JP6394087B2 - Energy management system - Google Patents

Description

  The present invention relates to an energy management system.

  Conventionally, CEMS (Cluster Energy Management System or Community Energy Management System) has been proposed as a system for managing energy consumption in units of regions.

  As an example of such a CEMS, a technique described in Patent Document 1 is known. In the technique described in Patent Document 1, an energy network monitoring device (hereinafter referred to as a server) acquires energy usage record information and energy supply information of a plurality of houses (customers and suppliers). Then, the server predicts the energy supply and demand amount used by these houses based on the acquired information, and repeatedly calculates the operation plan of the energy equipment of each house based on the prediction result.

JP 2013-156937 A

  In the technology as described above, the server repeatedly obtains information from each house and corrects the operation plan repeatedly. However, when the frequency at which each house transmits information is high, the frequency at which the server corrects the operation plan also increases. Therefore, there is a high possibility that the load on the server becomes too high. However, if the frequency with which each house transmits information is lowered, the real-time property of the operation plan created by the server may be impaired.

  In view of the above points, an object of the present invention is to realize an agile operation plan creation while suppressing an increase in the load on a server in a technique for repeatedly creating an operation plan for energy equipment in each house.

Invention of Claim 1 for achieving the said objective is equipped with the server (1) and the some energy management terminal (5a-5c) each provided in the some house (3a-3c), Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. An event notification command is transmitted to the server based on being in an operating state, and when the server receives an event notification command from one of the plurality of energy management terminals, the plurality of energy management terminals are installed. An operation plan of the energy equipment of the house that has been made is created and transmitted to the plurality of energy management terminals, and each of the plurality of energy management terminals When receiving the operation plan of the energy equipment of the installation destination home from server, have row control of energy equipment of the Site house based on the received drive plan, each of the plurality of energy management terminal, the installation destination house Monitoring the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c), and the event notification command, And the performance data of the energy supply and demand by the energy equipment of the installation destination house are transmitted to the server, and the server receives an event notification command and one of the installation destination houses from one of the plurality of energy management terminals. When the actual data on energy supply and demand by the energy device is received, the plurality of energy pipes are based on the received actual data. The operation plan of the energy equipment of the house where the terminal is installed is created and transmitted to the plurality of energy management terminals, and each of the plurality of energy management terminals is configured as an operating state of the energy equipment of the installation destination house. Energy management characterized in that the amount of stored hot water is monitored and, based on the fact that the amount of stored hot water is below a set lower limit value, actual data on energy supply and demand by the energy equipment in the installation destination house is transmitted to the server. System .
Moreover, invention of Claim 3 is equipped with the server (1) and the some energy management terminal (5a-5c) each provided in the some house (3a-3c), These some energy management Each of the terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home are in an operation state that satisfies the event notification condition. And sending an event notification command to the server,
When the server receives an event notification command from one of the plurality of energy management terminals, the server creates an operation plan of a home energy device in which the plurality of energy management terminals are installed, and sends the operation plan to the plurality of energy management terminals. Each of the plurality of energy management terminals, when receiving an operation plan of the energy equipment of the installation destination house from the server, to control the energy equipment of the installation destination house based on the received operation plan, Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. Based on the status, the event notification command and the energy demand from the energy equipment in the installation home When the server receives the event notification command and the energy supply / demand performance data from the energy equipment of the installation house from one of the plurality of energy management terminals, Based on the received performance data, the operation plan of the energy equipment of the house where the plurality of energy management terminals are installed is created and transmitted to the plurality of energy management terminals, and the server includes the plurality of energy management terminals. An event setting command including an event notification condition is transmitted to at least one of them, and each of the at least one energy management terminal receives the event setting command from the server, and includes the received event setting command. The event notification condition is set to the event An energy management system and recording condition.
Moreover, invention of Claim 5 is equipped with the server (1) and the some energy management terminal (5a-5c) each provided in the some house (3a-3c), These some energy management Each of the terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home are in an operation state that satisfies the event notification condition. And sending an event notification command to the server,
When the server receives an event notification command from one of the plurality of energy management terminals, the server creates an operation plan of a home energy device in which the plurality of energy management terminals are installed, and sends the operation plan to the plurality of energy management terminals. Each of the plurality of energy management terminals, when receiving an operation plan of the energy equipment of the installation destination house from the server, to control the energy equipment of the installation destination house based on the received operation plan, Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. Based on the status, the event notification command and the energy demand from the energy equipment in the installation home When the server receives the event notification command and the energy supply / demand performance data from the energy equipment of the installation house from one of the plurality of energy management terminals, Based on the received performance data, the operation plan of the energy equipment of the house where the plurality of energy management terminals are installed is created and transmitted to the plurality of energy management terminals, and the server includes the plurality of energy management terminals. An event setting command including an event notification condition and a counter value is transmitted to at least one of them, and when each of the at least one energy management terminal receives the event setting command from the server, the event setting command is sent to the received event setting command. The event notification conditions included in the energy equipment of the installation home The event value is recorded as an event notification condition, and the counter value included in the received event setting command is recorded. Each of the at least one energy management terminal monitors the operating state of the energy device in the installation destination house, and installs it. After the energy device of the previous house has transitioned to the state set as the event notification condition, it has been detected that the energy device of the installed house is in the state continuously for the number of times equal to or greater than the recorded counter value. In this case, the energy management system is characterized in that the actual data of energy supply and demand by the energy equipment in the installation destination house is transmitted to the server.

  As described above, each of the plurality of energy management terminals transmits an event notification command to the server based on the fact that the operation state of the energy device in the installation destination home is set as the event notification condition. When the server receives the event notification command, the server creates an operation plan for the energy device in the house where the plurality of energy management terminals are installed, and transmits the operation plan to the plurality of energy management terminals.

  In this way, the event notification command is sent and the operation plan is created by selecting the case where the state has been changed in advance by setting, so it is possible to select and send the operation plan when necessary. Become. In the technique of repeatedly creating an operation plan for energy equipment in each house, it is possible to realize an agile operation plan while suppressing an increase in server load.

It is a lineblock diagram of the energy management system concerning the embodiment of the present invention. It is a block diagram of a regional server. It is a block diagram of an energy management terminal. It is a flowchart of a planning process. It is a flowchart of an event notification condition setting process. It is a flowchart of an event notification condition management process. It is a flowchart of a notification process. It is a sequence diagram of the example of an action | operation of an energy management system. It is a figure which shows the transition of power consumption, and the relationship of event occurrence. It is a lineblock diagram of the energy management system concerning the embodiment of the present invention. It is a figure which shows the process sequence of the event notification process in an energy management system. It is a figure which shows the process sequence of the event notification condition setting process in an energy management system. It is an internal block diagram of the existing HEMS system. It is a new internal block diagram of a HEMS system. It is a figure of the flow of a power threshold excess event notification. It is a figure of the flow of communication between each energy apparatus in an event notification. It is a figure of the communication sequence in an event notification. It is a table | surface of an event setting command (area server-> HEMS). It is a table | surface of an event setting command (area server-> HEMS). It is a table | surface of an event setting command (area server-> HEMS). It is a table | surface of an event setting command (area server-> HEMS). It is a table | surface of an event setting command (HEMS-> regional server). It is a table | surface of an event setting command (HEMS-> regional server). It is a table | surface of an event setting command (HEMS-> regional server). It is a figure which shows the collection cycle of the electric power performance information between each energy apparatus. It is a figure which shows the flow of operation | movement of a peak cut function.

(First embodiment)
The first embodiment of the present invention will be described below. An energy management system 100 according to the present embodiment shown in FIG. 1 is for realizing a CEMS (Cluster Energy Management System or Community Energy Management System). As shown in FIG. 1, the energy management system 100 includes a regional server 1 and a system power supply side terminal 2, and includes a plurality of consumers 3a to 3c.

  Consumers included in the energy management system 100 are built in the same area. The number of customers included in the energy management system 100 may be about 10 units, about 100 units, or about 1000 units, but in this embodiment, as an example, three customers 3a to 3c are energized. It is included in the management system 100. In the present embodiment, each of the consumers 3a to 3c is also a supplier with a generator installed.

  The consumers 3a to 3c have gateways 4a to 4c, energy management terminals 5a to 5c, and energy devices 61a to 63a, 61b to 63b, 61c to 63c, respectively. Taking the customer 3a as an example, the customer 3a has a gateway 4a, an energy management terminal 5a, and energy devices 61a, 62a, 63a.

  The regional server 1 is a device that performs peak shift or leveling of energy supply and demand of the entire energy management system 100 by communicating with the energy management terminals 5a to 5c via the gateways 4a to 4c.

  As shown in FIG. 2, the regional server 1 includes a communication unit 11, a memory 12, and a calculation unit 13. The communication unit 11 is a network interface for communicating with the grid power supply side terminal 2 and communicating with the energy management terminals 5a to 5c via the gateways 4a to 4c. The memory 12 is a storage medium in which programs executed by the arithmetic unit 13 and various parameters are recorded. The calculation unit 13 is a calculation circuit that executes a plan process 13a, an event notification condition setting process 13b, and the like, which will be described later, by executing a program recorded in the memory 12. The calculation unit 13 executes the planning process 13a and the event notification condition setting process 13b in a multitask simultaneously in parallel.

  The system power supply side terminal 2 is a system power supply source (such as a power plant) that supplies power to each of the devices 4a to 4c, 5a to 5c, 61a to 63a, 61b to 63b, and 61c to 63c of the consumers 3a to 3c. It is a device that repeatedly creates power supply information (such as an upper limit value of suppliable power) and periodically transmits it to the regional server 1.

  The gateways 4a to 4c are devices (for example, home routers) that mediate communication between the energy management terminals 5a to 5c in the customer at the installation destination (the customer on which the device is installed) and the regional server 1.

  The energy management terminals 5a to 5c control the operation of each energy device 61a to 63a, 61b to 63b, 61c to 63c in the customer of the installation destination received from the regional server 1, and each energy device 61a to 63a, 61b. The operating states of ˜63b and 61c˜63c are monitored.

The energy devices 61a to 63a, 61b to 63b, and 61c to 63c may include electric energy devices that operate by consuming electric power, such as indoor air conditioners, lighting devices, and electric floor heating devices. Furthermore, a generator that supplies electric power (for example, a solar generator, a gas generator that generates power using gas as a fuel, or a hydrogen generator that generates power using hydrogen as a fuel) may be included. Furthermore, it may include a water heater including a hot water storage device (for example, a CO ₂ cycle water heater that boils hot water with electric power), a power storage device that stores electric power, or may be used in a hydrogen generator. A hydrogen storage device that stores hydrogen may be included.

  As illustrated in FIG. 3, each of the energy management terminals 5 a to 5 c (hereinafter simply referred to as the energy management terminal 5) includes a communication unit 51, a memory 52, an operation unit 53, and a control unit 54.

  The communication unit 51 includes an out-of-home communication interface for communicating with the regional server 1 via a gateway installed in the same house among the gateways 4a to 4c, and further includes energy devices 61a to 63a, 61b to 63b, and 61c. ˜63c, an in-home communication interface for communicating with energy devices installed in the same house is provided.

  The memory 52 is a non-volatile memory (for example, a flash memory) for recording an event notification condition 521, a counter value 522, and the like which will be described later. The operation unit 53 is a device that directly receives a user operation. The control unit 54 is a microcomputer including a CPU, a RAM, a ROM, and the like. The CPU executes a program recorded in the ROM, and uses the RAM as a work area when executing the program. The processes realized by the CPU executing the program recorded in the ROM include an energy supply and demand measurement process 541, a notification process 542, an energy device control process 543, and a notification condition management process 544. The control unit 54 executes these processes 541 to 544 in a multitask simultaneously in parallel.

Hereinafter, the operation of the energy management system 100 configured as described above will be described in detail. In this operation, all of the following conditions are recorded as or conditions as event notification conditions 521 in the memory 52 of the energy management terminal 5. As another example, a plurality of conditions may be recorded as an and condition, or a combined condition of or and and may be recorded.
(A) Condition that the total power consumption in the customer at the installation destination is larger than the upper limit value Pmax (threshold value) (b) Condition that the total power consumption in the customer at the installation destination is smaller than the lower limit value Pmin (threshold value) (C) The condition that the amount of hot water stored in the hot water storage device of the customer at the installation destination is smaller than the lower limit value Cmin (threshold) (d) The condition that the energy device of the customer at the installation destination has failed (e) On the other hand, the condition that a user operation to change the operation of the energy equipment of the consumer at the installation destination has occurred. Note that the hot water storage device of (c) is limited to that supplied with hot water from a water heater that boils hot water with electric power. May be.

  First, energy supply and demand measurement processing 541 and device control processing 543 executed by the control unit 54 of the energy management terminal 5 will be described. The control unit 54 continuously executes the energy supply and demand measurement process 541, thereby monitoring the operation state of each energy device installed in the customer at the installation destination sequentially (for example, periodically and once a second).

  The operating state of each energy device to be monitored includes the amount of energy supply and demand of each energy device, the amount of electricity stored in the storage battery, the amount of hot water stored in the hot water storage device, the presence or absence of a failure in each energy device, and the user operation on the operation unit 53 in the consumer. Changes in the operation of each energy device are included. As described above, the control unit 54 functions as an energy supply / demand measurement unit by executing the energy supply / demand measurement process 541. These operation states may be received from each energy device via the communication unit 51. Further, the amount of energy supply and demand of each energy device may be specified based on a signal from a distribution board (not shown).

  The amount of energy supply and demand of the energy device in the present embodiment is AB, where A is the power supplied to the energy device and B is the power supplied to the outside from the energy device. For example, in the case of an energy device that exclusively consumes electric power, such as an air conditioner or a lighting device, the power consumption is the amount of energy supply and demand. Further, a value obtained by multiplying the generated power of the power generation device by −1 is the amount of energy supply and demand of the power generation device. In addition, when the power storage device is deenergizing, the amount of energy supply and demand is positive, and when it is discharged, the amount of energy supply and demand is negative.

  Moreover, the control part 54 controls the action | operation of the energy equipment of the consumer of an installation place (namely, drive | operates) by always performing the energy equipment control process 543. More specifically, based on having received the operation plan mentioned later from the regional server 1, it controls so that the energy equipment of the consumer of an installation destination may operate | move according to the schedule designated by the said operation plan. Moreover, when the user operation which changes the action | operation of the energy equipment of the consumer of an installation destination generate | occur | produces with respect to the operation part 53, the action | operation of the said energy equipment is controlled according to the content of the user operation. For example, charging and discharging of the power storage device are switched according to a user operation on the operation unit 53.

  Next, the operation of the regional server 1 will be described. As shown in FIG. 4, the calculation unit 13 of the regional server 1 determines whether or not the regular communication timing that comes at regular time intervals (specifically, 30 minutes) has arrived in step 105 as shown in FIG. 4. If it is not visited, the process proceeds to step 110. In step 110, it is determined whether or not an event notification command is newly received from any of the energy management terminals 5a to 5c. If not received, the process returns to step 105. That is, the calculation unit 13 of the regional server 1 repeats the loop of steps 105 and 110 until the regular communication timing comes or the event notification command is received in the planning process 13a.

  In addition, in the event notification condition setting process 13b that is always executed, the calculation unit 13 of the regional server 1 first, as shown in FIG. 5, in step 160, for any one or more of the energy management terminals 5a to 5c. To determine whether it is necessary to change the event notification condition or counter value setting.

  If it is determined that neither the event notification condition nor the counter value needs to be changed, step 160 is executed again. That is, the calculation unit 13 repeats the determination in step 160 until it determines that the event notification condition needs to be changed or until it is determined that the counter value needs to be changed.

  Examples of the case where it is determined that it is necessary to change the setting of the event notification condition or counter value include the following (Example 1) to (Example 3).

  (Example 1) When the predetermined time of the day corresponding to the turn of the season arrives, the calculation unit 13 needs to change the setting of the event notification condition for all of the energy management terminals 5a to 5c. Determine and proceed to step 170. The predetermined time of the day corresponding to the change of season is, for example, 00: 00: 00: 00 on April 1, 00: 00: 0 on July 1, and 0: 0: 0 on September 1. There will be 0:00:00 on December 1st. This is because the power consumption of each consumer varies greatly depending on the season.

  (Example 2) The calculation unit 13 may change the weather in the area where the consumers 3a to 3c are located from sunny to cloudy or rainy during the daytime (for example, from 8:00:00 to 4:00:00) On the other hand, when the change is made, it is necessary to change the setting of the event notification condition for all the energy management terminals 5a to 5c regardless of whether the photovoltaic power generation apparatus is not attached to the customer at the installation destination. Determine and proceed to step 170. This is because when the weather is cloudy or rainy, the amount of power generated by the photovoltaic power generation device is greatly reduced compared to when it is clear, so there is a high possibility that the power obtained from the grid power source will be tight. Because it becomes. In addition, the calculating part 13 comes to acquire repeatedly the weather of the area where the consumers 3a-3c are located from the weather server which is not shown in figure using the communication part 11, for example (for example, once every 10 minutes regularly). It may be.

  (Example 3) The calculation unit 13 changes the setting of the counter value for the energy management terminal 5 based on continuous reception of an event notification command, which will be described later, from the energy management terminal 5 of a certain consumer by the upper limit number of times. It is determined that it is necessary to perform the operation, and the process proceeds to step 170.

  When the process proceeds to step 170 as in (Example 1) to (Example 3), the event notification condition is updated in Step 170 when it is determined in Step 160 that it is necessary. In the case of the above (Example 3), the event notification condition is not updated.

  When it corresponds to the above (example 1), among the event notification conditions for all the energy management terminals 5a to 5c, the upper limit value and the lower limit value of the total power consumption in each consumer are changed. For example, when the season changes from spring to summer, the upper limit value Pmax and the lower limit value Pmin of the total power consumption in each consumer described later are reduced. Further, for example, when the season changes from summer to autumn, the upper limit value Pmax and the lower limit value Pmin of the total power consumption in each consumer described later are increased. The upper limit value Pmax and the lower limit value Pmin are used for determination of an event notification condition described later, and are also used for selecting a template described later.

  Even in the case of the above (Example 2), among the event notification conditions for all the energy management terminals 5a to 5c, the upper limit value and the lower limit value of the total power consumption in each consumer are changed. For example, when the weather changes from sunny to cloudy or rainy, the upper limit value Pmax and the lower limit value Pmin of total power consumption in each consumer are reduced. For example, when the weather changes from cloudy or rainy to sunny, the upper limit value Pmax and the lower limit value Pmin of total power consumption in each consumer are increased.

  In the following step 180, the counter value is updated when it is determined in step 160 that it is necessary. When the above (Example 1) and (Example 2) are applicable, the counter value is not updated. In the case of the above (Example 3), the counter value is increased more than before. For example, increase from 1 to 5. In addition, when the state where the counter value is 5 or more continues for a predetermined period, the counter value may be returned to 1.

  Subsequently, in step 190, an event setting command is transmitted to the energy management terminals 5a to 5c using the communication unit 11.

  This event setting command may include all event notification conditions including updated event notification conditions and non-updated event notification conditions, or include only updated event notification conditions. Also good. The event setting command may include a counter value, whether or not it is updated, or may include a counter value only when it is updated. .

  In addition, the content of the event notification condition included in the event setting command may be different or the same for each energy management terminal 5 of the transmission destination. Further, the contents of the counter value may be different or the same for each energy management terminal 5 of the transmission destination. The event setting command may be transmitted only to the energy management terminal 5 that needs to be updated, or may be transmitted to all the energy management terminals 5a to 5c each time. The contents of the event setting command may be as described in (Additional configuration) described later. After step 190, the process returns to step 150.

  In the operation example shown in FIG. 8, at the time point t1, one of the above (Example 1) to (Example 3) is satisfied, and as a result, the event setting command 305 is transmitted from the regional server 1 to the energy management terminal 5. . In the energy management terminal 5, the control unit 54 is constantly executing the notification condition management process 544 shown in FIG. 6, and whether or not an event setting command is received from the regional server 1 through the communication unit 51 in step 260. Step 260 is repeated until it is determined that it has been received. If it is determined that it has been received, the process proceeds to step 270, where the contents of the received event setting command are recorded in the memory 52 (step 307 in FIG. 8). Specifically, all event notification conditions and counter values included in the received event setting command are overwritten in the memory 52. In the example of FIG. 8, it is assumed that the counter values 522 of the energy management terminals 5a to 5c are all 1 by the recording in step 307.

  In FIG. 8, only one energy management terminal is illustrated for simplicity, but a plurality of energy management terminals 5 a to 5 c actually communicate with the regional server 1.

  Further, in the notification process 542 that is always executed, the control unit 54 first determines in step 210 whether or not a performance data request to be described later has been received from the regional server 1 via the communication unit 51, as shown in FIG. If not received, the process proceeds to step 220. In step 20, it is determined whether or not an event has been triggered. If not, the procedure returns to step 220. The event is triggered only when the state where any of the event notification conditions 521 in the memory 52 is satisfied continues for the counter value 522 times. In addition, when any of the event notification conditions 521 is satisfied in M consecutive times out of the execution of step 220 N times, the state in which any of the event notification conditions 521 is satisfied continues M times. Become. Since it is in this way, the control unit 54 repeats the determinations in steps 210 and 220 until it receives a record data request or an event is triggered.

  Regardless of whether or not steps 230 and 240 described later are executed, the calculation unit 13 has a fixed period (for example, 1 minute) from the execution of step 220 to the next execution of step 220.

  After the time point t1 in FIG. 8, the event is not triggered in the energy management terminal 5 until the time point t2, which is the next periodic communication timing, and the event notification command is not transmitted in the regional server 1, and the actual result in the regional server 1 Assume that no data request is sent and no setting change is required.

  In this case, in a period after time t1 and before time t2, the calculation unit 13 of the regional server 1 repeats the determination (NO) in steps 105 and 110 in the planning process 13a, and steps in the event notification condition setting process 13b. 160 (NO) is repeated. Further, the control unit 54 of the energy management terminal 5 repeats the determination (NO) of step 260 in the notification condition management process 544 and repeats the determinations (NO) of steps 210 and 220 in the notification process 542. In addition, the control unit 54 sequentially monitors the operation state of each energy device installed in the customer at the installation destination in the energy supply and demand measurement process 541 (for example, periodically and once a second). Moreover, the control part 54 controls the action | operation of the energy equipment of the consumer of an installation place by the apparatus control process 543 according to the apparatus operation plan received from the regional server 1 before the time t1.

  At time t2, a fixed time (for example, 30 minutes) has elapsed from the previous regular communication timing, and at the same time, the calculation unit 13 determines that the regular communication timing is reached in step 105 of the planning process 13a and proceeds to step 115. . In step 115, the record data request 310 is transmitted to the energy management terminals 5a to 5c using the communication unit 11, and then the process proceeds to step 120 to wait for reception of record data for a predetermined time (for example, 5 minutes).

  Then, the control unit 54 of the energy management terminal 5 receives this result data request 310 via the communication unit 51, determines that the result data request has been received in step 210 of the notification process 542, and proceeds to step 230. In step 230, performance data 315 is created and transmitted to the regional server 1, and then the process proceeds to step 220. The actual data is the operating state of each energy device obtained by the energy supply and demand measurement process 541 in a predetermined period in the past from the present (for example, the latest 30 minutes may be the period from when the actual data was transmitted last time to the present). Create based on.

  The actual data to be created includes the amount of energy supply and demand, the amount of hot water stored in the hot water storage device, and the amount of power stored in the power storage device in the customer from which the energy management terminal 5 is installed, from the present to the past for a predetermined period. . Furthermore, the actual data created includes the presence or absence of a current failure and the current operating state in each energy device of the consumer at the installation destination of the energy management terminal 5. The operating state includes, for example, a set temperature of the air conditioner, a set temperature of the floor heating device, and the like.

  The calculation unit 13 of the regional server 1 receives the actual data transmitted from the energy management terminals 5a to 5c through the communication unit 11 within the predetermined period (for example, 5 minutes) in step 120 of the planning process 13a.

  Subsequently, in step 125, the amount of energy supply and demand of the entire consumers 3a to 3c in a period after the current time is predicted based on the received performance data. Specifically, a template that matches the received actual data is selected from a plurality of predetermined templates, and the change over time in the amount of energy supply and demand associated with the selected template is determined by the consumer who has transmitted the actual data. Adopted as a prediction of changes in energy supply and demand over time. Then, the amount of energy supply and demand of the entire consumers 3a to 3c is predicted from the prediction of the change with time in the amount of energy supply and demand of each consumer determined in this way. Note that the temporal change in the amount of energy supply and demand associated with the template differs for each template.

  Here, the latest amount of energy supply and demand P of all the energy devices installed in the consumer who is the transmission source of the actual data, that is, the latest total power consumption P of the consumer can be calculated from the actual data. However, the template to be selected differs depending on the total power consumption P.

  More specifically, a template is selected according to the relationship between the total power consumption P and the upper limit value Pmax and the lower limit value Pmin in the event notification conditions (a) and (b) for the consumer. Is different. That is, (1) when the total power consumption P is greater than the upper limit value Pmax, (2) when the upper limit value Pmax is less than or equal to the lower limit value Pmin, and (3) when the total power consumption P is less than the lower limit value Pmin, The template chosen is different. Therefore, in these three cases, the predictions of changes in energy supply and demand over time are also different.

  The template to be selected differs depending on the latest value of the hot water storage amount C of the hot water storage device included in the actual data. More specifically, the hot water storage amount C is selected in two cases, that is, a case where the hot water storage amount C is equal to or higher than the lower limit value Cmin and the lower limit value Cmin in the event notification condition (c) for the consumer. Different templates are used. Accordingly, in these two cases, the predictions of changes in energy supply and demand over time are also different.

  In addition, a template to be selected varies depending on the presence or absence of a failure of the energy device included in the result data. Therefore, the prediction of changes in the amount of energy supply and demand over time differs depending on whether there is a failure in the energy device.

  In addition, the template to be selected differs depending on whether or not the operation content of each energy device included in the result data is in accordance with the device operation plan. Therefore, the prediction of changes in energy supply and demand over time differs depending on whether the operation content of each energy device is in accordance with the device operation plan.

  Further, in step 125, the energy supply amount of the system power supply source in a period after the current time is predicted based on the power supply information of the system power supply source (power plant or the like) received from the system power supply side terminal 2.

  Further, in step 125, based on the calculated energy supply / demand prediction results of the consumers 3a to 3c and the prediction result of the energy supply amount of the grid power supply source, the energy management system 100 in the period after the current time. In order to perform peak shift or leveling of energy supply and demand, an operation plan (hereinafter referred to as device operation plan) of energy devices 61a to 63a, 61b to 63b, 61c to 63c of consumers 3a to 3c is created (step 317).

  The equipment operation plan is a schedule (time table) for how and in what time zone the operation of the energy equipment 61a to 63a, 61b to 63b, 61c to 63c is controlled. For example, whether the generator generates electricity, whether the hot water storage capacity of the hot water storage device is increased or decreased, whether the storage battery is charged or discharged, the set temperature of the air conditioner, the brightness of the TV, etc. Corresponds to the plan.

  As described in, for example, Patent Document 1, it is well known how to create an equipment operation plan for performing peak shift or leveling of energy supply and demand based on prediction results of energy supply and demand. . For example, in a time zone in which the predicted value of power consumption of the entire consumers 3a to 3c is predicted to exceed a reference value, all the rechargeable batteries in the consumers 3a to 3c are discharged and in a time zone that is less than or equal to the reference value. A plan may be created so that the rechargeable battery is charged. Further, for example, in a time zone in which the predicted value of the power consumption of the entire consumers 3a to 3c is equal to or less than a reference value, a plan is made to increase the amount of hot water stored in a hot water storage device to which hot water is supplied from a hot water supply device that boils hot water with electric power. You may create it.

  Subsequently, in step 130, the equipment operation plan created in step 125 is transmitted to the energy management terminals 5a to 5c using the communication unit 11. The equipment operation plan 320 to be transmitted to each of the energy management terminals 5a to 5c may be only a plan for the energy equipment of the consumer at the installation destination of the energy management terminal 5 among the equipment operation plans created in Step 125.

  In the energy management terminals 5a to 5c, when the control unit 54 receives the device operation plan 320 via the communication unit 51, the device control processing 543 includes the demand of the installation destination in the schedule in the new device operation plan 320. It starts to control the operation of the energy device so that the energy device of the house complies (step 322).

  After the execution time of step 322 in FIG. 8, the event is not triggered at the energy management terminal 5 until the time t3 arrives, the event notification command is not transmitted by the regional server 1, and the actual data request is also transmitted by the regional server 1. It is assumed that the setting change was not necessary. In this case, in the period after the execution time of step 322 and before the time point t3, the operation is the same as the period after the time point t1 and before the time point t2.

  At time t3, one energy management terminal 5 uses one of the event notification conditions 521 recorded in its own memory 52 (above (a), (b), (c), (d), (e It is determined that any of) is satisfied. The control unit 54, when the number of times that one of the event notification conditions 521 is satisfied and the same one of the event notification conditions 521 is continuously satisfied is greater than or equal to the counter value 522 in step 220 of the notification processing 542 Only when it is determined that the event has been triggered. In this case, since the value of the event notification condition 521 is 1, when one of the event notification conditions 521 is satisfied for the first time, it is determined in step 220 that an event has been triggered.

  If the control unit 54 determines that the event has been triggered in step 220, the control unit 54 proceeds to step 240, transmits the event notification command 325 to the regional server 1 using the communication unit 51, and proceeds to step 210. Since the event notification command 325 includes an identification code for identifying the energy management terminal 5 that is the transmission source, the regional server 1 knows from which energy management terminal 5 the received event notification command 325 has been transmitted. The contents of the event notification command may be as described in (Additional configuration) described later.

  When receiving the event notification command 325 via the communication unit 11, the calculation unit 13 of the regional server 1 determines that the event notification command has been received in step 110 of the planning process 13 a and proceeds to step 115.

  The processing contents from step 115 to step 130 and the operation of the entire energy management system 100 are the same as those in the case of proceeding from step 105 to step 115 (already described) except for the differences described below.

  Briefly, in step 115, the actual data request 330 is transmitted to the energy management terminal 5, and then the process proceeds to step 120 to wait for reception of actual data for a predetermined time (for example, 5 minutes). However, the point that the energy management terminal 5 that is the transmission destination of the record data request 330 is only the energy management terminal 5 that is the transmission source of the event notification command 325 is different from the case where the process proceeds from step 105 to step 115.

  Then, the control unit 54 of the energy management terminal 5 receives the actual data request 330, determines that the actual data request has been received in Step 210 of the notification process 542, and proceeds to Step 230. In step 230, performance data 335 is created and transmitted to the regional server 1, and then the process proceeds to step 220. Then, since the event is not triggered after the event is triggered at time t3, the process returns from step 220 to 210.

  The calculation unit 13 of the regional server 1 receives the record data 335 transmitted from the energy management terminal 5 within the predetermined period (for example, 5 minutes) in step 120 of the planning process 13a.

  Subsequently, in step 125, based on the received performance data 335, the amount of energy supply and demand of the entire consumers 3a to 3c in a period after the current time is predicted. The forecast created here is different from the previous forecast of energy supply and demand. This is because a template selected for the consumer in step 125 is different from the previous one when any of the event notification conditions (a) to (e) described above is satisfied by a certain consumer. It is.

  Furthermore, based on the power supply information of the grid power supply source (power plant etc.) received from the grid power supply side terminal 2, the energy supply amount of the grid power supply source in a period after the current time is predicted. Further, in step 125, based on these prediction results, the energy devices 61a to 63a, 61b to 61a to 3c of the consumers 3a to 3c are used to perform peak shift or leveling of energy supply and demand in a period after the current time of the entire energy management system 100. The apparatus operation plan of 63b, 61c-63c is created (step 337).

  The equipment operation plan created here is different from the equipment operation plan so far. This is because the prediction of the amount of energy supply and demand for the entire consumers 3a to 3c has become different from the past.

  Subsequently, in step 130, the equipment operation plan 340 created in step 125 is transmitted to the energy management terminals 5a to 5c. The equipment operation plan 320 to be transmitted to each of the energy management terminals 5a to 5c may be only a plan for the energy equipment of the consumer at the installation destination of the energy management terminal 5 among the equipment operation plans created in Step 125.

  In the energy management terminals 5a to 5c, when the control unit 54 receives the device operation plan 340, in the device control processing 543, the energy device of the installation destination consumer follows the contents of the new device operation plan 340. Control of the operation of the energy device begins (step 342).

  In addition, when an event notification condition such as (a) and (b) above is satisfied in a certain consumer, the power consumption will be out of the normally assumed range. There is a high possibility that the prediction made by the calculation unit 13 of the server 1 in step 125 of the planning process 13a becomes extremely inaccurate. Therefore, if the event notification command 325 and the performance data 335 are transmitted to the regional server 1 in such a case, the step 125 is executed again, the inaccuracy of the prediction is alleviated, and the equipment operation plan is accordingly appropriate. Become.

  In addition, when an event notification condition such as the above (c) is satisfied in a certain consumer, the amount of stored hot water will be out of the normally assumed range. There is a high possibility that the prediction made by the unit 13 in step 125 of the planning process 13a will be significantly inaccurate. Therefore, if the event notification command 325 and the performance data 335 are transmitted to the regional server 1 in such a case, the step 125 is executed again, the inaccuracy of the prediction is alleviated, and the equipment operation plan is accordingly appropriate. Become.

  In addition, when an event notification condition such as (d) is satisfied in a certain consumer, a failed energy device (for example, a generator) becomes unusable, so that the computing unit of the regional server 1 before that 13 is highly likely to be significantly inaccurate in the prediction made at step 125 of the planning process 13a. Therefore, if the event notification command 325 and the performance data 335 are transmitted to the regional server 1 in such a case, the step 125 is executed again, the inaccuracy of the prediction is alleviated, and the equipment operation plan is accordingly appropriate. Become.

  In addition, when an event notification condition such as (e) is satisfied in a certain consumer, a failed energy device (for example, a generator) becomes unusable, so that the computing unit of the regional server 1 before that There is a high possibility that the equipment operation plan created by step 13 in step 125 of the plan process 13a will not be realized. Therefore, if the event notification command 325 and the performance data 335 are transmitted to the regional server 1 in such a case, the step 125 is executed again, and the equipment operation plan can be changed to one that is consistent with the user operation.

  After the execution time of step 342 in FIG. 8, the event is not triggered at the energy management terminal 5 until the time t4 arrives, the event notification command is not transmitted at the regional server 1, and the actual data request is also transmitted at the regional server 1. It is assumed that the setting change was not necessary. In this case, in the period after the execution time of step 342 and before the time point t4, the operation is the same as the period after the execution time of step 322 and before the time point t3.

  At time t4, a fixed time (for example, 30 minutes) has elapsed from the previous regular communication timing (time t2), and at the same time, the calculation unit 13 determines that it is the regular communication timing in step 105 of the planning process 13a. Proceed to step 115. Subsequent operations of the energy management system 100 are the actual data request 310, the actual data 315, the step 317, the equipment operation plan 320, and the step 322 in the explanation of the operation after the time t2 and before the time t3, respectively. This is the same as the request 345, the actual data 350, the step 352, the equipment operation plan 355, and the step 357.

  The above is the description of the example of FIG. In the example of FIG. 8, since all the counter values 522 are 1, the control unit 54 of the energy management terminals 5a to 5c has triggered an event only at the event notification condition in step 220 of the notification process 542. It is determined.

For example, it is assumed that the transition of the total power consumption detected by the energy supply and demand measurement process 541 of the computing unit 13 in a certain consumer is as shown by a solid line 70 in FIG. Then, at time t11, the counter value 522 is changed from 1 to 5 by the same operation as t1 described above,
It is assumed that the upper limit value 71 of the total power consumption in the installation destination consumer included in the event notification condition 521 is increased by the same operation as the above-described t1 at time t12. A black circle in the solid line 70 corresponds to the timing at which the presence / absence of event activation is determined in step 220 (that is, the timing at which it is determined whether the event notification condition is satisfied in step 220).

  In the example of FIG. 9, it was determined that the event was triggered every time the total power consumption 71 exceeded the upper limit value before the time t11, but after the counter value increased to 5 at the time t11, An event is triggered only when the total power consumption 71 exceeds the upper limit value five times in succession. Thus, by setting the counter value to 2 or more, the possibility that the event notification command based on the same event notification condition, the actual data transmission, and the process of step 125 in FIG. 4 are performed too frequently is reduced. The

  As described above, each of the energy management terminals 5a to 5c monitors the operating state of the energy devices 61a to 61c, 62a to 62c, and 63a to 63c in the installation destination house. Then, based on the fact that the energy device in the installation destination house is in a state that satisfies the event notification condition, the event notification command 325 and the energy supply / demand result data 335 by the energy device in the installation destination house are transmitted to the regional server 1. To do.

  Then, when the regional server 1 receives, from one of the energy management terminals 5a to 5c, the actual data 335 of energy supply and demand by the energy equipment of the house where the one energy management terminal is installed, the regional server 1 is based on the received actual data 335. Then, the device operation plan 340 of the house where the energy management terminals 5a to 5c (including the transmission source of the event notification command 325 and the result data 335) are installed is created and transmitted to the energy management terminals 5a to 5c.

  When each of the energy management terminals 5a to 5c receives the equipment operation plan 340 of the energy equipment of the installation destination house from the regional server 1, the energy management terminals 5a to 5c control the energy equipment of the installation destination house based on the received equipment operation plan 340. Do.

  As described above, each of the plurality of energy management terminals transmits the energy supply / demand record data to the server based on the transition of the operation state of the energy device in the installation destination home to the state set as the event notification condition. . Then, when the server receives the energy supply / demand record data, the server creates an operation plan of the energy equipment of the house where the plurality of energy management terminals are installed based on the received record data, and transmits the operation plan to the plurality of energy management terminals To do.

  In this way, since the case of transition to the state predetermined by the setting is selected, the actual energy supply / demand data is transmitted and the operation plan is created, so it is not necessary to transmit the energy supply / demand actual data too frequently. It is possible to select and send an operation plan when it is necessary. Therefore, in the technology that repeatedly receives energy usage information from each house and repeatedly creates an operation plan for energy equipment in each house based on the received information, the agile operation plan while suppressing an increase in server load Creation can be realized.

  The control unit 54 of the energy management terminals 5a to 5c executes step 220 of the energy supply / demand measurement process 541 and the notification process 542, thereby managing the threshold value of the energy supply / demand, and the energy supply / demand set. It functions as an energy supply and demand monitoring unit that monitors whether the measured value exceeds the threshold value (upper limit value and lower limit value). Moreover, the control part 54 functions as an event notification part which notifies the event which generate | occur | produced in the consumer with respect to the regional server 1 by performing step 230,240 of the notification process 542. FIG. The event notification command 325 and the result data 330 correspond to threshold excess information.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. The content of the second embodiment is largely the same as that of the first embodiment.

  As shown in FIG. 10, the energy management system according to this embodiment includes a regional server (or aggregator) and energy management terminals A, B, C,... Of consumers A, B, C,. It is the structure connected via.

  The regional server collects energy information of each customer and power generation facility (specifically, energy measurement values such as power consumption and power generation), and monitors the energy supply and demand situation. It has an energy supply and demand prediction unit that performs a supply and demand prediction calculation, and a plan calculation unit that calculates a device operation plan of each consumer.

  The energy management terminals A, B, C,... On the customer side are energy supply and demand measurement units that measure the energy supply and demand situation such as the power and heat quantity of the devices (for example, devices 1 to 3) installed in each consumer. Energy threshold management unit that manages energy supply and demand thresholds, energy supply and demand monitoring unit that monitors whether measured values exceed the set energy supply and demand thresholds (upper limit and lower limit), and demand for regional servers It has an event notification unit for notifying events that occur in the house.

  As shown in FIG. 11, the regional server includes local energy including consumers A, B, C,... Based on energy information and energy supply and demand status of each customer and power generation facility collected by the energy supply and demand monitoring unit. Supply / demand prediction calculation is performed to calculate (or recalculate) the equipment operation plan of each consumer. And based on the result of a calculation (or recalculation), an apparatus operation plan (target power consumption etc.) is distributed to the apparatus control part (a part of energy management terminal) of consumers A, B, C,.

  The device control unit controls devices (for example, devices 1 to 3) based on the received device operation plan.

  Moreover, as shown in FIG. 12, the regional server communicates with the energy threshold management unit of the energy management terminals A, B, C,... Of the consumers A, B, C,. Then, the upper and lower thresholds for energy supply and demand are set by transmitting event notification conditions. And each of energy management terminal A, B, C, ... memorize | stores the notification conditions of the received event.

  As shown in FIG. 11, the energy supply and demand monitoring unit of the energy management terminals A, B, C,... Constantly (or repeatedly periodically) monitor the energy measurement value and detect that the energy measurement value exceeds the threshold value. Notify threshold value information to the regional server (that is, notify the event). The regional server that has received this event notification recalculates the device operation plan of the event notification source consumer based on the received threshold excess information, and the recalculation result of the device operation plan of the event notification source customer. Delivered to the device control unit.

  Moreover, the operation state of the apparatus to acquire is set with respect to the energy threshold value management part of energy management terminal A, B, C, ... of consumer A, B, C, ... from a local server. Then, the energy supply / demand monitoring unit of the energy management terminals A, B, C,... Of the consumers A, B, C,... Constantly (or repeatedly) monitor the operation state of the device, and transition to the operation state in which the device is set. If it is detected, the threshold value excess information (that is, event notification) is notified to the regional server. The regional server that has received this event notification recalculates the device operation plan of the event notification source consumer based on the received threshold excess information, and the recalculation result of the device operation plan of the event notification source customer. Delivered to the device control unit.

(Other embodiments)
In addition, this invention is not limited to above-described embodiment, In the range described in the claim, it can change suitably. Further, the above embodiments are not irrelevant to each other, and can be combined as appropriate unless the combination is clearly impossible. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes. Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. Further, in each of the above embodiments, when referring to the shape, positional relationship, etc. of the component, etc., the shape, unless otherwise specified and in principle limited to a specific shape, positional relationship, etc. It is not limited to the positional relationship or the like. In addition, any part of the following modifications can be applied to the above embodiment (additional configuration).
Hereinafter, an additional configuration to the above embodiment will be described. In recent years, “demand response” is a method for optimizing energy such as electric power and heat used in the entire region. The definition of demand response is `` When the wholesale market price rises or the system reliability decreases, the power consumption pattern is changed so that the consumer side suppresses the use of electricity according to the setting of the electricity price or payment of incentives (* 1). In other words, the regional server that manages the energy of the entire region realizes energy savings for the entire region by changing the electricity rate so that it is high during peak demand during the daytime in summer, for example, and cheaper at night. However, it is a mechanism that smoothes power consumption. In order to realize this, it is indispensable to collaborate with consumers, such as Home Energy Management System (HEMS) and Building Energy Management System (BEMS). Therefore, as a HEMS that can respond to the energy optimization of the entire region, a mechanism that can cooperate with the regional server has been created.

  The types of demand response can be roughly divided into (1) those based on electricity charges such as hourly charges, and (2) those that are incentives such as supply-demand adjustment contracts (* 1). Electricity charges based on (1) are based on the demands at high loads when expensive charges are set at the customer's discretion, as electric utilities such as regional servers set electricity charges according to time of day. It is a mechanism that encourages shifts in demand at low loads where restrained and cheap rates are set. On the other hand, the incentive base in (2) is a mechanism that requests or implements load suppression / blocking when the wholesale power price rises or the supply and demand of electricity is tight.

In (2), two approaches are being conducted in Toyota City demonstration. One is an attempt to post the electricity unit price to the user and shift the usage of electricity at home and the way of living according to the electricity supply and demand, and the local server is verifying this demonstration. The other is a mechanism in which HEMS is linked to the setting of the unit power price of the regional server, and HEMS automatically controls Ecocute, stationary storage battery, etc., and corresponds to automatic demand response (ADR). This verification is verified as HEMS with a high learning function. As an effort to (2), a regional cooperative power control system has been constructed since 2012, and verification is ongoing. This regional cooperative power control system is equivalent to an event object called “Direct Load Control” defined in the international standard OpenADR, and is a system that controls energy devices remotely from a regional server according to the local power tightness situation. It is.

  In addition, we have established a mechanism that allows direct control from the local server using the stationary energy storage battery and the car (charging station) as the control target energy equipment, and has confirmed that the actual machine can request control of the local server.

  However, two issues remained. One is that the control logic on the controller side becomes complicated because different control constraints exist for each energy device. This problem was solved by unifying the control rules. Second, there was a risk of power outage exceeding the contracted amperage of the customer due to an increase in load due to direct control. For example, when the storage battery is charged, there is a possibility of a power failure because it flows in the direction of increasing load from the viewpoint of household load. In order to solve this, it is necessary to have a mechanism that monitors the power usage status of consumers in advance and does not exceed the contract amperage. Note that OpenADR is basically intended for load suppression, and thus no such case is mentioned. On the other hand, “Echonet Lite” defines an object “inf” that is notified to the controller when the state of the energy device changes. With reference to the concept of “Echonet Lite”, a mechanism (event notification function) for notifying the regional server when the state of the energy device in the HEMS changes is established.

  (* 1) “About demand response” (Source: Ministry of Economy, Trade and Industry).

  FIG. 13 shows the configuration of the entire system and the notification flow in the conventional regional cooperation control, and FIG. 14 shows the configuration of the entire new system and the notification flow. The major difference between a storage battery and a charging station, which are controlled by regional cooperation control, is the presence or absence of a HEMS timer controller.

  In the conventional HEMS, only a charging stand has a timer function, and a user can set one set of charging start time (hh: mm) and charging end (hh: mm). The date cannot be specified. Charging starts when the charging start time set by the user is reached, and ends when the charging end time is reached. On the other hand, there is no such thing as a timer function in a storage battery. Therefore, as a mechanism when the planned operation control is acquired from the regional server, it may be constructed as follows. Here, the PC-HEMS is a part of the HEMS, and is a computer mainly responsible for communication and data conversion functions among the functions of the HEMS, and can be realized by, for example, a personal computer. PC of PC-HEMS is an abbreviation for Personal Computer.

About storage battery:
(1) PC-HEMS holds the operation plan value acquired from the regional server (2) When the time to operate is reached based on the operation plan value held by the PC-HEMS, the PC-HEMS passes through the HEM and energy equipment Forcing control requests to the charging station:
(1) Hold the operation plan value acquired from the regional server by the PC-HEMS (2) Notify the operation plan value held by the timer control controller of the HEMS and reflect the operation plan acquired from the regional server at the timer time ( 3) When the time to operate is reached based on the timer function, HEMS makes a control request to the energy equipment. Since the timer function is a kind of planned operation, the charging station planning control uses this timer control. I decided to do it. Therefore, in the planned operation control of the charging station, there is still a limitation of the conventional timer function that the date can not be specified for only one set of “charge”-“stop” that can be maintained.

  Therefore, the charging station timer function was disabled for planned operation control from the local server, and it was rebuilt so that it would be exactly the same as the storage battery.

  In addition, the system of planned operation control by regional cooperation control was redefined with the following requirements.

Operation of PC-HEMS:
(1) Obtain an operation plan from a regional server and register it in a predetermined DB in the PC-HEMS. (2) Send a plan value control request to the HEMS forced control controller at the plan time.
(1) Invalidate charging station timer control during execution of regional cooperation control (2) Judgment of energy equipment during execution of regional cooperation control, except for fail-safe control of energy equipment (eg, refresh charging of storage battery) In addition, a mechanism has been established that can directly control energy devices in the HEMS from the regional server. However, one problem remained when introducing it to the demonstration house. That is, there is a possibility that the contracted amperage of the consumer may be exceeded due to an increase in the power load of the energy equipment by direct control.

  The target energy devices for regional cooperation control in this demonstration are storage batteries and cars, and each energy device can be charged, discharged, and stopped from the regional server. In this case, care must be taken when charging is performed. When charging is performed, the household load is urged to increase. If any energy device or both energy devices are charged, there is a possibility that the household load will be boosted and the amperage contracted by each house will be exceeded. According to the operation specifications of each energy device, the maximum charging power at the moment of the storage battery is 2000 W (maximum current 10 A), the maximum charging power at the moment of the vehicle is 2400 W (maximum current 12 A), and when combined, it is 4400 W (22 A). Since the contract ampere of Toyota City Demonstration House is 50A or 75A, only storage batteries and cars will occupy 30-45% of the contract ampere, which is problematic. Therefore, it is necessary for the local server side to constantly monitor the power demand situation of each house. However, at present, the period of providing performance information such as power demand from the HEMS to the regional server is a period of 30 minutes, and is not in a state where monitoring is always possible. Considering communication traffic, HEMS, and processing load of regional servers, it is difficult to reduce the frequency of providing performance information. Therefore, it is necessary to construct a mechanism that allows the regional server to constantly monitor so as not to cause a power outage in the house by regional cooperation control from the regional server.

  Another concern is that the operation plan held by the regional server may be different from the operation plan held by the HEMS. When the HEMS is in a mode in which the regional cooperation control can be performed, the HEMS invalidates the schedule operation that the energy device has conventionally and operates the energy device based on the plan distributed from the regional server. However, the plan may be changed on the HEMS side due to exceptional processing on the HEMS side (for example, maintenance of energy equipment). At present, the energy equipment plan information held by the HEMS is provided to the regional server at a cycle of 15 minutes, so there is a possibility that a mismatch of up to 15 minutes may occur between the regional server and the HEMS. Also, according to the service contents of the regional server, the energy equipment operation plan created by the regional server is to be posted to the user through the regional server photo frame at any time, so the plan on the HEMS screen and the regional server photo frame The plans are not consistent and the user may be confused. As described above, transmitting the plan information in a short cycle is not a realistic measure, and therefore a mechanism for notifying the regional server whenever the HEMS changes the operation plan is necessary.

  With OpenADR, which is an international standard for communication protocols between regional servers and customers, direct control of energy devices is a control aimed at “suppressing the customer's power load”. No mention is made of the case where the power load is increased by the control. On the other hand, in the “Echonet Lite” standardized in Japan for the communication protocol between the controller and the energy device, “Get” for acquiring the state of the energy device from the controller to the energy device, and from the controller to the energy device. “Set” for requesting control of the energy device, and “Inf” for notifying the controller of the state change of the energy device from the energy device to the controller are defined. By adopting this “Inf” concept and adopting a mechanism to notify the local server when the state in the HEMS changes and the power load exceeds a certain threshold and there is a risk of a power failure, Measures to prevent power outages, such as correction of the control plan, can be made.

Note that “Echonet Lite” is not a standard that assumes communication between the regional server and the HEMS, but the regional server is referred to as a “controller” because the control request is made from the regional server to the energy device via the HEMS. I think that there is no problem in adopting the concept of “Echonet Lite”. In addition, since the performance data provision method that has already been built is a mechanism to get from the regional server to the HEMS, and a mechanism to post the energy equipment control request from the regional server to the HEMS, “Echonet Lite” Equivalent communication is realized. However, from the viewpoint of the protocol, since the communication protocol was initially defined based on the JIPDEC common specification, it is difficult to introduce the protocol of “Echonet Lite”. Therefore, this time corresponds to “inf” of “Echonet Lite”. The event notification mechanism was newly defined in accordance with existing protocols, and a new event notification interface was devised.

Functional specifications:
A1: Approach to the problem The following two problems should be overcome.
Problem 1.
1. Construction of a system that allows regional servers to constantly monitor the power demand state of each house so that the house will not experience a power outage through regional cooperation control.
Construction of a system that can constantly grasp changes in the operation plan of residential energy equipment so that there is no discrepancy between the operation plan of residential energy equipment owned by the regional server and the operation plan owned by HEMS. Clarified the necessary information and examined solutions. Problem 1. Then, it is only necessary for the regional server to grasp whether the power consumption in the house, particularly the amount of power purchased from the grid, exceeds the contracted amperage by operating the storage battery or the charging stand. As a means for solving this problem, it is considered that the problem can be solved if the HEMS side has an arbitrary power threshold and can notify the local server as needed when the threshold is exceeded.

  Problem 2 Then, since the plan that the regional server is distributed can be grasped by the regional server, only the case where the operation plan is changed on the HEMS side is notified to the regional server, and the regional server side can grasp the change, The latest plan can be reflected in real time.

  Summarizing these issues, it is considered that various events in HEMS such as “power threshold exceeded” and “operation plan changed” can be solved in real time to the local server, and an event notification interface will be developed. did.

A2: Functional requirements The following requirements were defined as event notification functions.

Event notification (HEMS-> regional server):
-Notification of occurrence of threshold value An event occurrence notification is sent to the regional server when various threshold values set by the regional server are continuously exceeded the specified number of times (measurement per minute).
-Operation plan change notification When a change occurs in the operation plan on the PC-HEMS side, an event occurrence notification is sent from the HEMS to the regional server.
-PC-HEMS reset notification An event notification is sent from the PC-HEMS to the regional server at the time of recovery after the PC-HEMS is down.

Event setting (regional server → HEMS):
-The threshold value is set for the HEMS with respect to the threshold value and the applicable time zone from the condition setting area server. The HEMS performs threshold monitoring based on the threshold setting value.
The flow of the power threshold excess notification is as shown in FIG.

A3: Definition of communication sequence in event notification Communication between the regional server and HEMS, such as providing demonstration data from the HEMS to the regional server and regional cooperation control for controlling energy devices from the regional server to the HEMS, A communication infrastructure based on one-way communication from the server to the HEMS has been constructed. However, the event notification scheduled to be realized this time requires a mechanism for communicating from the HEMS to the regional server, and has to be extended to a platform capable of bidirectional communication. The considerations for extending the communication infrastructure are described below. Since the communication IF energy device having the role of a gateway controls communication between the home and the outside in the home, it was considered separately between the HEMS-communication IF energy device and the communication IF-regional server.

Communication between the communication IF energy device and the HEMS / SSL mutual authentication by SSL mutual communication The communication between the HEMS-communication IF energy device has already realized SSL mutual authentication communication in both directions. Therefore, the existing SSL communication is used between the HEMS and the communication IF energy device.
In the HAN (Home Area Network), communication is performed using an SSL certificate provided by a KDDI original certificate authority.

Communication between the regional server and the communication IF energy device / HTTP POST communication communication IF-communication between the regional server and the communication IF energy device by the combination of SSL authentication and Basic authentication is as described above. Although only SSL communication by authentication can be realized, it cannot cope with the reverse direction. From the viewpoint of restrictions on communication IF energy devices and simplification of client authentication mechanism on the local server side, a communication mechanism that combines SSL server authentication and Basic authentication was adopted.
The communication flow between the energy devices in the event notification is as shown in FIG. The communication sequence is as shown in FIG.

A4: Command definition Based on the functional requirements, an event setting command and an event notification command are newly defined.

[Event setting command]
There are one type of measurement value and determination condition used for threshold determination. However, as command specifications, a combination of a plurality of conditions using the “AND” and “OR” syntax and a plurality of measured values (information other than the purchased power) can be supported. Assume that a counter value (Count) until the event is triggered can be specified.

[Event notification command]
As for the event notification command of the threshold excess event, the event notification is performed when the threshold set in the designated time zone is exceeded a certain number of times. As notification contents, data corresponding to the number of times exceeding the threshold is transmitted. In this implementation, only the threshold for the grid power purchase is targeted. However, in consideration of future expandability, the command specification is a specification that can be used for each distribution board and each energy device.

  As for the event notification command of the operation plan event, when the operation plan of each energy device is updated by the PC-HEMS side, a list of operation plans is transmitted to the regional server. In this implementation, the target energy devices are only accumulators and electric vehicles. However, the command specification is applicable to various energy devices. This event is not transmitted when the operation plan is updated by post_target_data from the regional server side.

  The event notification command of the PC-HEMS reset event is used to notify an event when the PC-HEMS is restored after being down.

  The event setting command (region server → HEMS) is shown in FIGS. In addition, FIG. 22 to FIG. 24 show event notification commands (HEMS → regional server).

B: Power outage countermeasures against excess contract amperage on the HEMS side B1: By implementing the issue extraction event notification function, it is possible to correct the operation plan of energy equipment created on the local server side and prevent power outages in advance Became. However, due to the communication time lag between the energy devices, there remains a concern that real-time monitoring cannot be performed and an instantaneous response cannot be made. Therefore, it is necessary to monitor the power usage state in real time and control the energy equipment so as not to exceed the contracted amperage.

B2: Functional specification B2.1: Approach to the problem The problem of power failure countermeasures due to excessive contract amperage is to monitor the power usage state in real time and to control the energy equipment so as not to exceed it. The collection cycle of each energy device in the current system is as shown in FIG. In the event notification, the PC-HEMS determines that the threshold is exceeded from the actual power value collected from the HEMS in a cycle of 60 seconds, and notifies the regional server. On the other hand, since HEMS is collected every few seconds from the distribution board, it is desirable to constantly monitor the power usage status with HEMS and control the energy equipment as necessary.

  Therefore, (1) monitoring the power usage, and (2) forcing the energy equipment to be controlled when a certain threshold is exceeded, the “peak cut function” will be newly constructed as a new function of HEMS. .

B2.2: Functional requirements The following requirements were defined as the peak cut function.
-Charging of the car and the storage battery is stopped when the power used that can be obtained from the distribution board exceeds the threshold, and charging is restarted when it is determined that the power used is low and charging is possible.
The operation flow of the peak cut function is as shown in FIG. The cutting priority of energy devices was set to storage battery> car.

Claims (8)

Server (1),
A plurality of energy management terminals (5a to 5c) respectively provided in a plurality of houses (3a to 3c),
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. An event notification command is sent to the server based on the operational state,
When the server receives an event notification command from one of the plurality of energy management terminals, the server creates an operation plan of a home energy device in which the plurality of energy management terminals are installed, and sends the operation plan to the plurality of energy management terminals. Send
Each of the plurality of energy management terminal receives the operation plan of the energy equipment of the Site's house from the server, have row control of energy equipment of the Site house based on the received drive plan,
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. Based on the fact that it is in the operating state, the event notification command and the actual data of energy supply and demand by the energy equipment of the installation destination house are transmitted to the server,
When the server receives an event notification command and actual energy supply / demand data from the energy equipment of the installation destination house from one of the plurality of energy management terminals, the server, based on the received actual data, Create an operation plan of the energy equipment of the house where the energy management terminal is installed and send it to the plurality of energy management terminals,
Each of the plurality of energy management terminals monitors the hot water storage amount of the hot water storage device as the operating state of the energy equipment of the installation destination house, and based on the fact that the hot water storage amount is below the set lower limit value, The energy management system characterized by transmitting performance data of energy supply and demand by energy equipment in a house to the server . The server transmits an event setting command including an event notification condition to at least one of the plurality of energy management terminals,
When each of the at least one energy management terminal receives the event setting command from the server, the event notification condition included in the received event setting command is recorded as an event notification condition of an energy device in the installation destination house The energy management system according to claim 1 . Server (1),
A plurality of energy management terminals (5a to 5c) respectively provided in a plurality of houses (3a to 3c),
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. An event notification command is sent to the server based on the operational state,
When the server receives an event notification command from one of the plurality of energy management terminals, the server creates an operation plan of a home energy device in which the plurality of energy management terminals are installed, and sends the operation plan to the plurality of energy management terminals. Send
Each of the plurality of energy management terminal receives the operation plan of the energy equipment of the Site's house from the server, have row control of energy equipment of the Site house based on the received drive plan,
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. Based on the fact that it is in the operating state, the event notification command and the actual data of energy supply and demand by the energy equipment of the installation destination house are transmitted to the server,
When the server receives an event notification command and actual energy supply / demand data from the energy equipment of the installation destination house from one of the plurality of energy management terminals, the server, based on the received actual data, Create an operation plan of the energy equipment of the house where the energy management terminal is installed and send it to the plurality of energy management terminals,
The server transmits an event setting command including an event notification condition to at least one of the plurality of energy management terminals,
When each of the at least one energy management terminal receives the event setting command from the server, the event notification condition included in the received event setting command is recorded as an event notification condition of an energy device in the installation destination house An energy management system characterized by The server transmits an event setting command including an event notification condition and a counter value to at least one of the plurality of energy management terminals,
When each of the at least one energy management terminal receives the event setting command from the server, the event notification condition included in the received event setting command is recorded as an event notification condition of an energy device in the installation destination house And recording the counter value included in the received event setting command,
Each of the at least one energy management terminal monitors the operating state of the energy device in the installation destination home, and after the transition to the state where the energy device in the installation destination home is set as the event notification condition, When it is detected that the energy device in the house is in the state continuously for a number of times equal to or greater than the recorded counter value, the actual data on energy supply and demand by the energy device in the installation destination is transmitted to the server. The energy management system according to any one of claims 1 to 3 , wherein Server (1),
A plurality of energy management terminals (5a to 5c) respectively provided in a plurality of houses (3a to 3c),
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. An event notification command is sent to the server based on the operational state,
When the server receives an event notification command from one of the plurality of energy management terminals, the server creates an operation plan of a home energy device in which the plurality of energy management terminals are installed, and sends the operation plan to the plurality of energy management terminals. Send
Each of the plurality of energy management terminal receives the operation plan of the energy equipment of the Site's house from the server, have row control of energy equipment of the Site house based on the received drive plan,
Each of the plurality of energy management terminals monitors the operating state of the energy devices (61a to 61c, 62a to 62c, 63a to 63c) in the installation destination home, and the energy devices in the installation destination home satisfy the event notification condition. Based on the fact that it is in the operating state, the event notification command and the actual data of energy supply and demand by the energy equipment of the installation destination house are transmitted to the server,
When the server receives an event notification command and actual energy supply / demand data from the energy equipment of the installation destination house from one of the plurality of energy management terminals, the server, based on the received actual data, Create an operation plan of the energy equipment of the house where the energy management terminal is installed and send it to the plurality of energy management terminals,
The server transmits an event setting command including an event notification condition and a counter value to at least one of the plurality of energy management terminals,
When each of the at least one energy management terminal receives the event setting command from the server, the event notification condition included in the received event setting command is recorded as an event notification condition of an energy device in the installation destination house And recording the counter value included in the received event setting command,
Each of the at least one energy management terminal monitors the operating state of the energy device in the installation destination home, and after the transition to the state where the energy device in the installation destination home is set as the event notification condition, When it is detected that the energy device in the house is in the state continuously for a number of times equal to or greater than the recorded counter value, the actual data on energy supply and demand by the energy device in the installation destination is transmitted to the server. A featured energy management system. Each of the plurality of energy management terminals monitors the amount of energy supply and demand by the energy device of the installation home as the operating state of the energy device of the installation home, and the amount of energy supply and demand exceeds a set threshold on the basis that there installation destination home energy management system according to any one of claims 1 to 5 actual data of energy supply and demand by energy equipment and transmits to the server. Each of the plurality of energy management terminals monitors whether there is a failure in the energy equipment in the installation destination house as an operating state of the energy equipment in the installation destination house, and a failure has occurred in the energy equipment in the installation destination house The energy management system according to any one of claims 1 to 6 , characterized in that, based on energy equipment in an installation destination house, actual data on energy supply and demand is transmitted to the server. Each of the plurality of energy management terminals monitors the presence / absence of a user operation in the house with respect to the energy device in the installation destination house as the operating state of the energy equipment in the installation destination house, and based on the occurrence of the user operation The energy management system according to any one of claims 1 to 7 , wherein actual data on energy supply and demand by energy equipment in an installation destination house is transmitted to the server.

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