JP6281818B2 - Management system - Google Patents

Description

The present invention generally relates to the management system, and more particularly relates to the management system using the communication equipment having a communication function with an external device.

  2. Description of the Related Art Conventionally, there has been proposed a power cutoff device that stops power supply in the event of a disaster such as an earthquake (see, for example, Patent Document 1).

  The power shut-off device described in Patent Document 1 includes a seismic device that detects vibration and a control unit in a distribution board that includes a plurality of power shut-off switches. The control means cuts off only the power cut-off switch of the circuit in which a predetermined current value or more flows among the plurality of power cut-off switches when detecting the seismic vibration from the signal from the seismoscope. Further, in Patent Document 1, a display panel is provided in the distribution board to display whether the cause of power interruption is an earthquake, overcurrent, leakage, or neutral wire phase failure.

JP 2005-102498 A

  However, in the configuration described in Patent Document 1, after an earthquake occurs at the epicenter, the seismic vibration can be detected by the seismometer only after the main motion actually arrives. There is a possibility that the time required to cut off the supply of energy (for example, electric power) may become longer.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a management system that can shorten the time required to cut off the supply of energy to the consumer from the time of occurrence of an earthquake.

The management system of the present invention includes a first communication unit that communicates with an external device, a second communication unit that communicates with a meter device that measures the amount of energy used by a consumer, and the first communication. A communication device having a first control unit for transmitting a notification signal from the second communication unit to the meter device when the unit receives an earthquake early warning from the external device, and the meter device, The meter device is provided on the energy supply path to the consumer, and switches between a supply state for supplying the energy to the consumer and a shut-off state for blocking the supply of energy, and the notification A second control unit that controls the switching unit by the notification signal and a detection unit that detects the occurrence of an earthquake so that the switching unit is placed in the shut-off state when a signal is received; 2 control units When the shaking detected by the detecting unit after receiving the notification signal is less than a first seismic intensity, the switching unit is supplied when the predetermined return time has elapsed since the switching unit was switched to the shut-off state. It is configured to switch to a state.

  Since this invention has the 1st control part which transmits a notice signal to a meter device, when a communication device receives an emergency earthquake bulletin from an external device, supply of energy to a consumer from the occurrence of an earthquake There is an advantage that the time required to shut off can be shortened.

1 is a block diagram illustrating a schematic configuration of a management system according to a first embodiment. It is a block diagram which shows schematic structure of the electricity distribution panel which concerns on Embodiment 2. FIG. It is a block diagram which shows schematic structure of the apparatus control system which concerns on Embodiment 3. FIG.

(Embodiment 1)
As illustrated in FIG. 1, the communication device 1 according to the present embodiment includes a first communication unit 11, a second communication unit 12, and a first control unit 13.

  The first communication unit 11 communicates with the external device 2.

  The 2nd communication part 12 communicates with the meter apparatus 3 which measures the usage-amount of energy in a customer's facility.

  The first control unit 13 transmits a notification signal from the second communication unit 12 to the meter device 3 when the first communication unit 11 receives the earthquake early warning from the external device 2.

  The earthquake early warning here is a prediction / alarm of earthquake motion that is issued immediately after an earthquake by a specific organization such as the Japan Meteorological Agency. In other words, when an earthquake occurs, a specific organization such as the Japan Meteorological Agency analyzes the observation data captured by a seismometer close to the epicenter and immediately estimates the epicenter and magnitude of the earthquake (magnitude) based on this, and based on this, the main motion in each region The arrival time and seismic intensity are predicted, and an emergency earthquake bulletin is issued (notified). The earthquake early warning is transmitted to terminals such as a mobile phone terminal, a smartphone, a personal computer, and a radio receiver, and these terminals notify the user when the earthquake early warning is received. Users can know the predicted arrival time and seismic intensity immediately after the occurrence of the earthquake (ideally, before the arrival of the main movement), so use the time immediately after the occurrence of the earthquake appropriately. , Can reduce the damage.

  That is, the communication device 1 according to the present embodiment automatically transmits a notification signal to the meter device 3 when receiving an emergency earthquake warning from the external device 2. Therefore, when the meter device 3 is provided with a switch (switch) provided on a supply path of energy (in this case, electric power) to consumers as in a so-called smart meter, the switch of the meter device 3 is provided when an earthquake occurs. This can cut off the energy supply to consumers.

  Thereby, the communication apparatus 1 can interrupt | block the supply of energy to a consumer automatically at the time of an earthquake occurrence, and can improve safety | security compared with the case where electric power is supplied continuously. In other words, for example, even if a heating appliance falls due to an earthquake, for example, a secondary disaster can be prevented by automatically shutting off the supply of energy to the heating appliance.

  In addition, according to the present embodiment, the communication device 1 transmits the notification signal to the meter device 3 by using the earthquake early warning from the external device 2 as a trigger. Can receive the notification signal before the main motion arrives. Therefore, according to the communication apparatus 1 which concerns on this embodiment, there exists an advantage that the time required to interrupt | block the supply of energy to a consumer from the occurrence of an earthquake can be shortened.

  In the present embodiment, a management system including the communication device 1 and the meter device 3 will be described.

  The meter device 3 includes a switching unit 31 and a second control unit 32. The switching unit 31 is provided on the energy supply path to the consumer, and switches between a supply state for supplying energy to the consumer and a shut-off state for shutting off the supply of energy. The second control unit 32 controls the switching unit 31 by the notification signal so that the switching unit 31 is put into a blocking state when the notification signal is received.

  Hereinafter, the communication device 1 and the management system according to the present embodiment will be described in detail. However, the configuration described below is only an example of the present invention, and the present invention is not limited to the following embodiment, and the technical idea according to the present invention is not deviated from this embodiment. Various changes can be made in accordance with the design or the like as long as they are not.

  In the following embodiment, the case where the energy measured by the meter device 3 is electric power (electric energy) will be described as an example. However, energy is a resource supplied to consumers from an external supplier such as electric power, gas, water and heat, and is not limited to electric power. Moreover, although the case where an energy consumer is a detached house will be described below as an example, the present invention is not limited to this example, and the consumer may be, for example, each dwelling unit, office, store, factory, etc. of an apartment house. .

  First, the meter device 3 will be described.

  As shown in FIG. 1, the meter device 3 includes a switching unit 31, a second control unit 32, a measurement unit 33, a communication unit 34, a detection unit 35, and a storage unit 36.

  The meter device 3 is a so-called smart meter. The meter unit 3 measures the amount of power used by a consumer (the amount of power used) by the measuring unit 33 as the amount of energy used, and a concentrator (not shown) provided outside the consumer. To send). Thus, the meter device 3 enables remote meter reading by transmitting the meter reading value (measurement result of the measuring unit 33) from the communication unit 34 to the concentrator by communication.

  In addition, request information that is a request for suppressing power consumption from the power company that is an energy supply company or a server (not shown) that is operated by a power saving company to the meter device 3 of each consumer. Various information may be transmitted. The request information here is, for example, DR (demand response) information that requests adjustment of power supply and demand.

  More specifically, the measurement unit 33 is electrically connected to the power line 6 serving as a supply path of energy (here, power) from the power supplier to the consumer, and the amount of power used by the consumer is determined. It is an electric power meter (electric energy meter) to measure. Here, the meter device 3 includes a measurement unit 33 and other components (a switching unit 31, a second control unit 32, a communication unit 34, a detection unit 35, and a storage unit 36) in one housing (not shown). 2), it may have separate housings.

  The switching unit 31 is a switch (switch) provided on the power line 6 serving as a supply path of energy (here, electric power) from the supplier to the consumer. The switching unit 31 is configured to be able to switch between two states, a supply state and a cutoff state. In the supply state, the switching unit 31 supplies energy to the consumer by closing (turning on) the contact inserted in the power line 6. In the cut-off state, the switching unit 31 cuts off the supply of energy to the consumer by opening (turning off) the contact point inserted in the power line 6.

  The second control unit 32 controls the switching unit 31 according to the notification signal from the communication device 1 to switch between the supply state and the cutoff state. Specifically, when the notification signal is transmitted from the communication device 1 that has received the emergency earthquake warning to the meter device 3, the second control unit 32 determines that an earthquake has occurred and controls the switching unit 31 to be cut off. . On the other hand, when the meter device 3 does not receive the notification signal from the communication device 1, the second control unit 32 controls the switching unit 31 to the supply state.

  The communication unit 34 is configured to be able to communicate with the second communication unit 12 of the communication device 1 provided in the consumer. The communication unit 34 has a function of receiving at least a notification signal from the communication device 1. Further, the communication unit 34 is configured to be able to communicate with a display device (not shown) provided in the consumer via the communication device 1, and transmits a meter reading value and request information to the display device. It can be displayed on a display device.

  Further, the communication unit 34 is configured to be able to communicate with a concentrator or a server provided outside the consumer. Thereby, the meter apparatus 3 can transmit a meter-reading value to a concentrator as mentioned above (remote meter-reading), or can receive request information from a server.

  The detection unit 35 is configured by using an acceleration sensor (not shown), and is a seismic sensor that detects the magnitude (seismic intensity) of the shake based on the acceleration applied to the meter device 3. In other words, the detection unit 35 is configured to measure the magnitude of shaking when an earthquake occurs, and detects the occurrence of an earthquake by monitoring the magnitude of shaking of the meter device 3. However, what is detected by the detection unit 35 is not the vibration (initial fine movement) caused only by the P wave, but the main movement caused by the S wave and the surface wave.

  Here, as the acceleration sensor, for example, a small acceleration sensor using MEMS (Micro Electro Mechanical Systems) technology is used, so that the detection unit 35 is reduced in size and made into one chip. The detection unit 35 is configured to represent the magnitude of the detected shaking in, for example, 10 levels “level 1” to “level 10”, and output the detection result to the second control unit 32.

  By the way, in this embodiment, the 2nd control part 32 changes predetermined | prescribed after switching the switch part 31 to the interruption | blocking state, when the shake detected by the detection part 35 after receiving a notification signal is less than a 1st seismic intensity. When the return time elapses, the switching unit 31 is configured to switch to the supply state. That is, when the second control unit 32 receives the notification signal from the communication device 1, the second control unit 32 controls the switching unit 31 to be in a cut-off state, but then returns if the shaking detected by the detection unit 35 is less than the first seismic intensity. After a lapse of time, the switching unit 31 is returned to the supply state.

  Specifically, the second control unit 32 sets a period from when the switching unit 31 is switched to the shut-off state until the return time elapses, and the detection of the shaking detected by the detection unit 35 within the monitoring period. The magnitude (seismic intensity) is compared with the first seismic intensity stored in the storage unit 36. Then, the second control unit 32 maintains the switching unit 31 in the shut-off state when the magnitude of the shake detected by the detection unit 35 becomes equal to or greater than the first seismic intensity within the monitoring period, and the first seismic intensity. If not, the switching unit 31 is controlled to the supply state.

  The return time may be a fixed time, or may be a time dynamically determined reflecting the arrival time of the main motion. In the latter case, for example, in the case of the earthquake early warning, even though it is estimated that the main movement will arrive after 10 seconds, even if the detection unit 35 does not detect the shake even after the return time of 1 minute has passed, The second control unit 32 returns the switching unit 31 to the supply state.

  In addition, although the detection part 35 is incorporated in the housing | casing in which the measurement part 33 grade | etc., Was accommodated in this embodiment, you may be provided in the form externally attached to this housing | casing. When externally attached, the detection unit 35 is configured to perform a determination as to whether or not the shaking is less than the first seismic intensity, which is a part of the function of the second control unit 32 described above. That is, in this case, the detection unit 35 compares the detected magnitude of the shake with the first seismic intensity stored in the built-in memory (not shown), and determines that an earthquake has occurred if the seismic intensity is greater than or equal to the first seismic intensity. The externally attached detection unit 35 is electrically connected to an input terminal (not shown) provided on the housing. When an earthquake occurs, an internal contact (not shown) is turned on to electrically connect the input terminal. By short-circuiting, the detection result (earthquake occurrence) is output to the second control unit 32.

  The storage unit 36 stores the first seismic intensity described above in advance. The first seismic intensity is a threshold value for determining whether or not the second control unit 32 returns the switching unit 31 to the supply state as described above, and is the “level 1” to “level 10” described above. It is selected from the magnitudes of the 10 levels of shaking and is stored in advance in the storage unit 36 before the meter device 3 is shipped. However, the initial value of the first seismic intensity may be set by a user (a consumer's householder) and registered in the storage unit 36 after the meter device 3 is shipped.

  In the present embodiment, the meter device 3 includes a microcomputer (microcomputer), and realizes the function of the second control unit 32 by causing the microcomputer to execute an appropriate program. The program is stored in the storage unit 36, for example.

  Next, the communication device 1 according to the present embodiment will be described.

  As shown in FIG. 1, the communication device 1 according to the present embodiment includes a first communication unit 11 that communicates with the external device 2, a second communication unit 12 that communicates with the meter device 3, 1 control unit 13. Furthermore, in the example of FIG. 1, the communication apparatus 1 includes the third control unit 14, but the third control unit 14 will be described in the second embodiment.

  This communication apparatus 1 comprises the management system which concerns on this embodiment with the meter apparatus 3 mentioned above. The communication device 1 is arranged in the vicinity of the meter device 3 or in a predetermined position (for example, in the vicinity of a distribution board) in the consumer.

  The external device 2 may be any device that transmits an emergency earthquake bulletin to the communication device 1 when an earthquake occurs. In the present embodiment, the external device 2 is assumed to be a distribution server that distributes an emergency earthquake bulletin. However, the external device 2 is not limited to the distribution server, and is a device that receives an earthquake early warning from the distribution server and transfers it to the communication device 1, such as an information terminal such as a personal computer provided in the consumer and connected to the Internet. Also good.

  The first communication unit 11 is connected to the external device 2 via the Internet or a dedicated line, and is configured to be able to receive an emergency earthquake warning from the external device 2 at least when an emergency earthquake warning is issued. The communication method between the first communication unit 11 and the external device 2 is not particularly limited, and may be any of wired communication, wireless communication, or a communication method in which wired communication and wireless communication are mixed.

  The second communication unit 12 includes a meter device (smart meter) 3 provided on the power line 6 and a power line carrier communication (PLC) that transmits a communication signal using a communication path using the power line 6 as a transmission medium. Communication by Line Communications). However, the communication method between the second communication unit 12 and the meter device 3 is not limited to the power line carrier communication, and may be, for example, wireless communication. The wireless communication mentioned here includes systems such as a 920 MHz band specific low power radio, a 400 MHz band specific low power radio, Wi-Fi (registered trademark), and Bluetooth (registered trademark).

  In addition, when the 1st communication part 11 and the 2nd communication part 12 employ | adopt the same communication system, as these 1st communication part 11 and the 2nd communication part 12, one communication module is used. It may be done.

  The first control unit 13 receives the earthquake early warning from the external device 2 and transmits a notification signal to the meter device 3. Specifically, when the first communication unit 11 receives the earthquake early warning from the external device 2, the first control unit 13 estimates the contents of the earthquake early warning (the occurrence time of the earthquake, the epicenter, the magnitude of the earthquake). Area, where the estimated seismic intensity is more than the specified value, estimated arrival time of main motion in each area, etc.).

  Here, the communication device 1 stores in advance the area of the customer where the communication device 1 is provided as an installation region, and the first control unit 13 has an estimated seismic intensity as a specified value (for example, seismic intensity 4). It is determined whether or not the above warning area includes an installation area. When the installation area is included in the warning area, the first control unit 13 transmits a notification signal from the second communication unit 12 to the meter device 3. That is, if the warning area does not include an installation area, the first control unit 13 is not an emergency earthquake bulletin addressed to the communication device 1, so that the first earthquake control unit 13 does not receive the emergency earthquake bulletin signal. The notification signal is not transmitted.

  However, when the first communication unit 11 receives the earthquake early warning from the external device 2, the first control unit 13 notifies the meter device 3 of the notification signal regardless of the content (warning area, etc.) of the earthquake early warning. May be configured to transmit. In short, the content analysis of the earthquake early warning in the communication device 1 is not an essential configuration.

  Note that the communication device 1 includes a microcomputer, and realizes the function of the first control unit 13 by causing the microcomputer to execute an appropriate program. The program is stored in, for example, a built-in memory (not shown) of the microcomputer.

  In the present embodiment, as described above, when the meter device 3 receives the notification signal, the switching unit 31 is set to the cutoff state. Therefore, the communication device 1 transmits the notification signal to the meter device 3 to indirectly control the switching unit 31 of the meter device 3 so as to cut off the supply of energy to the consumer.

  By the way, it is preferable that the 1st control part 13 is comprised so that a predetermined | prescribed standby | waiting time may pass after the 1st communication part 11 received the earthquake early warning, and may transmit a notification signal. That is, the first control unit 13 does not immediately switch the switching unit 31 to the shut-off state when the emergency earthquake warning is delivered from the external device (server) 2, but after the standby time has elapsed from that point, the switching unit 31 A notification signal is transmitted so that 31 is switched to the cutoff state.

  Specifically, the standby time is set to about 10 seconds, for example. The first control unit 13 starts counting from the point in time when the earthquake early warning is distributed from the external device 2, and transmits a control signal for switching the switching unit 31 from the supply state to the cutoff state when the standby time has elapsed.

  In this configuration, it is possible to provide a time difference corresponding to the standby time from when the earthquake early warning is issued until the switching unit 31 is switched to the shut-off state. For this reason, for example, when an earthquake occurs at night, the power (energy) is not immediately cut off, and the user can have time for safety and evacuation.

  Further, the meter device 3 may be used instead of the communication device 1 to provide a time difference corresponding to the standby time from the emergency earthquake warning to the switching unit 31 being switched to the shut-off state. In this case, the communication device 1 transmits a notification signal immediately after receiving the earthquake early warning, and in the meter device 3, the switching unit 31 is shut off after the standby time elapses after the second control unit 32 receives the notification signal. Switch to state.

  According to the communication device 1 of the present embodiment described above, the first control unit 13 transmits a notification signal to the meter device 3 when receiving an emergency earthquake warning from the external device 2. And the meter apparatus 3 will switch the switch part 31 to the interruption | blocking state in the 2nd control part 32, if a notification signal is received. Therefore, the communication device 1 and the management system according to the present embodiment can automatically cut off the supply of energy such as electric power to consumers when an earthquake occurs, and improve safety compared to the case where energy is continuously supplied. Can do.

  In addition, according to the present embodiment, the communication device 1 transmits the notification signal to the meter device 3 by using the earthquake early warning from the external device 2 as a trigger. Can receive the notification signal before the main motion arrives. Therefore, the communication apparatus 1 can shorten the time required from the time of the occurrence of the earthquake to the interruption of the supply of energy to the consumer.

  Furthermore, the communication apparatus 1 interrupts energy supply using the switching part 31 provided in the meter apparatus 3 which measures the usage-amount of energy in a consumer. Therefore, by using a device originally provided with a switching unit (switch) 31 such as a smart meter as the meter device 3, the communication device 1 itself is not provided with a switching unit, and the energy of consumers to the customer when an earthquake occurs Supply can be cut off.

  Moreover, it is preferable that the meter apparatus 3 further has the detection part 35 which detects generation | occurrence | production of an earthquake like this embodiment. In this case, when the shaking detected by the detection unit 35 after receiving the notification signal is less than the first seismic intensity, the second control unit 32 switches the switching unit 31 to the shut-off state and then a predetermined return time has elapsed. Then, it is preferable to be configured to switch the switching unit 31 to the supply state.

  According to this configuration, for example, if the earthquake early warning is a false alarm, and if the detection unit 35 does not actually detect a shake greater than or equal to the first seismic intensity, the switching unit 31 after the return time has elapsed. Can be automatically returned to the supply state. Therefore, when the emergency earthquake warning is a false report, the energy supply is automatically restored after the return time has elapsed even if the supply of energy to the customer is interrupted.

  Further, the meter device 3 may use the notification signal received from the communication device 1 in addition to the control of the switching unit 31 as described above. For example, when the meter device 3 receives the notification signal, the meter device 3 may notify the server operated by the energy supplier through the same route as the remote meter reading. As a result, the supplier can grasp the area where the earthquake early warning is delivered, and the server collects information sent from the meter device 3 to collect local shaking information and perform maintenance, etc. Can be useful.

  In addition, even when energy is resources other than electric power, for example, gas, water supply, heat, etc., the structure similar to the said embodiment is applicable to a communication apparatus. For example, when the energy is gas, the meter device includes a gas meter as a measuring unit and a shut-off valve (valve) provided on a gas supply path as a switching unit. This meter device normally opens the shut-off valve to bring the switching unit into a supply state, and receives the notification signal, closes the shut-off valve and puts the switching unit into a shut-off state.

(Embodiment 2)
As shown in FIG. 2, the communication device 1 according to the present embodiment is different from the communication device 1 according to the first embodiment in that the communication device 1 is attached to a cabinet 43 of the distribution board 4. In this embodiment, energy is limited to electric energy (electric power). Hereinafter, the same configurations as those of the first embodiment are denoted by common reference numerals, and description thereof is omitted as appropriate.

  The distribution board 4 has a plurality of branch breakers 42 and 42 that branch the power into a plurality of electric circuits on the secondary side of the communication device 1 and the power supply path to the consumer and the secondary side of the main circuit breaker 41. ,... Are attached to the cabinet 43.

  As shown in FIG. 2, the cabinet 43 is formed in a box shape in which the front view is a horizontally long rectangular shape and the front surface is opened, and is used by being attached to a wall of a house. The cabinet 43 has a space for accommodating at least a main breaker 41 as an internal unit and a plurality of branch breakers 42, 42,. Here, the cabinet 43 is made of synthetic resin, and a lid (not shown) that can be opened and closed is attached to the front surface of the cabinet 43. The lid may be included in the cabinet 43 or may not be included in the cabinet 43.

  That is, the cabinet 43 of the distribution board 4 has a space for mounting various internal devices such as a breaker, a first space 431 in which the main breaker 41 is arranged, and a plurality of branch breakers 42, 42,. At least a second space 432 in which is disposed.

  The cabinet 43 of the distribution board 4 according to the present embodiment includes a third space 433 in addition to the first space 431 and the second space 432.

  The cabinet 43 of the distribution board 4 configured as described above has, as a minimum configuration, a main breaker 41 in the first space 431 and a plurality of branch breakers 42, 42,. The other third space 433 is an empty space provided for function expansion of the distribution board 4.

  Here, the minimum configuration as an internal unit of the distribution board 4 is a main breaker 41 attached to the first space 431 and a plurality of branch breakers 42, 42,... Attached to the second space 432. Further, the distribution board 4 according to the present embodiment is provided with various internal devices other than the main breaker 41 and the plurality of branch breakers 42, 42, ... by providing the cabinet 43 with the third space 433 as described above. Can be attached (retrofitted). In the present embodiment, the distribution board 4 includes the communication device 1 attached to at least the third space 433 as an internal unit, as shown in FIG.

  Below, the internal unit (the internal unit which can be attached to the cabinet 43) of the distribution board 4 is demonstrated.

  The main breaker 41 is electrically connected to a primary terminal (not shown) of a single-phase three-wire lead-in line of a system power supply (commercial power supply). On the secondary side of the main breaker 41, a conductive bar made of a conductive member that is long and long in the left-right direction is electrically connected. The main breaker 41 is configured to be switchable between an input state in which power from a system power source connected to the primary side is supplied to a conductive bar connected to the secondary side and an open state in which the supply of the power is cut off. Yes.

  The plurality of branch breakers 42, 42,... Are divided into an upper side and a lower side of a conductive bar (not shown) in the second space 432 of the cabinet 43, and a plurality of branch breakers 42, 42,. Yes. Each branch breaker 42 has a primary side terminal (not shown) and a secondary side terminal (not shown). The primary side terminal is electrically connected to the conductive bar, and the secondary side terminal includes Each of a plurality of electric circuits (not shown) is connected. Each branch breaker 42 is formed in a contracted dimension. Here, the agreement type dimension means a dimension (and shape) of a circuit breaker for a light distribution board in accordance with “JIS C 8201-2-1”.

  For example, one or more devices such as lighting fixtures and hot water supply facilities, outlets of plug connection devices, and wall fixtures such as wall switches are connected to the electric circuit connected to the secondary terminal of each branch breaker 42 as a load. And constitutes a branch circuit. In other words, each of the plurality of branch breakers 42, 42,... Has a branch circuit electrically connected thereto, and has an on state in which power from the main breaker 41 is supplied to each branch circuit and an open state in which the supply of power is cut off. It is configured to be switchable.

  Here, it is assumed that the communication device 1 communicates with the meter device 3 by power line carrier communication (PLC) that transmits a communication signal using a communication path using the power line 6 as a transmission medium. Therefore, the communication device 1 is electrically connected to the meter device 3 via the power line 6.

  Further, in the present embodiment, the cabinet 43 is attached with an interconnection breaker 44 provided on a power supply path from the distributed power source 7 to the consumer. Examples of the distributed power source 7 include a solar power generation device 71, a fuel cell 72, a storage battery (including a storage battery mounted on an electric vehicle) 73, and the like. As the interconnection breaker 44, there are a primary interconnection breaker 441 electrically connected to the primary side of the main breaker 41 and a secondary interconnection breaker 442 electrically connected to the secondary side of the main breaker 41. .

  That is, the cabinet 43 of the distribution board 4 is electrically connected to the primary side terminal of the main breaker 41 and is provided on the power supply path from the photovoltaic power generation device 71 as the distributed power source 7 to the customer. A breaker (interconnection breaker 44) 441 is attached. The primary interconnection breaker 441 is disposed in a fourth space 434 provided between the first space 431 and the third space 433 in the cabinet 43.

  In addition, the distribution board 4 is electrically connected to a conductive bar and is connected to a secondary grid breaker (link breaker 44) provided on a power supply path from a fuel cell 72 or a storage battery 73 as a distributed power source 7 to a consumer. ) 442 is attached. The secondary interconnection breaker 442 is arranged in the second space 432 of the cabinet 43 together with a plurality of branch breakers 42, 42,.

  By the way, when the communication device 1 transmits a notification signal from the second communication unit 12, the communication device 1 is configured to open at least one of the main breaker 41 and the plurality of branch breakers 42, 42,. It has the 3rd control part 14 (refer FIG. 1) which controls a breaker. Specifically, when the first communication unit 11 receives the earthquake early warning from the external device 2, the third control unit 14 transmits a control signal to the target breaker, thereby turning on the target breaker. , Switch the open state. That is, when the communication device 1 receives the earthquake early warning from the external device 2, the communication device 1 transmits a notification signal to the meter device 3 and transmits a control signal to the target breaker to open the target breaker.

  As the control signal transmission method and the control signal format, appropriate specifications according to the target breaker are used. In this embodiment, the 3rd control part 14 illustrates the case where the main breaker 41 which has an earth-leakage interruption | blocking function is made into an object breaker. The third control unit 14 is electrically connected to the main breaker 41 in the cabinet 43, and a pseudo-leakage signal is used as a control signal.

  As described above, in the distribution board 4 of the present embodiment, when the notification signal is transmitted to the meter device 3, the third control unit 14 provided in the communication device 1 has the main breaker 41 and the plurality of branch breakers. At least one of 42, 42,... Is opened as a target breaker. Thereby, the distribution board 4 which concerns on this embodiment can interrupt | block the supply of electric power to a consumer automatically at the time of the occurrence of an earthquake, and can improve safety compared with the case where electric power is continued to be supplied. That is, even if a heating appliance (electric heater or the like) falls due to an earthquake, for example, a secondary disaster can be prevented in advance by automatically shutting off the power supply to the heating appliance.

  In addition, the distribution board 4 uses a main breaker 41 or a plurality of branch breakers 42, 42,... That are generally attached to the cabinet 43 as a target breaker, and cuts off power supply. Therefore, the distribution board 4 can cut off the supply of power when an earthquake occurs without providing a dedicated circuit breaker. In particular, since the main breaker 41 is used as a target breaker in the present embodiment, the distribution board 4 can collectively block power supply to the entire customer by opening the target breaker when an earthquake occurs.

  Next, a first modification of the present embodiment will be described.

  In the first modification, the distribution board 4 is configured so that the third control unit 14 has only a part of the branch breakers 42 determined in advance among the main breaker 41 and the plurality of branch breakers 42, 42,. Is configured to be controlled as a target breaker. That is, in the first modified example, the target breakers are some of the predetermined branch breakers 42.

  In the first modification, the third control unit 14 is electrically connected to the branch breaker 42 as the target breaker in the cabinet 43, and transmits a control signal to the branch breaker 42, whereby the branch breaker 42. Switch between on state and open state.

  Here, the target breaker may be a part of the plurality of branch breakers 42, 42,... Provided in the distribution board 4, and is not limited to one branch breaker 42, but two or more branch breakers 42. , 42,... However, the third control unit 14 does not set all of the plurality of branch breakers 42, 42,... Provided in the distribution board 4 as target breakers, but sets only a part as target breakers and the rest as non-targets. Breaker.

  Here, the branch breaker 42 as the target breaker is selected from the plurality of branch breakers 42, 42,... Except for the branch breaker 42 to which communication infrastructure related facilities such as a telephone and a LAN (Local Area Network) are connected. It is preferable. In other words, it is preferable that the branch breaker 42 to which communication infrastructure-related equipment is connected is a non-target breaker. The device connected to the non-target breaker is not limited to the communication infrastructure-related equipment, and may be various devices such as medical devices for which continuous power supply is desired even when an earthquake occurs.

  As described above, in the distribution board 4 according to the first modification, the third control unit 14 has a predetermined part of the main breaker 41 and the plurality of branch breakers 42, 42,. Only the branch breaker 42 is controlled as a target breaker. According to this configuration, even when an earthquake occurs, the main circuit breaker 41 is not opened and the power supply of the entire consumer is not shut off, but only some branch breakers 42 are opened and some Only the power supply to the branch circuit is cut off. Therefore, by removing the branch breaker 42 to which a specific device (for example, communication infrastructure related equipment or medical device) is connected from the target breaker, the power supply to the specific device can be continued even in the event of an earthquake. .

  Next, a second modification of the present embodiment will be described.

  In the second modification, the distribution board 4 is combined with the target breaker so that the third control unit 14 opens the interconnection breaker 44 when a notification signal is transmitted from the second communication unit 12. The interconnection breaker 44 is configured to be controlled. That is, the third control unit 14 is configured to control the interconnection breaker 44 together with the target breaker when the first communication unit 11 receives the earthquake early warning from the external device 2.

  Specifically, the third control unit 14 outputs a control signal to the primary interconnection breaker (interconnection breaker 44) 441 when an earthquake occurs, and opens the primary interconnection breaker 441. That is, the third control unit 14 is configured to open the primary interconnection breaker 441 together when the communication device 1 receives the earthquake early warning and opens the main breaker 41 as the target breaker.

  Moreover, the 3rd control part 14 outputs a control signal also to the secondary interconnection breaker (interconnection breaker 44) 442 at the time of the occurrence of an earthquake, and opens the secondary interconnection breaker 442. That is, the third control unit 14 is configured to open the secondary interconnection breaker 442 together when the communication device 1 receives the earthquake early warning and opens the main breaker 41 as the target breaker. .

  As described above, in the distribution board 4 according to the second modified example, when the third control unit 14 transmits a notification signal from the second communication unit 12, the connection breaker 44 is opened. The interconnection breaker 44 is configured to be controlled together with the target breaker. According to this configuration, the distribution board 4 not only cuts off the power supply from the system power source to the customer at the main breaker 41 as the target breaker, but also at the distributed breaker 44 at the time of the occurrence of the earthquake. The power supply from 7 to customers can also be cut off.

  However, the interconnection breaker 44 is not the same cabinet 43 as the main breaker 41 and the plurality of branch breakers 42, 42,..., For example, a cabinet of an interconnection breaker box (not shown) arranged adjacent to the cabinet 43. It may be attached to. That is, when a connection breaker box is used for connection of the distributed power supply 7, the communication device 1 controls the connection breaker 44 of the connection breaker box.

  Note that the configuration according to the second modification can also be employed in combination with the configuration according to the first modification.

(Embodiment 3)
As shown in FIG. 3, the communication device 1 according to the present embodiment constructs a device control system 10 together with the device control device 5. Hereinafter, the same configurations as those of the first embodiment are denoted by common reference numerals, and description thereof is omitted as appropriate.

  A device control system 10 according to the present embodiment includes a communication device 1 and a device control device 5. The device control apparatus 5 communicates with the consumer device 51 and the communication device 1. The device control device 5 is configured to control the device 51 using the earthquake early warning.

  Specifically, the device control device 5 is installed in a consumer, and in addition to a communication function with the communication device 1, a HEMS (Home Energy Management System) that controls a plurality of devices 51, 51,. It has a function as a controller. Here, the device control device 5 communicates with the communication device 1 by wireless communication using radio waves as a transmission medium. However, the communication method between the device control device 5 and the communication device 1 is not limited to wireless communication, and may be either wired communication or a communication method in which wired communication and wireless communication are mixed.

  The plurality of devices 51, 51,... Here are HEMS compatible devices. The plurality of devices 51, 51,... Suffice as long as they are management targets of power consumption. including. Further, the plurality of devices 51, 51,... May include two other four large power consumption sources, a refrigerator, a television receiver, and the like. However, the device 51 is not intended to be limited to these devices.

  The device control device 5 has a function of visualizing (visualizing) the meter reading value of the meter device 3 by controlling the device 51 including a display device, and controlling the device 51 based on the meter reading value. According to this device control device 5, it becomes possible to manage the power consumption status of a plurality of devices 51, 51,..., And wasteful power consumption can be suppressed.

  Here, the device control device 5 has a function of receiving the earthquake early warning from the communication device 1 when an earthquake occurs and controlling a plurality of devices 51, 51,. That is, when the communication device 1 receives the earthquake early warning from the external device 2, the communication device 1 transfers the earthquake early warning to the device control device 5, and the device control device 5 uses the earthquake early warning to generate a plurality of HEMS-compatible devices 51. , 51,... Are controlled. At this time, the device control apparatus 5 may turn off the power of the device 51 or may be in a standby state without completely turning off the device 51. In addition, the device control device 5 may perform control other than stopping the operation of the device 51, such as opening an electric shutter or turning on a lighting fixture in response to the earthquake early warning.

  According to the device control system 10 of the present embodiment described above, the device control device 5 that communicates with the communication device 1 controls the plurality of devices 51, 51,. By doing so, the device 51 can be controlled based on the earthquake early warning. Therefore, the device control apparatus 5 can automatically control the device 51 when an earthquake occurs as described above.

  In the present embodiment, the (at least one) device 51 is a display device, and the device control device 5 is configured to display information based on the emergency earthquake warning on the device (display device) 51. It is preferable. The display device here may be a device having a display function, and is appropriately selected from a television receiver, an interphone master unit, a power monitor, and the like.

  That is, upon receiving the earthquake early warning, the device control device 5 receives the contents of the emergency earthquake early warning (the time of occurrence of the earthquake, the epicenter, the estimated value of the magnitude of the earthquake, the estimated seismic intensity greater than the prescribed value, Earthquake information representing the estimated arrival time of the main motion). And the apparatus control apparatus 5 controls the apparatus 51 which consists of display apparatuses so that the produced | generated earthquake information may be displayed.

  According to this configuration, information based on the earthquake early warning, such as the earthquake occurrence time, the epicenter, the estimated magnitude of the earthquake, the area where the estimated seismic intensity exceeds the specified value, the estimated arrival time of the main motion to each area, etc. Can be displayed on the device (display device) 51. Therefore, the user (customer's householder) can confirm the content of the emergency earthquake warning from the information displayed on the device 51 when the emergency earthquake warning is issued, and can respond quickly.

  Other configurations and functions are the same as those of the first embodiment. Note that the configuration according to the present embodiment can also be employed in combination with the configuration according to the second embodiment.

DESCRIPTION OF SYMBOLS 1 Communication apparatus 10 Apparatus control system 11 1st communication part 12 2nd communication part 13 1st control part 14 3rd control part 2 External device 3 Meter apparatus 31 Switching part 32 2nd control part 35 Detection part 4 Distribution board 41 Main breaker 42 Branch breaker 43 Cabinet 44 Interconnection breaker 441 Primary interconnection breaker 442 Secondary interconnection breaker 5 Device control device 51 Device 7 Distributed power supply 71 Solar power generation device 72 Fuel cell 73 Storage battery

Claims (1)

A first communication unit that communicates with an external device;
A second communication unit that communicates with a meter device that measures the amount of energy used by consumers;
If the first communication unit receives earthquake early warning from the external device, a first control unit and that communication device having a for transmitting a notification signal to said meter device from the second communication unit ,
Comprising the meter device,
The meter device is
A switching unit that is provided on the supply path of the energy to the consumer and switches between a supply state of supplying the energy to the consumer and a shut-off state of blocking the supply of energy;
A second control unit that controls the switching unit with the notification signal so that the switching unit is in the blocking state when the notification signal is received;
A detection unit for detecting the occurrence of an earthquake,
The second control unit, when the shaking detected by the detection unit after receiving the notification signal is less than the first seismic intensity, when a predetermined return time elapses after switching the switching unit to the blocking state. The switching unit is configured to switch to the supply state.
Management system.

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