JPWO2015019464A1 - Energy management system, controller, energy management method, and program - Google Patents

Abstract

In the energy management system, the transmission unit of the controller transmits a notification to the effect that the operation capability of the device is restricted and the device is operated every first predetermined time when the transition condition for shifting to the restricted operation is satisfied. The transmission part of a controller stops transmission of notification, when the cancellation | release conditions which cancel | release restriction | limiting operation | movement are satisfy | filled. The device operates with limited driving capability when a notification is received from the controller. In addition, when the device does not receive the notification again after the notification is received and before the second predetermined time elapses, the device operates by releasing the restriction.

Description

  The present invention relates to an energy management system, a controller, an energy management method, and a program for managing electric power in a house.

  There is a system for controlling electric power energy consumed in a house (inside a customer). For example, Patent Document 1 discloses a home energy management system (HEMS) that is provided in a consumer having a power supply means capable of independent operation and at least one load and controls the power supply means and the load.

  For example, Patent Document 1 discloses a system in which a schedule for independent operation is determined based on a period during which autonomous operation is performed, and the power supply status and load status of power supply means.

  Further, Patent Document 2 discloses a power distribution system that can immediately grasp the power usage state. Patent Document 2 discloses that the device is switched from the normal mode to the low consumption mode in accordance with the remaining amount of the battery.

JP 2012-228043 A JP 2008-048471 A

  In HEMS, the device which suppresses the power consumption by an apparatus is made | formed so that it can continue working for as long as possible at the time of a power failure. However, if a failure occurs in the communication network of the system during the operation of the device, the device cannot receive a new instruction from the command, and continues to operate according to the received instruction before the failure occurs. In particular, if a communication failure occurs after the device is restricted in the event of a power failure, the device will be restricted until the communication failure is resolved even if power reception from the commercial power supply is resumed. There is a problem that the convenience of the user is impaired.

  The present invention has been made in order to solve the above-described problems, and easily controls a device so that it can continue to operate for as long as possible at the time of a power outage without troublesome user's hand even if a communication failure occurs. The purpose is to provide an energy management system, a controller, an energy management method, and a program that can return the system to normal operation.

In order to solve the above problems, an energy management system according to the present invention is:
An energy management system comprising a controller and a device whose operation is instructed by the controller,
The controller transmits a notification to the effect that the operation capability of the device is restricted when the transition condition for shifting to the restricted operation is satisfied, to the device every first predetermined time, and releases the restricted operation. A transmission unit that stops transmission of the notification when a release condition to be satisfied is satisfied,
When the device receives the notification from the controller, the device operates with limited driving ability, and does not receive the notification again after the second predetermined time elapses after receiving the notification. Operates with the restriction removed.

  While controlling the device so that it can continue to operate for as long as possible at the time of a power failure, it is possible to easily return the device to normal operation without bothering the user even if a communication failure occurs.

It is a figure which shows the structure of an energy management system. It is a figure which shows the structure of a HEMS controller. It is a figure which shows the example of the definition data which defines the function restriction | limiting of an apparatus. It is a figure which shows the other example of the definition data which defines the function restriction | limiting of an apparatus. It is a figure which shows the other example of the definition data which defines the function restriction | limiting of an apparatus. It is a figure for demonstrating the function restriction | limiting in normal driving | operation, power saving driving | operation, and survival driving | operation. It is a figure for demonstrating the function restriction | limiting in normal driving | operation, power saving driving | operation, and survival driving | operation. It is a figure for demonstrating the function restriction | limiting in normal driving | operation, power saving driving | operation, and survival driving | operation. It is a flowchart for demonstrating apparatus control processing. It is a figure showing the notification conditions which transmit a survival notification. It is a flowchart for demonstrating apparatus control processing.

  Embodiments of the present invention will be described below.

  In FIG. 1, the structure of the energy management system 1 which concerns on this embodiment is shown. The energy management system 1 monitors the power consumption, state, and the like of various devices installed in a house (inside a customer) and controls the operation of various devices.

  The HEMS controller 100 controls the energy management system 1 as a whole. The HEMS controller 100 communicates with a device 160 installed in a home such as an air conditioner (described as 160A, 160B, 160C, 160D in FIG. 1) by wireless or wired, and acquires information indicating the state of the device 160. . For example, the HEMS controller 100 acquires information such as the temperature set for the air conditioner, the settings for cooling and heating, and whether the television receiver is turned on.

  Further, the HEMS controller 100 causes the device 160 to execute a predetermined process based on information indicating a state acquired from the device 160. For example, the HEMS controller 100 controls the device 160 according to an operation mode switched by the distribution board 140 in the power conditioner 110.

  There are two types of operation modes of the energy management system 1. One is a cooperative mode in which the power line 170 is connected to a commercial power source and receives power supply from the commercial power source. In the cooperation mode, in addition to power from the commercial power source, power generated by the power generation system 120 and power stored by the power storage system 130 can be supplied to the home. In the cooperation mode, the power generated by the power generation system 120 can be supplied to a commercial power source (sold to a power company or the like).

  The other is that the power line 170 is disconnected from the commercial power supply, and the power generated by the power generation system 120 and / or the power stored in the power storage system 130 is supplied to the house without receiving power supply from the commercial power supply. This is a self-supporting mode. In the self-supporting mode, the HEMS controller 100 limits the functions that can be used by the device 160 so that the user can use the device 160 and the like for as long as possible while suppressing the amount of power consumed by the entire energy management system 1. Details will be described later.

  Switching of the operation mode is performed by the distribution board 140 based on the measurement result indicating the supply state of power from the commercial power source. Typically, the linkage mode is set when the commercial power supply is not interrupted, and the self-sustained mode is set when a commercial power failure is detected.

  The power conditioner 110 includes a control unit 111, a DC / AC switching device (PCS) 112, and a bidirectional PCS 113.

  The control unit 111 controls charging and discharging by the PCS 112 and the bidirectional PCS 113.

  The PCS 112 converts a direct current generated by the power generation system 120 into an alternating current and supplies the alternating current to the power line 170.

  The bidirectional PCS 113 supplies the direct current generated by the power generation system 120 to the power storage system 130, or converts the alternating current supplied from the commercial power source into a direct current and supplies the direct current to the power storage system 130. In addition, the bidirectional PCS 113 converts the electric power stored in the power storage system 130 into an alternating current and supplies it to the power line 170.

  The power generation system 120 generates power by, for example, solar power generation. However, the power generation method is not limited by the present invention.

  The power storage system 130 stores the power generated by the power generation system 120 and the power supplied from a commercial power source. An electric vehicle can also be used as the power storage system 130.

  Distribution board 140 connects a commercial power source and power line 170 and includes a plurality of breakers. The commercial power source and the power line 170 can be connected or disconnected by opening and closing the main breaker. Moreover, the power line 170 is branched to each room in the house by a branch breaker connected to each branch circuit branched from the distribution board 140.

  The measuring unit 150 measures the amount of power consumed in the house and the amount of power generated by the power generation system 120.

  Next, the configuration of the HEMS controller 100 will be described with reference to FIG.

  The input unit 201 includes input devices such as a keyboard and buttons. The input unit 201 receives an instruction input from a user (system administrator).

  The display unit 202 includes a display device such as a display.

  The storage unit 203 includes a nonvolatile memory. The storage unit 203 stores various data such as a program executed by the control unit 205 and measurement values measured by the measurement unit 150.

  The communication unit 204 includes a NIC (Network Interface Card) and communicates with the device 160 and the measurement unit 150.

  The control unit 205 includes a CPU (Central Processing Unit), a ROM (Read Only Memory) that stores programs such as an operating system, a RAM (Random Access Memory) that serves as a work area, and the like. The control unit 205 executes the program stored in the storage unit 203 and controls the entire HEMS controller 100.

  As the HEMS controller 100, a general server, mainframe, personal computer, or the like can be adopted.

  Next, the configuration of the device 160 will be described.

  The device 160 is, for example, an air conditioner, lighting, a television receiver, an IH (Induction Heating) cooking heater, a refrigerator, or the like.

  The device 160 includes a CPU that controls the entire device 160 and a nonvolatile memory.

  In addition, the device 160 includes a communication module for communicating with the controller 100. The communication module may be built in the device 160 or may be externally attached via an expansion I / F.

  Next, device control processing performed by the HEMS controller 100 in the self-supporting mode will be described. When power transmission from the commercial power supply stops, the operation mode of the energy management system 1 is switched from the cooperation mode to the self-sustaining mode. In the self-supporting mode, the HEMS controller 100 controls the device 160 so as to reduce power consumption as much as possible so that power can be continuously supplied to the home device 160 and the like for a longer time.

  The operation mode of the device 160 includes a normal operation mode and a limited operation mode in which the operation capability is limited. Further, the limited operation mode includes a first limited operation mode (hereinafter referred to as “power saving operation mode”) and a second limited operation mode (hereinafter referred to as “survival operation mode”). One of the operation modes is selected by the HEMS controller 100.

  In the present embodiment, when the control unit 205 determines that a predetermined transition condition is satisfied, the control unit 205 selects the survival operation mode, and notifies the device 160 that the operation is performed in the survival operation mode (hereinafter referred to as “survival notification”). Send regularly to. Further, when determining that the predetermined release condition is satisfied, the control unit 205 selects the normal operation mode or the power saving mode, and stops the periodic transmission of the survival notification.

  In the present embodiment, when it is determined that the operation mode of the energy management system 1 has been changed from the cooperation mode to the self-sustained mode, the control unit 205 determines that the transition condition is satisfied and transmits a survival notification to the device 160. Moreover, the control part 205 discriminate | determines that cancellation | release conditions were satisfy | filled, when it determines with the operation mode of the energy management system 1 having been changed from the self-supporting mode to the cooperation mode.

  The transition condition and the cancellation condition are not limited to the above. For example, the control unit 205 may determine that the transfer condition is satisfied when the amount of power purchased from the commercial power source by the energy management system 1 is acquired and it is determined that the amount of power purchased is equal to or greater than a predetermined amount. In addition, the control unit 205 may determine that the release condition is satisfied when it is determined that the power purchase amount is less than a predetermined amount.

  In the normal operation mode, the range in which the device 160 can be executed among the driving capabilities of the device 160 is not limited, and the user can freely select and execute a function.

  In the power saving operation mode, the range in which the device 160 can be executed is limited in the driving capability of the device 160, and the user can use the device 160 within the range that falls within this limit. Note that the user can input an instruction to switch the normal operation mode to the power saving operation mode, and can input an instruction to switch the power saving operation mode to the normal operation mode.

  In the survival operation mode, a more severe limit is imposed on a range in which the device 160 can be executed among the driving capabilities of the device 160, and the user can use the device 160 within a range that falls within the strict limit. The user cannot input an instruction to switch the normal operation mode or the power saving operation mode to the survival operation mode, and only the HEMS controller 100 can instruct the device 160 to switch to the survival operation mode. Further, the user cannot input an instruction to switch from the survival operation mode to the normal operation mode or the power saving operation mode, and the survival operation mode is canceled only by the HEMS controller 100.

  The power saving operation mode can be arbitrarily switched by the user or the HEMS controller 100 when it is desired to save the electricity bill when it is not a power outage or when the power consumption amount is to be suppressed. On the other hand, unlike the power saving operation mode, the survival operation mode operates the energy management system 1 for as long as possible when it is necessary to rely on power generation by the power generation system 120 and / or power storage by the power storage system 130 due to a power failure. The purpose is to continue. Therefore, in the survival operation mode, the HEMS controller 100 narrows the driving ability of the device 160 to a minimum range necessary for the life of the user.

  FIG. 3A, FIG. 3B, and FIG. 3C show configuration examples of the definition data 300 that defines the limitation of the operation capability of the device 160 in each of the normal operation mode, the power saving operation mode, and the survival operation mode.

  FIG. 3A is a diagram illustrating functional limitations when the device 160 is a lighting device. In the normal operation mode, the driving ability is not limited, and the user can freely set the brightness from 0% (lights off) to 100%.

  In the power saving operation mode, the brightness can be set from 0% to 70%. The user can set the brightness to 70% of the maximum output.

  In the survival operation mode, the brightness can be set from 0% to 50%. The user can set the brightness to 50% of the maximum output. The user cannot set the brightness exceeding 50% until the survival operation mode is canceled by the HEMS controller 100.

  FIG. 3B represents the limitation of the driving capability when the device 160 is a refrigerator-freezer. In the normal operation mode, the operating capacity is not limited, and the temperature is maintained within a specified range in both the refrigerator and the freezer.

  In the power saving operation mode, the refrigerator and the refrigerator can set the set temperature only to a weak one of two levels of strong and weak.

  In the survival operation mode, the refrigerator can set the set temperature only to a weak one of the two levels of strong and weak, and the freezer is stopped.

  FIG. 3C represents the limitation of the driving capability when the device 160 is an air conditioner. In the normal operation mode, there is no limit on the driving ability.

  In the power saving operation mode, the user can set the set temperature only to 28 degrees Celsius or lower for cooling, and can set the set temperature only to 20 degrees Celsius or higher for heating. There is no limit to the operation of air blowing.

  In the survival operation mode, the cooling and heating operations are prohibited, and the device 160 can execute only the blowing operation.

  Here, although the limitation regarding the driving capability of the device 160 has been described using the lighting device, the air conditioner, and the refrigerator-freezer as examples, the types of the devices 160 that can limit the driving capability are not limited thereto. Further, the detailed contents of the limitation of the driving ability in the normal operation mode, the power saving operation mode, and the survival operation mode are not limited to the contents shown in FIGS. 3A, 3B, and 3C.

  The definition data 300 shown in FIGS. 3A, 3B, and 3C is stored in advance in the storage unit 203 of the HEMS controller 100.

  Not only the HEMS controller 100 but also the device 160 may store this definition data. When there are a plurality of devices 160 in the energy management system 1, it is not necessary for each device 160 to store definition data for all the devices 160, and at least store definition data that defines restrictions on the driving ability of the devices 160 themselves. If you do.

  FIGS. 4A, 4B, and 4C schematically show the interrelationships of the range of operation capability in the normal operation mode, the power saving operation mode, and the survival operation mode.

  The range of the driving ability in the power saving operation mode is only a part of the range of the driving ability in the normal operation mode. Furthermore, the range of the driving ability in the survival operation mode is only a part of the range of the driving ability in the power saving operation mode.

  In other words, the parameter ranges that can be set by the control unit 205 in the survival operation mode are all included in the parameter ranges that can be set by the control unit 205 in the power saving operation mode. Further, the parameter ranges that can be set by the control unit 205 in the power saving operation mode are all included in the parameter ranges that can be set by the control unit 205 in the normal operation mode.

  For example, as shown in FIG. 4A corresponding to FIG. 3A, the parameter that can be set by the lighting device is the brightness of the lighting. The range 412 in which the lighting device can be set in the power saving operation mode is all included in the range 411 in which the lighting device can be set in the normal operation mode. Further, the range 413 in which the lighting device can be set in the survival operation mode is all included in the range 412 in which the lighting device can be set in the power saving operation mode.

  Moreover, as shown in FIG. 4B corresponding to FIG. 3B, there are two parameters that can be set in the refrigerator-freezer: strength of the refrigeration temperature and on / off of the refrigeration. The range 422 in which the refrigerator-freezer can be set in the power saving operation mode is all included in the range 421 in which the refrigerator-freezer can be set in the normal operation mode. Further, the range 423 in which the refrigerator-freezer can be set in the survival operation mode is included in the range 422 in which the refrigerator-freezer can be set in the power saving operation mode.

  Further, as shown in FIG. 4C corresponding to FIG. 3C, there are three parameters that can be set by the air conditioner: a set temperature for cooling, a set temperature for heating, and on / off of blowing. The range 432 in which the air conditioner can be set in the power saving operation mode is all included in the range 431 in which the air conditioner can be set in the normal operation mode. The range 433 in which the air conditioner can be set in the survival operation mode is all included in the range 432 in which the air conditioner can be set in the power saving operation mode.

  Therefore, switching from the normal operation mode to the power saving operation mode means that the parameter range that can be set by the device 160 is changed from the range 411, 421, 431 to the range 412, 422, 432, which is narrower than the range 411, 421, 431. Means to be reduced. In addition, switching from the power saving operation mode to the survival operation mode means that the parameter range that can be set by the device 160 is from the range 412, 422, 432 to the range 413, 423, 433 that is narrower than the range 412, 422, 432. It means that it is reduced.

  The control unit 205 can switch from normal operation to power saving operation or from power saving operation to normal operation based on an instruction from the user. In addition, the control unit 205 can switch from normal operation to power saving operation or from power saving operation to normal operation according to, for example, the power consumption.

  Further, the control unit 205 changes from the normal operation mode (or power saving operation mode) to the survival operation mode or from the survival operation mode to normal operation mode (or the power saving operation) according to the change of the operation mode of the energy management system 1. Mode).

  The user can instruct switching from the normal operation mode to the power saving operation mode, or from the power saving operation mode to the normal operation mode, but from the normal operation mode (or the power saving operation mode) to the survival operation mode, Alternatively, it is impossible to instruct switching from the survival operation mode to the normal operation mode (or the power saving operation mode).

  When the control unit 205 of the HEMS controller 100 detects that the operation mode of the energy management system 1 is switched from the cooperation mode to the self-sustaining mode, it determines that the transition condition is satisfied. Then, the control unit 205 causes the device 160 to stop the normal operation mode and causes the device 160 to switch to the survival operation mode. When there are a plurality of devices 160 that can be controlled by the HEMS controller 100, the control unit 205 causes each of the plurality of devices 160 to stop the normal operation mode and switch to the survival operation mode.

  In the present embodiment, when the control unit 205 switches from the cooperation mode to the self-supporting mode, the control unit 205 determines that the transition condition is satisfied, and transmits a survival notification to the device 160 using an arbitrary message in the ECHONET protocol.

  The device 160 that has received the survival notification limits the driving ability based on the definition data illustrated in FIGS. 3A, 3B, and 3C. For example, the air conditioner stops the cooling and heating functions when receiving the survival notification. That is, when operating with cooling or heating, the air conditioner stops cooling or heating, and does not accept a cooling start instruction and a heating start instruction from the user.

  In addition, either or both of the HEMS controller 100 and the device 160 notify the user that switching from the normal operation mode to the survival operation mode or switching has been performed by displaying on the display and / or outputting sound from the speaker. May be.

  In addition, the device 160 does not have a communication module, or even if it has a communication module, it does not store definition data that defines a restriction in the survival operation mode. When there is a device 160 that cannot be used, the control unit 205 preferably prompts the user to turn off the device 160. This prompting is performed by displaying on a display and / or outputting sound from a speaker.

  By the way, in this embodiment, when operating the device 160 in the survival operation mode, the control unit 205 does not transmit the survival notification only once at the start of the survival operation mode, but during the period of operating in the survival operation mode, The survival notification is repeatedly transmitted to the device 160 at predetermined time intervals. When the control unit 205 cancels the survival operation mode of the device 160, the control unit 205 ends the transmission of the periodic survival notification to the device 160. The control unit 205 does not explicitly notify the device 160 that the survival operation mode is to be canceled.

  The length of the predetermined time is arbitrary, but is 10 seconds in the present embodiment. The unit representing the length of the predetermined time is not limited to “seconds”, and may be the number of occurrences of an interrupt function that is periodically executed, such as a vertical synchronization interrupt (VSYNC), for example.

  When the device 160 receives the survival notification while operating in the normal operation mode, the device 160 switches the operation mode from the normal operation mode to the survival operation mode. Similarly, when the device 160 receives the survival notification while operating in the power saving operation mode, the device 160 switches from the power saving operation mode to the survival operation mode.

  If the device 160 operating in the survival operation mode receives the survival notification again within a predetermined time, the device 160 continues in the survival operation mode.

  On the other hand, if the device 160 operating in the survival operation does not receive the survival notification again within a predetermined time, the device 160 stops the survival operation mode and starts the normal operation mode or the power saving operation mode.

  If the HEMS controller 100 and the device 160 transmit / receive a start notification for starting the survival operation mode only once at the start of the survival operation mode, and end the survival operation mode at the end of the survival operation mode. If the specification that the end notification is transmitted / received only once is adopted, when the end notification cannot be transmitted / received due to the failure of the communication module, the device 160 cannot cancel the survival operation mode until the failure of the communication module is corrected. However, if the HEMS controller 100 is configured to periodically transmit and receive the survival notification during the period in which the HEMS controller 100 operates in the survival operation mode as in the present embodiment, the device 160 cannot receive the survival notification due to a failure of the communication module. Even if the predetermined time has elapsed since the last survival notification was received, the survival operation can be automatically canceled. The same applies when a communication failure of the home LAN, a failure of the HEMS controller 100, or the like occurs in addition to the failure of the communication module.

  Next, device control processing performed by the energy management system 1 will be described using the flowchart of FIG. Here, it is assumed that the power reception from the commercial power supply is stopped (that is, a power failure) while the energy management system 1 is operating in the normal operation mode, and the normal operation mode is switched to the survival operation mode.

  The control unit 205 of the HEMS controller 100 periodically acquires the operation mode of the energy management system 1 from the power conditioner 110. The control unit 205 repeatedly inquires of the power conditioner 110 about the operation mode at predetermined time intervals, and the power conditioner 110 notifies the HEMS controller 100 of the operation mode in response to the inquiry. However, the power conditioner 110 may notify the HEMS controller 100 of the operation mode repeatedly at a predetermined time interval even if there is no inquiry from the HEMS controller 100.

  When there is no power failure, the power conditioner 110 operates the energy management system 1 in the cooperation mode (step S501). The control unit 205 of the HEMS controller 100 detects that the energy management system 1 is operating in the cooperation mode (step S502). The device 160 operates in the normal operation mode (step S503). Note that the control unit 205 of the HEMS controller 100 does not need to explicitly instruct the device 160 to operate in the normal operation mode.

  When the power conditioner 110 detects a power failure (step S504), the power conditioner 110 operates the energy management system 1 in the self-supporting mode (step S505).

  When the control unit 205 of the HEMS controller 100 detects that the energy management system 1 is operating in the independent mode (step S506), it determines that the transition condition is satisfied, resets the counter used for the timer, and starts counting. A setting process is performed (step S507), and a survival notification is transmitted to the device 160 (step S508).

  This timer times the time that has elapsed since the survival notification was sent. As described above, in the present embodiment, the control unit 205 repeatedly transmits a survival notification to the device 160 every predetermined time while the energy management system 1 is operating in the self-sustaining mode, but is set in step S507. The timer to be used is used to determine the next timing for transmitting a survival notification to the device 160.

  After transmitting the survival notification to the device 160, the control unit 205 determines, based on the timer, whether or not a first predetermined time has elapsed after transmitting the survival notification (step S509).

  If the first predetermined time has not elapsed (step S509; NO), the control unit 205 continues to count. When the first predetermined time has elapsed (step S509; YES), the control unit 205 detects based on the response from the power conditioner 110 that the energy management system 1 is operating in the cooperation mode. Is determined (step S511).

  When the cooperation mode is not detected, in other words, when power reception from the commercial power supply is still stopped (step S511; NO), the control unit 205 repeats the processes of steps S507, S508, S509, and S511. That is, when the first survival notification is transmitted to the device 160 and the first predetermined time has elapsed and the power is not yet received from the commercial power supply, the second survival notification is transmitted to the device 160.

  Similarly, if the control unit 205 determines that power reception from the commercial power source has not been resumed even after the first predetermined time has elapsed since the second survival notification was transmitted to the device 160, the third time A survival notification is transmitted to the device 160. When the control unit 205 determines that power reception from the commercial power source has not been resumed even after the first predetermined time has elapsed since the Nth (N is an integer equal to or greater than 1) survival notification is transmitted to the device 160. , The (N + 1) th survival notification is transmitted to the device 160.

  On the other hand, after the power reception from the commercial power supply is resumed and the power conditioner 110 sets the cooperation mode (step S510), when the control unit 205 detects the cooperation mode (step S511; YES), the control unit 205 cancels the release. It is determined that the condition is satisfied, and the process returns to step S502. The control unit 205 does not transmit a survival notification to the device 160.

  The device 160 that has received the survival notification in step S508 returns a response signal (ACK) to the survival notification to the HEMS controller 100, sets the device 160 to the survival operation mode (step S512), initializes the counter used for the timer, and counts it. Is started (step S513). In the survival operation mode, for example, the device 160 limits the brightness of the illumination to 50% or less based on the definition data shown in FIG. 3A and does not accept an instruction to set the brightness to exceed 50% from the user.

  Note that the timer set in step S507 is used only by the control unit 205 of the HEMS controller 100, and the timer set in step S512 is used only by the device 160, and these are not the same.

  Next, the device 160 determines whether or not a second predetermined time has elapsed after receiving the survival notification (step S514).

  The second predetermined time is longer than or equal to the first predetermined time.

  When the second predetermined time has not elapsed since the survival notification was received (step S514; NO), the device 160 continues counting and continues the survival operation mode.

  There is a possibility that the survival notification is received again after the second predetermined time elapses after receiving the survival notification. In this case, after receiving the survival notification again (step S508), the device 160 continues the survival operation mode (step S512), initializes the timer, and starts counting again (step S513).

  When the second predetermined time has elapsed after receiving the survival notification (step S514; YES), the device 160 cancels the survival operation (step S515) and returns to the normal operation (step S503).

  In other words, if the device 160 receives the survival notification again after the second predetermined time has elapsed after receiving the last survival notification, the device 160 continues to operate in the survival operation mode, but the last survival notification is sent. If the survival notification is not received again even after the second predetermined time has elapsed since the reception, even if there is no explicit instruction from the HEMS controller 100, the survival operation mode is canceled and the normal operation mode is restored. . Even if the device 160 cannot communicate with the HEMS controller 100 due to a communication failure or the like after switching to the survival operation mode, the device 160 can automatically cancel the survival operation mode without bothering the user.

  Note that when the control unit 205 of the HEMS controller 100 fails to transmit the survival notification to the device 160 due to a communication failure or the like, it is desirable to notify the user to turn off the power of the device 160. If there is no response signal (ACK) to the survival notification, the control unit 205 determines that the transmission of the survival notification has failed.

  As described above, according to the present embodiment, the energy management system 1 controls the device 160 so that it can continue to operate for as long as possible at the time of a power failure, and does not bother the user even if a communication failure occurs. The device 160 can be easily returned to the normal operation mode.

  If the device 160 does not receive the survival notification again after the second predetermined time has elapsed after switching from the normal operation mode to the survival operation mode, instead of directly changing from the survival operation mode to the normal operation mode. First, the survival operation mode may be changed to the power saving operation mode, and then the power saving operation mode may be changed to the normal operation mode after a predetermined return condition is satisfied. In this way, the temporary load concentration on the entire energy management system 1 can be prevented by releasing all the restrictions at once rather than all at once after the power failure.

  The return condition is, for example, “a third predetermined time has elapsed since the change from the survival operation mode to the power saving operation mode”. When canceling the survival operation mode, the device 160 operates in the power saving operation mode until the third predetermined time elapses, and operates in the normal operation mode after the third predetermined time elapses. The device 160 performs a trial operation in the power saving operation mode for a third predetermined time, and then sets the normal operation mode.

  The length of the third predetermined time is arbitrary, and may be different from the length of the first predetermined time and the length of the second predetermined time.

  The return condition may be “the user inputs an instruction to set the normal operation mode after changing from the survival operation mode to the power saving operation mode”. The device 160 performs a trial operation in the power saving operation mode until the user gives an instruction to set the normal operation mode, and sets the normal operation mode after receiving an instruction to set the normal operation mode from the user.

  The return condition may be different for each device 160. The length of the third predetermined time may be changed for each type of device 160.

  Further, depending on the device 160, it may be changed whether to directly change from the survival operation mode to the normal operation mode or from the survival operation mode to the normal operation mode through the power saving operation mode. For example, the refrigerator refrigerator may be changed directly from the survival operation mode to the normal operation mode, and the air conditioner may be changed from the survival operation mode to the power saving operation mode to the normal operation mode.

  In the present embodiment, the device control process is described when the survival notification is received while operating in the normal operation mode, but the flow of the device control process when the survival notification is received while operating in the power saving operation mode is the same. is there. If the device 160 does not receive the survival notification again after the last time the survival notification is received until the second predetermined time elapses, the device 160 cancels the survival operation mode and sets the power saving operation mode. Good.

  The present invention is not limited to the above-described embodiments, and various modifications and applications are possible. Moreover, it is also possible to freely combine the constituent elements of the above-described embodiments.

  The control unit 205 of the HEMS controller 100 does not transmit a survival notification to all of the plurality of devices 160 after detecting that the energy management system 1 has switched from the cooperation mode to the independent mode. The device 160 that transmits the survival notification may be separated from the device 160 that does not transmit the notification.

  FIG. 6 shows an example of notification conditions for transmitting a survival notification. The control unit 205 may not transmit the survival notification to all the devices 160 immediately after detecting the self-sustained mode, but may sequentially transmit the survival notification to the devices 160 after the notification condition is satisfied.

  FIG. 7 shows a modification of the flowchart of the device control process. The flowchart in FIG. 7 differs from the flowchart in FIG. 5 in that step S707 is added. Steps S701 to S706 in FIG. 7 are the same as steps S501 to S506 in FIG. Steps S708 to S716 in FIG. 7 are the same as steps S507 to S515 in FIG.

  In step S <b> 707, the control unit 205 determines whether the notification condition is satisfied based on the operation state of the device 160. When determining that the notification condition is not satisfied (step S707; NO), the control unit 205 waits until the notification condition is satisfied. On the other hand, when determining that the notification condition is satisfied (step S707; YES), the control unit 205 sets a timer (step S708), and transmits a survival notification to the device 160 (step S709).

  A specific operation of the device 160 when the process for determining the notification condition is added will be described taking a rice cooker, a refrigerator, and a refrigerator as examples.

  For example, when the rice cooker is switching from the cooperation mode to the self-sustaining mode while cooking rice, the control unit 205 postpones sending the survival notification to the rice cooker and does not send the survival notification until the rice cooking is over. And the control part 205 will transmit a survival notification to a rice cooker, and will operate | move by survival operation mode, after rice cooking is complete | finished and it becomes heat retention. As described above, the control unit 205 may delay the transmission of the survival notification according to the content of the process being executed by the device 160 when the self-supporting mode is detected.

  For example, when the refrigerator is in the cold state, the mode is switched from the cooperation mode to the self-sustained mode, and when the temperature in the refrigerator has not been cooled to a predetermined temperature, the control unit 205 delays the transmission of the survival notification, and the temperature in the refrigerator is Allow cooling to continue to the specified temperature. Thereafter, when the internal temperature reaches a predetermined temperature, the control unit 205 transmits a survival notification to the refrigerator and operates in the survival operation. Thereby, the inside of a warehouse can be kept near predetermined temperature for as long as possible.

  For example, when the freezer is in cold storage and switched from the cooperation mode to the independent mode, the control unit 205 first switches to the power saving operation mode, continues the power saving operation mode for a predetermined time, and transmits a survival notification. Grace. After the predetermined time has elapsed, the control unit 205 transmits a survival notification to the freezer and operates in the survival operation. Thereby, a margin can be provided so that the ice in the cabinet does not start to melt at once.

  The control unit 205 may select the device 160 that is the transmission target of the survival notification according to the amount of power generated by the power generation system 120 and / or the amount of power stored by the power storage system 130. For example, when the control unit 205 detects that the energy management system 1 is operating in the self-sustaining mode in step S706, the control unit 205 acquires the power generation amount by the power generation system 120 and the power storage amount by the power storage system 130, and the energy management system 1 Calculate the time that power can be supplied stably throughout. The control unit 205 selects one or more devices 160 that are the transmission destinations of the survival notification so that the time during which the calculated power can be supplied reaches the target time during which the operation can be continued in the independent mode. Then, the control unit 205 transmits a survival notification to the selected device 160 (step S709).

  The control unit 205 may generate advice including information indicating the time during which the calculated power can be supplied and display the advice on the display. Further, the control unit 205 may generate an advice for making the time for which power can be supplied as long as possible and display the advice on the display.

  In the present embodiment, the user cannot input an instruction to switch the normal operation mode or the power saving operation mode to the survival operation mode. However, the user may be able to input an instruction to switch the normal operation mode or the power saving operation mode to the survival operation mode. The control unit 205 may determine that the above-described transition condition is satisfied when an instruction to change from the normal operation mode to the power saving operation mode or the survival operation mode is received from the user.

  A program for operating a computer as all or part of the energy management system 1 is stored and distributed in a computer-readable recording medium such as a memory card, CD-ROM, DVD, or MO (Magneto Optical disk). Then, it may be installed in another computer and operated as the above-described means, or the above-described steps may be executed.

  Furthermore, the program may be stored in a disk device or the like included in a server device on the Internet, and may be downloaded onto a computer by being superimposed on a carrier wave, for example.

  Various embodiments and modifications can be made to the present invention without departing from the broad spirit and scope of the present invention. Further, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiments but by the claims. Various modifications within the scope of the claims and within the scope of the equivalent invention are considered to be within the scope of the present invention.

  As described above, according to the present invention, while controlling the device 160 so that it can continue to operate for as long as possible at the time of a power failure, the device 160 can be easily operated without troublesome users even if a communication failure occurs. You can return to driving.

  DESCRIPTION OF SYMBOLS 1 Energy management system, 100 HEMS controller, 110 Power conditioner, 111 Control unit, 112 PCS, 113 Two-way PCS, 120 Electric power generation system, 130 Power storage system, 140 Distribution board, 150 Measuring part, 160 Apparatus, 170 Power line, 201 Input unit 202 Display unit 203 Storage unit 204 Communication unit 205 Control unit 300 Definition data

In order to solve the above problems, an energy management system according to the present invention is:
An energy management system comprising a controller and a plurality of devices whose operations are instructed by the controller,
Wherein the controller sends between every first time defined a notification that operate to limit the operating capacity of the device when the shift condition to shift to the limited operation is pre-filled in the device, the A transmission unit that stops transmission of the notification when a release condition for releasing the restricted operation is satisfied,
The device, the notification the work by limiting the operating capacity when received from said controller, said notification until during the time the second predetermined from the reception of the notification has elapsed again If you do not receive it, it works by canceling the restriction .
The operation mode of the energy management system has a self-sustained mode in which power is supplied to the device from at least one of a power generation system and a power storage system that the energy management system has a power failure.
When the operation mode is the self-sustained mode, the transmission unit obtains from at least one of the amount of power generated by the power generation system and the amount of power stored by the power storage system, and the operation capability of the device. One or more devices are selected from the plurality of devices such that the available power supply time reaches the target operation time in the independent mode, and the notification is sent to the selected devices every first time Send .

Claims (12)

An energy management system comprising a controller and a device whose operation is instructed by the controller,
The controller transmits a notification to the effect that the operation capability of the device is restricted when the transition condition for shifting to the restricted operation is satisfied, to the device every first predetermined time, and releases the restricted operation. A transmission unit that stops transmission of the notification when a release condition to be satisfied is satisfied,
When the device receives the notification from the controller, the device operates with limited driving ability, and does not receive the notification again after the second predetermined time elapses after receiving the notification. Operates with the restriction removed,
Energy management system. The operation mode of the energy management system includes a cooperation mode in which at least one of a power generation system and a power storage system included in the energy management system and a commercial power source cooperate to supply power to the device, and the commercial power source has a power failure. And a self-supporting mode for supplying power to the device from at least one of the power generation system and the power storage system,
The controller further includes a determination unit that determines whether the operation mode is the cooperation mode or the independent mode,
The transition condition is satisfied when the determination unit determines that the operation mode is the independent mode,
The release condition is satisfied when the determination unit determines that the operation mode is the cooperation mode.
The energy management system according to claim 1. The operation mode of the device includes a normal operation mode in which the operation capability of the device is not limited, a first limited operation mode in which the operation capability of the device is limited and the restriction can be canceled by a user, and the device And a second limited operation mode in which the range of the driving capability is limited to be narrower than the range of the driving capability in the first limited operation mode, and the limitation cannot be canceled by the user,
The transmission unit changes the operation mode of the device from the normal operation mode to the second restricted operation mode, or changes the operation mode of the device from the first restricted operation mode to the second restricted operation mode. The notification is transmitted to the device every first predetermined time,
The energy management system according to claim 2. When the second predetermined time has elapsed since the notification was last received, the device changed from the second restricted operation mode to the first restricted operation mode, and changed to the first restricted operation mode. When a predetermined return condition is satisfied later, the first limited operation mode is changed to the normal operation mode.
The energy management system according to claim 3. The return condition is that a third predetermined time elapses after changing from the second restricted operation mode to the first restricted operation mode.
The energy management system according to claim 4. The return condition is that, after changing from the second restricted operation mode to the first restricted operation mode, an instruction to set the normal operation mode is input from the user.
The energy management system according to claim 4. When it is determined that the energy management system is operating in the self-sustained mode, the transmission unit transmits the notification to the device every first predetermined time after a predetermined notification condition is satisfied by the device. Send to
The energy management system according to any one of claims 1 to 6. The transmission unit selects one or more of the plurality of devices according to at least one of the amount of power generated by the power generation system and the amount of power stored by the power storage system, and selects the selected device. Sending the notification every first predetermined time;
The energy management system according to any one of claims 1 to 7. The controller further includes an acquisition unit that acquires the amount of power purchased to the commercial power source by the energy management system,
The transition condition is satisfied when a power purchase amount to the commercial power source by the energy management system is a predetermined amount or more,
The release condition is satisfied when the amount of electricity purchased to the commercial power source by the energy management system is less than the predetermined amount.
The energy management system according to claim 1. A controller for controlling the energy management system,
When a transition condition for shifting to the restricted operation is satisfied, a notification that the operation capability of the device included in the energy management system is restricted is transmitted to the device every predetermined time, and the restricted operation is released. A transmission unit that stops transmission of the notification when a release condition to be satisfied is satisfied,
Controller with. An energy management method in an energy management system,
When a transition condition for shifting to the restricted operation is satisfied, a notification that the operation capability of the device included in the energy management system is restricted is transmitted to the device every predetermined time, and the restricted operation is released. A transmission step of stopping transmission of the notification when a release condition to be satisfied is satisfied;
An energy management method comprising: A computer that controls the energy management system,
When a transition condition for shifting to the restricted operation is satisfied, a notification that the operation capability of the device included in the energy management system is restricted is transmitted to the device every predetermined time, and the restricted operation is released. A transmission unit that stops transmission of the notification when a release condition to be satisfied is satisfied,
Program to function as.

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