatus 101 (S233).

  In addition, when receiving a power generation increase command transmission (S212) from the integrated supply and demand adjustment device 101, the power central command device 103 instructs the power generation device 108 to perform control for adjusting the power generation amount (power generation). Plan correction command) is performed (S234). Information on the power generation amount comprising the plan value and the plan correction value of the power generation amount achieved at each time and the actual power generation value obtained from the power generation device 108 in accordance with the above-mentioned plan related to power generation and the control command related to the adjustment of the power generation amount. Is transmitted to the consignment management apparatus 200 (S235).

  The EMS 1114 transmits information on the actual gas use amount obtained from the gas meter 1111 to the gas central command device 102 (S245), and the same 30 minutes on the same day of the past N weeks (for example, N = 4) obtained from the electric meter 1112. By calculating from the average value of the amount of power received from the outside in the belt (for example, the low-voltage distribution line 33), the electric demand at the consumer 111 is predicted (at this time by the CHP in the same period and the same time period in the past) (A correction for adding the power generation amount is also performed) (S241).

  Next, EMS 1114 is a demand for heat in the customer (heating in the customer, hot water supply, heating or hot water by driving the heat pump by heat, or cooling or water supply by driving the adsorption refrigerator by heat) ) Heat demand in the same 30-minute time zone of the same day of the past N weeks (for example, N = 4) (especially, preferably, the operation time zone of CHP is shifted from the buffer for the heat demand in the customer such as a hot water tank) CHP power generation amount generated by the CHP operation planned to generate heat that satisfies the heat demand is calculated (S242).

  Next, when the EMS 1114 stops the CHP 1113 due to a heat demand shift or suppresses the operation within a possible range, the EMS 1114 newly calculates the amount of electric supply that needs to be supplied from the outside, and transmits it to the integrated supply and demand adjustment apparatus 101. (S243). In addition, when a gas demand suppression command transmission (S211) is received from the integrated supply and demand adjustment apparatus 101, the CHP 1113 is commanded to perform gas use suppression control for stopping or suppressing the operation of the CHP (S244).

  Note that the EMS 1124, 1134, and 1144 perform the same processing as the EMS 1114. The integrated supply and demand adjustment apparatus 101 receives the information on the shortage of gas supply at each time (S224) from the gas central command apparatus 102, and transmits the information on the reserve amount of power generation at each time from the power central command apparatus 103 (S233). If the EMS 1144 (and 1114, 1124, 1134 (not shown)) receives information on the required amount of external electricity supply (S43) by stopping the CHP or suppressing the operation (S43), A gas demand suppression command is transmitted to the EMSs 1114, 1124, 1134, and 1144 within a range in which the power generation reserve amount exceeds the external electric supply that increases due to operation suppression (S211).

  Furthermore, the integrated supply and demand adjustment apparatus 101 transmits a command to increase the amount of power generation by the same amount as the external electric supply that is increased by stopping or suppressing the operation of the CHP to the central power command apparatus 103 (S212). In addition, the integrated supply and demand adjustment apparatus 101 consigns and manages information related to the sum of the amount of power received from the outside (the actual amount and the planned amount (planned amount) by the electric meters 1112, 1122, 1132, and 1422) regarding the electricity of the customer. It transmits to the apparatus 200 (S213).

  The consignment management device 200 receives information (the actual amount and the scheduled amount) (S213, S235) related to the sum of the amount of power received by the customer, is notified of the information regarding the power generation amount from the power central command device 103, and receives the amount of power received. Whether the total amount and the power generation amount are the same amount is confirmed in each time zone (a time zone is a time zone in increments of 30 minutes, for example, and there is a time segment from 12:00 to 12:30). When the amount is not the same, the consignment management device 200 determines the imbalance adjustment fee according to the difference between the total amount of power received and the amount of power generation (specifically, the difference amount kW in the time zone (the unit kW is the average unit for 30 minutes (kWh / H) is calculated by multiplying a predetermined unit price (for example, 40 yen / kW)). Based on the calculated imbalance adjustment fee, the power transmission manager charges the electric utility with the imbalance adjustment fee. In addition, the consignment management apparatus 200 can also automatically transmit the charge of the imbalance adjustment fee to the system of the electric power company.

  Next, the effect of improving the stability of the gas and electricity supply when the gas and electricity supply system of this embodiment is processed will be described with reference to FIGS. 4A and 4B.

FIG. 4A illustrates a gas production amount X (Nm ³ / h) and a power generation amount Y (kW) when the integrated supply and demand adjustment device on a certain day is not used. On this day, demand exceeding the production limit of the gas production apparatus 104 is generated, and the gas supply amount is insufficient from 16:00 to 18:00 even when the release of gas from the holder 171 is combined. It occurs in the time zone. It can be seen that this causes a drop in supply pressure that impairs the comfort of consumers.

FIG. 4B shows X (Nm ³ / h) and power generation amount Y (kW) under the same day conditions as shown in FIG. 4A when the gas and electricity supply system of this embodiment is processed. It is shown. By suppressing the operation of the CHP of the customer, the gas demand is satisfied by the gas production within the limit range of the gas production, and the power generation supplementing the power generation in the customer by the CHP is generated by the power generation device 108 and supplied to the customer. ing.

  This phenomenon is a physical characteristic that the energy efficiency of the power generation device 108, which is a large generator, exceeds the energy efficiency of the CHP, which is a small generator installed by a consumer, with the efficiency of power generation only excluding heat. Is due to. This prevents consumers from compromising both the comfort of gas consumption and the comfort of electricity consumption, and the stability of gas and electricity supply (supplying only to meet actual demand) Is referred to here as stable).

  Next, a second embodiment of the present invention will be described. In the present embodiment, the sum of the gas fee and the electricity fee paid by the consumer to each of the gas company and the electric company is not performed when the gas and electricity supply system of the present invention is processed. Compared to the above, there is a feature that charges a low fee. Thereby, the problem that the consumer does not perform the suppression action of the gas demand for economic reasons is solved.

  FIG. 5 shows the hardware configuration of the information processing apparatus of the gas and electricity supply system according to the second embodiment of the present invention. In addition to the hardware configuration in the first embodiment of the present invention shown in FIG. 2, an integrated fee billing unit 214, an external electric supply and gas suppression result information transmission unit 246 are added.

  FIG. 6 shows the processing of the gas and electricity supply system. Here, the processing shown in FIG. 3 is added with processing S246 for transmission of external electric supply and gas supply performance information and processing for integrated billing S214 of the integrated supply and demand adjustment apparatus. Only differences from FIG. 3 will be described below. In S246, the EMS 1114 instructs the CHP to suppress the use of CHP gas, and as a result, records the amount of gas that can be suppressed by stopping the CHP, and records the amount of external electricity supplied to the CHP 1113, 1123, 1133. , 1143 operation information and the measurement data of the gas meters 1111, 1121, 1131, 1141 and the electric meters 1112, 1122, 1132, 1142 are calculated below and sent to the integrated supply and demand adjustment apparatus. Similar to FIG. 3, EMS 1124, 1134, and 1144 are the same processing as S246.

In the integrated billing process S214, the integrated supply and demand adjustment apparatus 101 first reduces the consumer gas charge by multiplying the suppressed gas amount by the unit sales price of gas (for example, 140 yen / m ³ ), and the increased external power consumption. Is calculated by multiplying the unit price of electricity by a unit price of electricity sales (for example, 20 yen / kWh). Subsequently, when the amount of increase in the customer's electricity rate exceeds the amount of reduction in the customer's gas rate, the corresponding amount is set as the amount of the request for refund to the customer, and the billing system is used as the gas server's rate server (not shown). ).

  FIG. 7 shows the detailed processing flow of S214. The integrated supply and demand adjustment apparatus 101 requests each EMS for external power supply and gas suppression performance information. Each EMS 1114, 1124, 1124, 1144 transmits the external electricity supply and gas suppression performance information to the integrated supply and demand adjustment apparatus 101. The integrated supply and demand adjustment apparatus 101 stores the performance information from each EMS in the storage device 1015 (S701).

  Next, the integrated supply and demand adjustment apparatus 101 calculates a consumer gas charge reduction amount by multiplying the suppressed gas amount by the gas sales unit price based on the collected gas suppression performance information (S702). Similarly, based on the collected power increase information, the integrated supply and demand adjustment apparatus 101 multiplies the increased power by the sales unit price of power to calculate a low increase in consumer power charges (S703).

  Next, the integrated supply and demand adjustment apparatus 101 calculates whether or not the amount of increase in the customer power rate exceeds the amount of reduction in the customer gas rate (S704), and the difference is used as the amount of the refund request to the customer (S705). ).

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  Each of the above-described configurations, functions, processing units, processing means, and the like may be realized by hardware by designing a part or all of them with, for example, an integrated circuit. Information such as programs, tables, and files for realizing each function can be stored in a recording device such as a memory, a hard disk, an SSD (Solid State Drive), or a recording medium such as an IC card, an SD card, or a DVD.

  Further, the control lines and information lines indicate what is considered necessary for the explanation, and not all the control lines and information lines on the product are necessarily shown.

1: Common communication network 11, 12: Communication network 21: High pressure trunk line 22: Medium pressure A gas conduit 23: Medium pressure B gas conduit 24: Low pressure gas conduit 31: Super high pressure system 32: High pressure system 33: Low pressure distribution line 41 42, 43, 44: Customer communication network 101: Integrated supply and demand adjustment device 102: Gas central command device 103: Electric power central command device 104: Gas production device:
105: Governor station 106: Valve station 107: Suppression station 108: Power generation device 109: Substation 110: Pillar transformer 111: Industrial consumer 112: Condominium consumer 113: Commercial consumer 114: Household consumer 1111, 1121, 1131, 1141: Gas meter 1112, 1122, 1132, 1142: Electric meter 1113, 1123, 1133, 1143: CHP (electric heat and power supply device)
1114, 1123, 1134, 1144: EMS
151, 161, 171: Dispersion building 152, 174, 180: Governor 153, 162, 173, 175: Valve 171: Holder 1111, 1121, 1131, 1141: Gas meter 1112, 1122, 1132, 1142: Electric meter

Claims (12)

A gas and electricity supply system,
With consumers who consume gas and electricity,
A gas central command device for calculating the gas supply shortage;
A power central command device for calculating information on the reserve amount of power generation;
Connected to the consumer, the gas central command device, the power central command device, and based on the supply shortage amount sent from the gas central command device and the power generation reserve amount sent from the power central command device If the supply capacity for gas supply temporarily falls short of the gas demand,
An integrated supply and demand adjustment device for temporarily limiting the gas demand of the consumer;
Having gas and electricity supply system. The gas central command device is a gas demand forecasting means for forecasting gas demand from the season, day of the week, time zone, temperature, water temperature, actual use value by a gas meter,
Gas production planning means for planning production based on demand forecast;
A gas storage planning means for planning the storage amount of gas to be manufactured and stored in a holder and a gas conduit, etc. during a time period when demand is low, and to be sent out during a time period when demand increases and the gas pressure in the conduit for storage;
A gas supply shortage estimation means for estimating the gas supply shortage from the predicted gas demand, the gas production amount and the gas delivery amount of storage;
The gas and electricity supply system according to claim 1. The power central command device is a power demand forecasting means for forecasting the demand for electricity from the season, day of the week, time zone, temperature, water temperature, actual use value by an electric meter,
Generator start / stop planning means for planning generator start / stop based on demand forecast;
Power generation reserve amount calculation means for calculating the amount of power generation that can be increased from the electricity demand prediction information and the information on the start and stop of the generator,
The gas and electricity supply system according to claim 1, comprising: The consumer includes CHP for hot water supply and power generation,
An EMS device connected to the CHP and commanding the operation and stop of the CHP,
The EMS device includes a consumer's power demand forecasting means for forecasting a consumer's electricity demand from a season, a day of the week, a time zone, an air temperature, a water temperature, an actual usage value by an electric meter,
CHP power generation monitoring means for monitoring the power generation amount by the CHP;
An external electric supply required amount calculation means at the time of CHP stop, which calculates an electric supply amount that requires a new external electric supply when the CHP is stopped or possible operation suppression is performed;
The gas and electricity supply system according to claim 1. The integrated supply and demand adjustment device is:
From the information of insufficient amount of the gas supply, the gas demand suppression command means for instructing to reduce the demand for gas C HP stopping or driving suppressed to E MS apparatus,
Power generation increase command means for instructing to start the generator or increase the power generation amount of the activated generator from the information of the electric supply amount that needs to be supplied from the outside when the CHP is stopped or possible operation is suppressed;
The gas and electricity supply system according to claim 1. The integrated supply and demand adjustment device is:
The amount of combined gas and electricity charges from electricity plus incremental use of electricity generated by temporarily restricting gas use, and gas use reduced by temporarily restricting gas use;
Compare the amount of gas combined with the use of gas and electricity generated without the temporary suppression of gas use and the use of gas and electricity,
The gas and electricity supply system according to claim 1, wherein when the amount of the former combined fee exceeds the amount of the latter combined fee, the amount of the combined fee is changed to the latter value. A method for supplying gas and electricity,
Gas and electricity are consumed by consumers,
The gas central command device calculates the shortage of gas supply,
The power central command device calculates the power reserve information,
An integrated supply and demand adjustment device connected to the consumer, the power central command device, and the gas central command device receives an insufficient supply amount sent from the gas central command device,
Receiving the power generation reserve amount sent from the power central command device,
A gas and electricity supply method for temporarily limiting the gas demand of the consumer when the supply capacity related to gas supply is temporarily insufficient with respect to the gas demand. The gas central command device predicts the demand for gas from the season, day of the week, time zone, temperature, water temperature, actual use value by gas meter,
Plan production based on demand forecasts,
Plan the gas storage capacity and the gas pressure in the pipe for storage, which are manufactured during the low demand period, stored in the holder and the gas pipe, etc.
The gas and electricity supply method according to claim 7, wherein an insufficient gas supply amount is estimated from the predicted gas demand, the gas production amount, and the stored gas delivery amount. The power central command device predicts the demand for electricity from the season, day of the week, time zone, temperature, water temperature, actual use value by electric meter,
Plan the start and stop of the generator based on the demand forecast,
The gas and electricity supply method according to claim 7, wherein the power generation amount that can be increased is calculated from the electricity demand prediction information and the information on starting and stopping of the generator. In the consumer, the EMS device that commands the operation and stop of the CHP for hot water supply and power generation predicts the consumer's electricity demand from the season, day of the week, time zone, temperature, water temperature, actual use value by electric meter,
Monitoring the amount of power generated by the CHP;
The gas and electricity supply method according to claim 7, wherein when the CHP is stopped or possible operation suppression is performed, an electricity supply amount that requires a new external electricity supply is calculated. The integrated supply and demand adjustment device is:
The lack of information of the gas supply, and instructing to reduce the demand for gas C HP stopping or operation inhibition against E MS apparatus,
The gas and electricity according to claim 7, wherein the start of the generator or an increase in the amount of power generation of the activated generator is instructed from information on an electric supply amount that needs to be supplied from outside when the CHP is stopped or possible operation is suppressed. Supply method. The integrated supply and demand adjustment device is:
The amount of combined gas and electricity charges from electricity plus incremental use of electricity generated by temporarily restricting gas use, and gas use reduced by temporarily restricting gas use;
Compare the amount of gas combined with the use of gas and electricity generated without the temporary suppression of gas use and the use of gas and electricity,
8. The gas and electricity supply method according to claim 7, wherein when the amount of the former combined fee exceeds the amount of the latter combined fee, the amount of the combined fee is changed to the latter value.

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