JP5064858B2 - Distributed energy community system - Google Patents

Description

  The present invention is a distributed energy system in which a plurality of communities each including at least one of an energy consuming device and an energy supplying device are connected to enable energy supply from the energy supplying device to the energy consuming device between the plurality of communities. Regarding the community system.

  Conventionally, a distributed energy community in which a plurality of communities each including at least one of an energy consuming device and an energy supplying device are connected to each other to enable energy supply from the energy supplying device to the energy consuming device. A system has been proposed. For example, a distributed energy community system described in Patent Literature 1 includes a plurality of communities including at least one energy consuming device and an energy supply device, and a center device for controlling interchange of energy between the plurality of communities. It is prepared for. The control monitoring device provided in the center device includes a database, collects data related to each community, accumulates the data in the database, and performs operation management of the energy supply device in each community based on this database.

By constructing such a distributed energy community system, the energy generated by the energy supply device of a certain community can be effectively utilized in other communities. In other words, energy surplus or energy shortage tends to occur only in one community, but energy surplus or energy shortage as a whole of multiple communities can be achieved by linking energy consumption devices and energy supply devices in multiple communities. Can be suppressed. As a result, targets such as energy saving, cost saving, and low CO ₂ emission, which were difficult to achieve with only one community, can be achieved.

JP 2002-44870 A

  The control and monitoring device provided in the center device described in Patent Literature 1 communicates with a computer functioning as a server, software for performing optimization calculation for energy interchange, and energy consumption devices and energy supply devices provided in each community. It is necessary to have such communication means. Therefore, there exists a problem that the cost for constructing a distributed energy community system increases. Further, when the center device fails, there is a problem that energy interchange between the plurality of communities becomes impossible.

The present invention has been made in view of the above problems, and its purpose is a distributed type capable of achieving the goals of energy saving, cost saving, and low CO ₂ emission of each community without providing a special center device. The point is to provide an energy community system.

In order to achieve the above object, the distributed energy community system according to the present invention is characterized in that a plurality of communities each including at least one of an energy consuming device and an energy supplying device are configured to supply the energy among the plurality of communities. A decentralized energy community system connected to enable energy supply from a device to the energy consuming device,
Each community has a community management device that manages the energy consuming device and the energy supply device,
The community management device provided in the community including the energy supply device includes communication means for communicating information with other communities, information on the predicted energy load of the energy consuming device in each community, and the community in each community. based on the information about the energy delivery characteristics of the energy supply system, the operation plan generating means for generating the operation plan of the energy supply apparatus in the operation plan and other communities of the energy supply device in its community, its community Operation control means for operating the energy supply device in accordance with the operation plan,
The community management device provided in the community including the energy consuming device has at least the communication unit and a predicted energy load deriving unit that derives a predicted energy load of the energy consuming device in its community,
Communities, including the energy supply device is connected to a plurality,
The community management device provided in the community including the energy supply device is:
Information about the predicted energy load of the energy consuming device in the other community and information about the energy supply characteristics of the energy supply device in the other community are obtained from the other community by the communication means. in that it is configured.
The community in this application means the management object unit (management unit) used as one management object which performs energy consumption, energy supply, or both.

According to the above characteristic configuration, each community is provided with a community management device. Therefore, even if a special center device for creating an operation plan is not provided, the community including the energy supply device is provided in each community. An operation plan for the energy supply device is created. Therefore, it is not necessary to provide a center device separately from each community and introduce an arithmetic processing device, an application, a communication function, and the like there. Therefore, the cost for constructing a decentralized energy community system can be reduced.
In addition, since energy interchange can be performed between the energy supply device and the energy consumption device in each community, each community can contribute to the achievement of targets such as energy saving, cost saving, and low CO ₂ emission. In addition, even a community that does not have an energy supply device but only an energy consumption device consumes surplus energy generated in other communities, so that it can save energy and save energy as a member of multiple communities. It can contribute to the achievement of targets such as cost and low CO ₂ emissions.
Accordingly, it is possible to provide a distributed energy community system that can achieve the goals of energy saving, cost saving, and low CO ₂ emission of each community without providing a special center device.

  Another characteristic configuration of the distributed energy community system according to the present invention is that the community management device provided in a community including the energy supply device includes information on energy supply characteristics of the energy supply device managed by the community management device. The apparatus characteristic storage means is provided for updating and storing the actual operation results. Here, the energy supply characteristics include the form of energy that can be supplied by the energy supply device (electricity, hot water, warm air, cold air, etc.), the instantaneous value of the energy supply amount, the total amount, and the energy supply efficiency.

  According to the above characteristic configuration, since the information on the energy supply characteristics of the energy supply device in each community can be stored by the device characteristic storage means, the device characteristics that change over time according to the actual operation result are sequentially stored. be able to.

Another characteristic configuration of the distributed energy community system according to the present invention is that the community management device provided in the community including the energy supply device determines a community group including a plurality of communities among all the communities. Having means,
The operation plan creation means is to create an operation plan of the energy supply device in the community group to which its own community belongs.

According to the above feature configuration, community groups can be set freely, so even if there is a community that cannot communicate due to communication troubles, etc., a community group consisting of a plurality of communities excluding that community is constructed, and those communities Can achieve energy savings, cost savings, and low CO ₂ emission goals through energy interchange.
Moreover, the operation plan creation means of each community can reduce the number of communities for which the operation plan is to be created to an appropriate number, and as a result, it is possible to prevent an increase in the time required to create the operation plan and the calculation load.

Another characteristic configuration of the distributed energy community system according to the present invention is that the community management device provided in the community including the energy supply device determines a parent community among a plurality of communities constituting the community group. Having a determination means;
The said operation plan preparation means provided in the said parent community exists in the point which produces the operation plan of the said energy supply apparatus in the said community group to which own community belongs.

  According to the said characteristic structure, the energy supply apparatus of each community can be drive | operated with the driving | running plan produced in the parent community of the some community.

Another characteristic configuration of the distributed energy community system according to the present invention is that the community management device provided in the community including the energy supply device is created by the operation plan creation means and each operation provided by the communication means. An operation plan determining means for determining an operation plan for execution from the plan;
The operation control means is to operate an energy supply device in its own community according to the execution operation plan.

According to the above characteristic configuration, an appropriate operation plan can be determined from among operation plans created in each community, so that the reliability of the operation plan is ensured and energy saving, cost saving, low CO ₂ emission, etc. are ensured. You can achieve your goals.

  Another characteristic configuration of the distributed energy community system according to the present invention is that the energy supply device is a combined heat and power supply device, a hot water supply device, a heating hot water supply device, or a heat pump device that supplies heat energy and electric energy together. It is in the point which is at least one of the energy storage device which is an energy generator and a power storage device or a heat storage device.

  According to the above characteristic configuration, energy generated by the combined heat and power supply device, hot water supply device, heating hot water supply device, or heat pump device can be accommodated in the energy consuming device, and the energy accumulated in the power storage device or the heat storage device can be used. Flexible to energy consuming equipment.

  Another characteristic configuration of the distributed energy community system according to the present invention is that the communication means provided in each community are connected to each other by a power line.

  According to the above characteristic configuration, communication between each community can be performed via the power line, so that the cost for installing a separate communication line can be reduced.

<First Embodiment>
The distributed energy community system according to the first embodiment will be described below with reference to the drawings. FIG. 1 is a block diagram illustrating a schematic configuration of a distributed energy community system.
As shown in FIG. 1, the distributed energy community system of the present invention is configured such that a plurality of communities 40 including at least one of an energy consuming device 20 and an energy supply device 30 are connected by a power line 1 so that energy can be interchanged. Configured. However, the distributed energy community system is configured by connecting at least one community 40 including the energy supply device 30. The power line 1 may be connected to a commercial power system, or may be provided independently of the commercial power system. In this embodiment, the communities 40a, 40c, 40d, 40e, 40f, and 40g are energy consumption devices 20 (20a, 20c, 20d, 20e, 20f, 20g) and energy supply devices 30 (30a, 30c, 30d, 30e, 30f, 30g). The community 40b includes only the energy supply device 30b. The community 40h includes only the energy consuming device 20h. Moreover, each community 40 (40a-40h) is provided with the community management apparatus 10 (10a-10h). The community in this application means the management object unit (management unit) used as one management object which performs energy consumption, energy supply, or both.

  FIG. 2 is a functional block diagram for explaining a specific example of the distributed energy community system shown in FIG. Below, the structure of the energy consumption apparatus 20 and the energy supply apparatus 30 in each community 40 is demonstrated.

In this embodiment, the energy consuming apparatus 20 is various electric energy consuming apparatuses 20E that consume electric power or various thermal energy consuming apparatuses 20T that consume heat in the form of heating or hot water.
The energy supply device 30 includes an energy generation device 30G that is a combined heat and power supply device, a hot water supply device, a heating hot water supply device, or a heat pump device that supplies heat energy and electric energy together, and a power storage device or heat storage device. It is at least one of energy storage devices 30S which is a device.

In the community 40a, the power consuming device 22 (20E) and the heat consuming device 23 (20T) function as the energy consuming device 20. Also, the energy generating device 30G that functions as the energy supplying device 30 is constituted by a hot water supply device 31 that generates heat.
The power consuming device 22 consumes power supplied via the power line 1 from another community 40, a commercial power system, or the like. The hot water supply device 31 consumes gas or electricity to generate hot water. The heat consuming device 23 is a currant or shower that consumes hot water (heat) generated by the hot water supply device 31. Therefore, the utility measuring means 21 of the community 40a measures the amount of power and heat used by the power consuming device 22 and the heat consuming device 23.

In the community 40b, the energy storage device (power storage device) 30S configured by the storage battery 36 functions as the energy supply device 30.
The storage battery 36 can perform a charging operation for charging power from the power line 1 and a discharging operation for discharging power to the power line 1.

In the community 40c, the power consuming device 22 (20E) and the heat consuming device 23 (20T) function as the energy consuming device 20. Also, the energy supply device 30 that functions as the energy supply device 30 is an energy generation device 30G configured by a combined heat and power supply device 32 and an energy storage device 30S configured by a hot water storage device (an example of a heat storage device) 33.
The power consuming device 22 consumes the power generated by the combined heat and power supply device 32 provided in its own community 40c and the power supplied from the other community 40 or the commercial power system via the power line 1. The combined heat and power device 32 consumes gas and generates heat and electricity together, or consumes fuel such as hydrocarbon gas, hydrogen gas, alcohol, kerosene, etc. to generate heat and electricity. A fuel cell type that also generates The hot water storage device 33 accumulates the heat generated by the combined heat and power supply device 32 in the form of hot water. The heat consuming device 23 is a currant or shower used for consuming heat generated by the combined heat and power supply device 32 or heat accumulated in the hot water storage device 33.
Therefore, the utility measuring means 21 of the community 40c measures the amount of power and heat used by the power consuming device 22 and the heat consuming device 23.

In the community 40d, the heat consuming device 23 (20T) functions as the energy consuming device 20. Further, the energy supply device 30 that functions as the energy supply device 30 is an energy generation device 30G configured by the combined heat and power supply device 32 and an energy storage device 30S configured by a flywheel (an example of a power storage device) 37.
Specific examples of the combined heat and power supply device 32 and the heat consuming device 23 are the same as described above. The flywheel 37 is a device (power storage device) that converts electrical energy generated by the combined heat and power supply device 32 into kinetic energy, accumulates it, reconverts the kinetic energy into electrical energy, and supplies it to the outside.
Therefore, the utility measuring means 21 of the community 40d measures the amount of heat used by the heat consuming device 23.

In the community 40e, the power consuming device 22 (20E) and the heat consuming device 23 (20T) function as the energy consuming device 20. Further, the energy generator 30 </ b> G configured by the heating hot water supply device 34 functions as the energy supply device 30.
The power consuming device 22 consumes power supplied via the power line 1 from another community 40 or a commercial power system. The heating and hot water supply device 34 is a device that consumes gas and electricity to generate high-temperature heat (hot water or the like) that can be used for heating and hot water supply. The heat consuming device 23 is a hot water heating device, a currant, a shower, or the like used for consuming heat generated by the heating and hot water supply device 34.
Therefore, the utility measuring means 21 of the community 40e measures the amount of power and heat used by the power consuming device 22 and the heat consuming device 23.

In the community 40f, the power consuming device 22 (20E) functions as the energy consuming device 20. Further, the energy storage device (power storage device) 30 </ b> S configured by the capacitor 38 functions as the energy supply device 30.
The power consuming device 22 consumes power supplied via the power line 1 from another community 40 or a commercial power system. The capacitor 38 can perform a charging operation for charging power from the power line 1 and a discharging operation for discharging power to the power line 1.
Therefore, the utility measuring means 21 of the community 40f measures the amount of power used by the power consuming device 22.

In the community 40g, the power consuming device 22 (20E) and the heat consuming device 23 (20T) function as the energy consuming device 20. The energy supply device 30 functions as an energy generation device 30G configured by the heat pump device 35 and an energy storage device (heat storage device) 30S configured by the hot water storage device 33.
The power consuming device 22 consumes power supplied via the power line 1 from another community 40 or a commercial power system. The heat pump device 35 is a device that heats and cools air in the process of compressing and expanding the refrigerant by using electric energy or power obtained by a gas engine or the like. The hot water storage device 33 accumulates the heat generated by the heat pump device 35 in the form of hot water. The heat consuming device 23 is used for consuming air generated by the heat pump device 35, an air conditioner using the warm air, heat generated by the heat pump device 35, or heat accumulated in the hot water storage device 33. They are currants and showers.
Therefore, the utility measuring means 21 of the community 40g measures the amount of power and heat used by the power consuming device 22 and the heat consuming device 23.

In the community 40h, the power consuming device 22 (20E) functions as the energy consuming device 20.
The power consuming device 22 consumes power supplied via the power line 1 from another community 40 or a commercial power system.
Therefore, the utility measuring means 21 of the community 40 h measures the amount of power used by the power consuming device 22.

Next, the configuration of the community management device 10 in each community 40 will be described.
As described above, the communities 40a, 40c, 40d, 40e, 40f, and 40g are connected to the energy consuming device 20 (20a, 20c, 20d, 20e, 20f, and 20g) and the energy supply device 30 (30a, 30c, 30d, 30e, and 30f). 30g). Therefore, the community management devices 10a, 10c, 10d, 10e, 10f, and 10g include the communication unit 11, the predicted energy load deriving unit 12, the operation plan creating unit 13, and the operation control unit 14. In this embodiment, each means with which the community management apparatus 10 is provided is incorporated in either the energy consuming apparatus 20 or the energy supply apparatus 30 together or dispersedly.
For example, an energy supply device that creates an operation plan based on a predicted energy load and operates according to the operation plan is realized. That is, such an energy supply apparatus includes a predicted energy load deriving unit 12, an operation plan creating unit 13, and an operation control unit 14. Therefore, if such an energy supply device is provided in the community, the existing predicted energy load deriving unit 12, the operation plan creating unit 13, and the operation control unit 14 can be used.

  The communication means 11 is for communicating information with other communities 40. In the present embodiment, the communication means 11 provided in each community 40 is connected to each other via a power line drawn into each community 40 and can communicate using a power line carrier technology. However, each community 40 owns the network address of another community 40.

  The predicted energy load deriving unit 12 derives the predicted energy load of the energy consuming apparatus 20 in its own community 40. That is, the power consumption and heat consumption as an energy load are predicted. For example, it can be derived based on past utility usage. Therefore, the predicted energy load deriving unit 12 calculates the predicted energy load of its own community 40 based on the past utility usage measured by the utility measuring unit 21 and stored in the storage device (not shown). Can be derived. Alternatively, the predicted energy load deriving unit 12 may derive the predicted energy load of the own community 40 based on a schedule of events that occur in the own community 40. The predicted energy load can also be corrected by referring to information on the calendar, climate, and the like.

The operation plan creation means 13 includes information on the predicted energy load of the energy consuming device 20 in each community 40 connected to each other by the power line 1, information on the energy supply characteristics of the energy supply device 30 in each community 40, and Based on the above, an operation plan for the energy supply device 30 in each community 40 is created. That is, the operation plan creation means 13 creates not only the operation plan of the energy supply device 30 in its own community 40 but also the operation plan of the energy supply device 30 in another community 40. The operation plan created at this time is configured by an optimal calculation for the purpose of energy saving, or by all the communities 40 so that the energy consumption in the community group composed of all the communities 40 becomes the smallest. It is created by an optimal calculation that minimizes the energy cost in the community group, that is, for the purpose of cost saving. Alternatively, it may be performed optimization calculation for the purpose of such low CO ₂ emissions. However, when the energy supply device 30 is the energy storage device 30S, the amount of energy generated when performing the operation of releasing energy from the energy storage device 30S is a positive value, and the energy generation when performing the operation of storing energy. The quantity is negative.

  The energy supply characteristics of the energy supply device 30 include the form of energy that can be supplied by the energy supply device 30 (electricity, hot water, warm air, cold air), the instantaneous value of the energy supply amount, the total amount, and the energy supply efficiency. . Therefore, the energy generated by operating the energy supply device 30 in its own community 40 is sent to the other community 40 (for example, electric energy is sent to the other community 40 via the power line 1), and the community 40 May be consumed by the energy consuming device 20.

  The operation plan is created by the operation plan creation means 13 once a day (for example, once at 2:00 am), when it is created as an operation plan for 24 hours, or once an hour. It may be created in the form of updating the operation plan. Further, the information on the energy supply characteristics of the energy supply device 30 of the other community 40 and the predicted energy load in the other community 40 can be obtained by providing each other via the communication means 11 when the operation plan is created. . Therefore, the information about the predicted energy load and the information about the energy supply characteristic used for creating the operation plan are common among the plurality of communities 40. As a result, the plurality of operation plans created by the operation plan creation means 13 in the plurality of communities 40 are the same as each other.

  The operation control means 14 operates the energy supply device 30 in its own community according to the operation plan created by the operation plan creation means 13. Therefore, the energy generated by the energy supply device 30 provided in the community group composed of all the communities 40 becomes a value close to the energy consumed by the energy consuming device 20 in this community group. Therefore, excess and deficiency of energy in the community group can be suppressed.

  The community 40b shown in FIG. 2 includes only the energy supply device 30b. Therefore, the community management apparatus 10b includes the communication unit 11, the operation plan creation unit 13, and the operation control unit 14. The configurations of the communication unit 11, the operation plan creation unit 13, and the operation control unit 14 are the same as described above.

  The community 40h shown in FIG. 2 includes only the energy consuming device 20h. Therefore, the community management device 10 h includes the communication unit 11 and the predicted energy load deriving unit 12. The configurations of the communication unit 11 and the predicted energy load deriving unit 12 are the same as described above.

FIG. 3 is a flowchart of control performed in the distributed energy community system in the first embodiment.
In step # 100, the operation plan creation means 13 of the community management device 10 at the timing of creating the operation plan, information on the predicted energy load of the energy consuming device 20 in each community 40 and the energy characteristics of the energy supply device 30 Are provided using the communication means 11. Next, in step # 102, the operation plan creation means 13 uses information on the predicted energy load of the energy consuming device 20 in each community 40 and information on the energy supply characteristics of the energy supply device 30 in each community 40. Based on this, the operation plan of the energy supply device 30 in each community 40 is created by optimal calculation. In step # 104, the operation plan creation means 13 uses the communication means 11 to transmit the created operation plan to another community. Thereafter, in step # 106, the operation control means 14 causes the energy supply device 30 in its own community to operate according to the operation plan created by the operation plan creation means 13.

As described above, in the distributed energy community system according to the first embodiment, the energy provided in each community in the community including the energy supply device can be provided without providing a special center device for creating an operation plan. A supply device operation plan is created by each community management device. Therefore, it is not necessary to provide a center device separately from each community and introduce an arithmetic processing device, an application, a communication function, and the like there. Therefore, the cost for constructing a decentralized energy community system can be reduced.
In addition, since energy interchange can be performed between the energy supply device and the energy consumption device in each community, each community can contribute to the achievement of targets such as energy saving, cost saving, and low CO ₂ emission. In addition, even a community that does not have an energy supply device but only an energy consumption device consumes surplus energy generated in other communities, so that it can save energy and save energy as a member of multiple communities. It can contribute to the achievement of targets such as cost and low CO ₂ emissions. Similarly, energy can be accommodated from a community including only energy supply devices to other communities including energy consuming devices, so that a community including only energy supply devices can also achieve targets such as energy saving, cost saving, and low CO ₂ emissions. You can contribute.

Second Embodiment
The distributed energy community system of the second embodiment is different from the first embodiment in the configuration of the community management device. Although the structure of the community management apparatus in 2nd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to 1st Embodiment.

FIG. 4 is a functional block diagram illustrating a specific example of the distributed energy community system according to the second embodiment. In the present embodiment, the community management device 10 provided in the community 40 including the energy supply device 30 includes a community group determination unit 15 and a device characteristic storage unit 16 for the community management device described in the first embodiment. It is additionally provided.
However, the community management device 10 provided in the community 40 (40h) including only the energy consuming device 20 does not include the community group determination unit 15, but the community 40h is any one of the community group determination unit 15 determined by the community group determination unit 15. It belongs to the community group.

The community group determination means 15 determines the community group which consists of a some community among all the communities. For example, as the number of communities 40 increases, the amount of information that the operation plan creation means 13 performs arithmetic processing to create an operation plan also increases. For this reason, in the present embodiment, the number of communities for which the operation plan creation unit 13 creates an operation plan is reduced to an appropriate number, and the amount of information that is calculated by the operation plan creation unit 13 is reduced to an appropriate amount. Therefore, the community group determination means 15 determines a community group.
For example, the community group determination means 15 of each community management device 10 exists at least in a range where communication is possible using the communication means 11 in order to prevent an increase in time and calculation load required for creating an operation plan, and a predetermined amount. A community group composed of a plurality of communities equal to or less than the number of community members is determined.

  The device characteristic storage means 16 stores information on the energy supply characteristics of the energy supply device 30 managed by the community management device 10 by updating the actual operation results. In the present embodiment, the energy supply characteristics include the form of energy that can be supplied by the energy supply device (electricity, hot water, warm air, cold air, etc.), the instantaneous value of the energy supply amount, the total amount, and the energy supply efficiency. The characteristics of the energy supply device 30 are changed according to actual operation results. For example, in the case of the storage battery 36, the instantaneous value of the dischargeable amount or the chargeable amount, the total amount, the energy supply efficiency, and the like change from time to time. Therefore, if the communication means 11 provides information on the energy supply characteristics with the community 40 of the same community group as needed, and the device characteristic storage means 16 stores the information on the energy supply characteristics, The operation plan creation means 13 can create an operation plan of the energy supply device 30 in the community group to which the own community belongs based on the information on the latest energy supply characteristics.

FIG. 5 is a flowchart of control performed in the distributed energy community system in the second embodiment. However, it is assumed that the community group has already been determined.
In step # 200, the operation plan creation unit 13 of the community management device 10 uses the communication unit 11 to transmit information on the predicted energy load between the communities 40 belonging to the same community group at the timing of creating the operation plan. Providing each other. Next, in step # 202, the operation plan creation means 13 includes information on the predicted energy load of the energy consuming device 20 in each community 40 and the energy supply device 30 in each community 40 stored in the device characteristic storage means 16. Based on the information on the energy supply characteristics, an operation plan for the energy supply device 30 is created by optimal calculation only for each community 40 belonging to the same community group. In step # 204, the operation plan creation means 13 uses the communication means 11 to transmit the created operation plan to other communities belonging to the same community group. Thereafter, in step # 206, the operation control unit 14 causes the energy supply device 30 in its own community to operate according to the operation plan created by the operation plan creation unit 13.

<Third Embodiment>
The distributed energy community system of the third embodiment is different from the second embodiment in the configuration of the community management device. Although the structure of the community management apparatus in 3rd Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to 1st Embodiment and 2nd Embodiment.

  FIG. 6 is a functional block diagram illustrating a specific example of the distributed energy community system according to the third embodiment. In the present embodiment, the community management device 10 provided in the community 40 including the energy supply device 30 is additionally provided with a parent community determination unit 17 with respect to the community management device described in the second embodiment. The community 40 that does not include the energy supply device 30 does not include the parent community determination means 17 and does not become a parent community.

  The parent community determining means 17 determines a parent community among the plurality of communities 40 constituting the community group. For example, the parent community determining unit 17 is linked with the parent community determining unit 17 of another community 40 belonging to the same community group, and determines the community 40 provided with both the energy consuming device 20 and the energy supplying device 30 as the parent community. To do. Therefore, a plurality of parent communities may exist in the same community group. Then, the operation plan creation means 13 provided in the parent community creates an operation plan for the energy supply device 30 in the community group to which the own community 40 belongs.

  In the present embodiment, the parent community determination unit 17 performs processing for determining a parent community when a new community 40 is connected to the power line 1. That is, when one community 40 provided with the energy supply device 30 is connected to the power line 1, that community becomes the parent community. Then, when another community 40 equipped with the energy supply device 30 is connected next, the parent community determining means 17 of those communities 40 determines the parent community.

Therefore, in the distributed energy community system of the third embodiment, the operation plan creation means 13 of the community management device 10 provided in the parent community is the same according to the control flow described with reference to FIG. 5 in the second embodiment. An operation plan of the energy supply device 30 of each community 40 belonging to the community group is created, and the operation plan is transmitted to the other communities 40.
And in communities other than the parent community, the operation plan creation means 13 of the community management device 10 does not create an operation plan of the energy supply device 30. Then, the operation control means 14 controls the operation of its own energy supply device 30 according to the operation plan received from the parent community.

<Fourth embodiment>
The distributed energy community system of the fourth embodiment is different from the third embodiment in the configuration of the community management device. Although the structure of the community management apparatus in 4th Embodiment is demonstrated below, description is abbreviate | omitted about the structure similar to 1st Embodiment-3rd Embodiment.

FIG. 7 is a functional block diagram illustrating a specific example of the distributed energy community system according to the fourth embodiment. In the present embodiment, the operation plan determination means 18 is provided in the community management device 10 provided in the community 40 including the energy supply device 30.
The operation plan determination means 18 determines an operation plan for execution from among the operation plans created by the operation plan creation means 17 and provided by the communication means 11 between the communities 40.

  When an operation plan is created separately by the operation plan creation means 13 of each community 40, the created operation plan may be different among the communities 40 due to a system error or a calculation error. Even in such a case, in the distributed energy community system of the present embodiment, the operation plan determining means 18 is provided in the community management device 10, so that one of the communities 40 belonging to the same community group should be executed. The operation plan can be determined. For example, the operation plan determination means 18 compares each operation plan provided with each community 40, and determines the operation plan for execution by majority vote.

FIG. 8 is a flowchart of control performed in the distributed energy community system according to the fourth embodiment. However, the community group and the parent community are already determined.
In step # 400, the operation plan creation means 13 of the community management device 10 uses the communication means 11 to transmit information on the predicted energy load between the communities 40 belonging to the same community group when the operation plan is created. Providing each other. Next, in step # 402, the operation plan creation means 13 includes information on the predicted energy load of the energy consuming apparatus 20 in each community 40 and the energy supply apparatus 30 in each community 40 stored in the apparatus characteristic storage means 16. Based on the information on the energy supply characteristics, an operation plan of the energy supply device 30 in each community 40 belonging to the same community group is created by optimal calculation. In step # 404, the operation plan creation means 13 uses the communication means 11 to transmit the created operation plan to other communities belonging to the same community group.

  The operation plan determination means 18 provided in each community 40 in step # 406 determines an operation plan for execution from among operation plans created by itself and other communities 40. Thereafter, in step # 408, the operation control unit 14 causes the energy supply device 30 in its own community to operate according to the operation plan created by the operation plan determination unit 18.

<Another embodiment>
<1>
In the above-described embodiment, electrical energy can be interchanged among the plurality of communities 40, but thermal energy may be configured to be interchangeable.

<2>
In the above embodiment, an example has been described in which the parent community determination unit 17 determines the community 40 in which both the energy consuming device 20 and the energy supply device 30 are provided as the parent community. However, the parent community is determined based on other criteria. May be. For example, based on the information stored in the device characteristic storage unit 16, the parent community determination unit 17 selects the community having the largest energy supply amount (or several from the largest) as the parent community. Modifications may be made to determine. Or you may modify | change so that the community connected with respect to the power line 1 earliest may become a parent community.

<3>
In the above embodiment, the operation plan creation means 13, the operation control means 14, the community group determination means 15, the device characteristic storage means 16, the parent community determination means 17, and the operation plan determination means 18 are provided in the community including only the energy consuming device. The community including only the energy consuming apparatus may be modified so that the operation plan of the energy supply apparatus of each community is created.

  The distributed energy community system according to the present invention can be used to exchange energy between communities provided with energy supply devices such as distributed power sources.

Block diagram explaining the schematic configuration of a distributed energy community system Functional block diagram illustrating a specific example of the distributed energy community system of the first embodiment Flow chart of control performed in the distributed energy community system in the first embodiment Functional block diagram illustrating a specific example of the distributed energy community system of the second embodiment Flow chart of control performed in the distributed energy community system in the second embodiment Functional block diagram illustrating a specific example of the distributed energy community system of the third embodiment Functional block diagram illustrating a specific example of the distributed energy community system of the fourth embodiment Flowchart of control performed in the distributed energy community system in the fourth embodiment

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Power line 10 Community management apparatus 11 Communication means 12 Predicted energy load derivation means 13 Operation plan preparation means 14 Operation control means 15 Community group determination means 16 Device characteristic storage means 17 Parent community determination means 18 Operation plan determination means 20 Energy consumption apparatus 30 Energy Supply device 31 Hot water supply device (energy supply device, energy generation device)
32 Cogeneration device (energy supply device, energy generator)
33 Hot water storage device (energy supply device, energy storage device, heat storage device)
34 Heating hot water supply device (energy supply device, energy generation device)
35 Heat pump device (energy supply device, energy generator)
36 Storage battery (energy supply device, energy storage device, power storage device)
37 Flywheel (energy supply device, energy storage device, power storage device)
38 capacitors (energy supply devices, energy storage devices, power storage devices)

Claims (7)

A distributed energy community in which a plurality of communities each including at least one of an energy consuming device and an energy supplying device are connected to enable the energy supply from the energy supplying device to the energy consuming device between the plurality of communities. A system,
Each community has a community management device that manages the energy consuming device and the energy supply device,
The community management device provided in the community including the energy supply device includes communication means for communicating information with other communities, information on the predicted energy load of the energy consuming device in each community, and the community in each community. based on the information about the energy delivery characteristics of the energy supply system, the operation plan generating means for generating the operation plan of the energy supply apparatus in the operation plan and other communities of the energy supply device in its community, its community Operation control means for operating the energy supply device in accordance with the operation plan,
The community management device provided in the community including the energy consuming device has at least the communication unit and a predicted energy load deriving unit that derives a predicted energy load of the energy consuming device in its community,
Communities, including the energy supply device is connected to a plurality,
The community management device provided in the community including the energy supply device is:
Information about the predicted energy load of the energy consuming device in the other community and information about the energy supply characteristics of the energy supply device in the other community are obtained from the other community by the communication means. distributed energy Community system configured.   The community management device provided in the community including the energy supply device is a device characteristic storage unit that updates and stores information on energy supply characteristics of the energy supply device managed by the community management device according to an actual operation result. The distributed energy community system according to claim 1. The community management device provided in a community including the energy supply device has a community group determination means for determining a community group consisting of a plurality of communities among all communities,
The distributed energy community system according to claim 1 or 2, wherein the operation plan creation means creates an operation plan of the energy supply device in the community group to which its own community belongs. The community management device provided in a community including the energy supply device has a parent community determination means for determining a parent community among a plurality of communities constituting the community group,
The distributed energy community system according to claim 3, wherein the operation plan creation means provided in the parent community creates an operation plan of the energy supply device in the community group to which its own community belongs. The community management device included in the community including the energy supply device is an operation plan determination unit that determines an operation plan for execution from among the operation plans created by the operation plan creation unit and provided by the communication unit. Have
The distributed operation community system according to any one of claims 1 to 4, wherein the operation control unit causes an energy supply device in its own community to operate according to the operation plan for execution. The energy supply device includes an energy generation device that is a combined heat and power supply device, a hot water supply device, a heating hot water supply device, or a heat pump device that supplies heat energy and electric energy together, and an energy storage device or an energy storage device. The distributed energy community system according to any one of claims 1 to 5, which is at least one storage device.   The distributed energy community system according to any one of claims 1 to 6, wherein the communication means provided in each community are connected to each other by a power line.

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