JP2019118196A - Blackout detection system - Google Patents

Abstract

To accurately and quickly detect a blackout for each power consumer.SOLUTION: A blackout detection system according to the present invention includes a plurality of electricity meters 101, 102, 103 which are set for respective power consumers 1, 2, 3 and which constitute a first communication network by being wirelessly connected, and a plurality of gas meters 201, 202, 203 which are set for the respective power consumers 1, 2, 3, which constitute a second communication network by being wirelessly connected, and which are driven by batteries. The gas meters 201, 202, 203 are associated with the electricity meters 101, 102, 103 on a one-on-one basis, regularly transmit radio signals to the corresponding electricity meters, and determine the blackout states of the power consumers 1, 2, 3 for which the corresponding electricity meters are set, on the basis of the response states of the corresponding electricity meters with respect to the radio signals.SELECTED DRAWING: Figure 1

Description

  BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a system for detecting a power failure of a power customer whose power is supplied by a distribution line.

  In recent years, smart grid or Advanced Metering Infrastructure (AMI) systems have a power failure detection function. In the power failure detection method in these systems, generally, the power meter operates for a fixed period of time with a built-in radio after power failure detection, and wirelessly notifies that a power failure has occurred. However, in this method, a battery or a capacitor for operating for a fixed time after a power failure needs to be mounted on a wireless device in the smart meter, which causes a problem that the cost of the smart meter increases.

JP, 2013-146115, A

  Patent Document 1 discloses a power failure detection system using information that the meter reading data can not be acquired. According to the power failure detection system of Patent Document 1, it is not necessary to mount a battery or a capacitor for operating even after a power failure in the wireless device of the smart meter. However, since the meter reading interval is generally as long as 15 minutes, 30 minutes or 1 hour, there is a problem that it takes time to detect a power failure. Also, when collecting meter reading data of multiple smart meters by multi-hop communication, it is not possible to collect meter reading data from another smart meter whose meter reading data should be collected by relaying the smart meter whose operation has stopped due to a power failure. Therefore, there is a problem that it is not possible to grasp whether or not a power failure has occurred in a power demander in which another smart meter is installed.

  SUMMARY OF THE INVENTION In view of the above problems, the present invention has an object of performing power failure detection accurately and quickly for each power consumer.

  The blackout detection system according to the present invention is a blackout detection system for detecting blackouts of a plurality of power consumers, which are installed in each power consumer and which constitute a first communication network by wireless connection; A plurality of battery-powered battery-powered meters installed in each power consumer and configuring a second communication network by wireless connection, a first upper network existing above the first communication network, and a second communication And a second upper network existing above the network, wherein each battery-powered meter is associated one-to-one with each power meter, and wireless signals are periodically transmitted to the corresponding power meter as a corresponding power meter. , And based on the response status of the corresponding power meter to the wireless signal, determine the power outage status of the power customer in which the corresponding power meter is installed, and the corresponding power meter When each battery operated meter determines that there is a power failure for the located power consumer, a notification of a power failure detection, which is information to that effect, is transmitted from the second communication network to the first upper network via the second upper network. Be done.

  In the blackout detection system of the present invention, blackout detection is performed by transmitting and receiving wireless signals between the power meter and the battery drive meter, so that blackout detection can be performed at high speed according to the transmission cycle of the wireless signal. Further, since the power failure detection system of the present invention performs power failure detection for each power consumer by means of each battery drive meter associated one-to-one with each power meter, accurate power failure detection can be performed.

FIG. 1 is an entire configuration diagram of a power failure detection system according to a first embodiment. FIG. 2 is a diagram showing a connection relationship between components of the power failure detection system of the first embodiment. It is a figure which shows the structure of an electric power meter and a gas meter. FIG. 2 is a diagram showing a connection relationship between components of the power failure detection system of the first embodiment when a power failure occurs. It is a figure which shows the sequence of a power failure detection process. It is a conceptual diagram of a pairing setting. It is a figure which shows the setting content of pairing. It is a figure which shows the protocol stack mounted in a power meter and a gas meter. FIG. 7 is an entire configuration diagram of a power failure detection system according to a second embodiment. FIG. 7 is a diagram showing a connection relationship between components of a power failure detection system according to a second embodiment. FIG. 7 is a diagram showing a connection relationship between components of the power failure detection system of the second embodiment when a power failure occurs. It is a figure which shows the sequence of the gas meter at the time of a power failure generation. It is a figure which shows the sequence of the gas meter at the time of a power failure non-generation. It is a conceptual diagram of a pairing setting. It is a figure which shows the setting content of pairing. FIG. 10 is an entire configuration diagram of a power failure detection system according to a third embodiment. It is a figure which shows the structure of the electric power meter of Embodiment 3. FIG. It is a figure which shows the sequence of a power failure detection process.

<A. Embodiment 1>
<A-1. Configuration>
FIG. 1 is an entire configuration diagram of a power failure detection system according to a first embodiment. The power failure detection system according to the first embodiment is a power failure detection system for power consumers 1, 2, and 3. The power transmitted through the high voltage line 21 is stepped down by the transformer 31 and then supplied to the power consumers 1, 2, 3 via the distribution lines 11a, 11b, 11c, 11d, 11e. Here, the number of power consumers is three, but this is only an example.

  The power failure detection system according to the first embodiment includes power meters 101, 102, 103, gas meters 201, 202, 203, concentrators 100, 200, a power network 104, and a gas network 204. FIG. 2 shows the connection between these components.

  The power meters 101, 102, and 103 are installed at power consumers 1, 2, and 3, respectively. The power meters 101, 102, and 103 are smart meters having a wireless communication function. As shown in FIG. 2, the power meters 101, 102, and 103 are wirelessly connected to each other in a line topology. That is, although wireless communication is possible between the power meters 102 and 103 and between the power meters 101 and 102, wireless communication is not possible between the power meters 101 and 103. The power meter 101 is wirelessly connected to the concentrator 100. Thus, the power meters 101, 102, and 103 constitute a first communication network by being wirelessly connected. The power meters 101, 102, and 103 are driven by the power supplied to the power consumers 1, 2, and 3, respectively. Therefore, when a power failure occurs in the power customers 1, 2, 3, the power meters 101, 102, 103 installed in the power customers 1, 2, 3 stop their operation.

  The concentrator 100 collects meter reading data of the power meters 101, 102, 103 by multi-hop communication by wireless communication with the power meter 101. That is, the meter reading data of the power meter 101 is directly transmitted from the power meter 101 to the concentrator 100. Meter reading data of the power meter 102 is transmitted from the power meter 102 to the concentrator 100 via the power meter 101. Meter reading data of the power meter 103 is transmitted from the power meter 103 to the concentrator 100 via the power meters 102 and 101 in order.

  The concentrator 100 is wirelessly connected to the power network 104. Generally, this connection uses an optical line or a mobile telephone line, but is not limited thereto. The power network 104 is a high level network of power meters to which a high level system of a power meter such as a meter reading server or a database is connected.

  Gas meters 201, 202 and 203 are installed at power consumers 1, 2 and 3, respectively. The gas meters 201, 202, and 203 are smart meters provided with a wireless communication function. The gas meters 201, 202, 203 are wirelessly connected to each other in a line topology. That is, although wireless communication is possible between the gas meters 202 and 203 and between the gas meters 201 and 202, wireless communication is not possible between the gas meters 201 and 203. The gas meter 201 is wirelessly connected to the concentrator 200. Thus, the gas meters 201, 202, and 203 form a second communication network by being wirelessly connected. Unlike the power meters 101, 102, and 103, the gas meters 201, 202, and 203 are battery-powered meters. Therefore, even if a power failure occurs in the power customers 1, 2, 3, the gas meters 201, 202, 203 installed in the power customers 1, 2, 3 can operate.

  The concentrator 200 collects meter reading data of the gas meters 201, 202, and 203 by multi-hop communication by wireless communication with the gas meter 201. That is, the meter reading data of the gas meter 201 is directly transmitted from the gas meter 201 to the concentrator 200. The meter reading data of the gas meter 202 is transmitted from the gas meter 202 to the concentrator 200 via the gas meter 201. The meter reading data of the gas meter 203 is transmitted from the gas meter 203 to the concentrator 200 via the gas meters 202 and 201 in order.

  The concentrator 200 is wirelessly connected to the gas network 204. Generally, this connection uses an optical line or a mobile telephone line, but is not limited thereto. The gas network 204 is an upper network of gas meters to which a host system of gas meters such as a meter reading server or database is connected.

  In the power failure detection system according to the first embodiment, the gas meter is an example of a battery-powered meter that can operate even during a power failure, and another battery-powered meter may be used.

  FIG. 3 shows the configurations of the power meter 101 and the gas meter 201 installed in the power consumer 1. The power meter 101 includes a wireless device 1010 and a main body 1011. The main body 1011 reads the power in the power consumer 1. The wireless device 1010 performs wireless communication with the concentrator 100 and the gas meter 201, and includes a meter communication unit 1012, a meter control unit 1013, a meter storage unit 1014, and a health check control unit 1015.

  The meter control unit 1013 performs various controls for wirelessly transmitting the meter reading data of the main body 1011 to the concentrator 100. The meter communication unit 1012 wirelessly transmits meter reading data of the main body 1011 to the concentrator 100. The meter storage unit 1014 stores various data necessary for wirelessly transmitting the meter reading data of the main body 1011 to the concentrator 100. The health check control unit 1015 receives a health check request (Health Check Request) from the gas meter 201, and transmits a health check response (Health Check Response) to the gas meter 201.

  The gas meter 201 includes a radio 2010 and a main body 2011. The main body 2011 performs gas measurement in the power consumer 1. The wireless device 2010 performs wireless communication with the concentrator 200 and the power meter 101, and the communication unit for meter 2012, the control unit for meter 2013, the storage unit for meter 2014, the communication unit for health check 2015, the control for health check And a storage unit 2017 for health check.

  The control unit for meter 2013 performs various controls for wirelessly transmitting the meter reading data of the main body 2011 to the concentrator 200. The meter communication unit 2012 wirelessly transmits the meter reading data of the main body 2011 to the concentrator 200. The meter storage unit 2014 stores various data required to wirelessly transmit meter reading data of the main body 2011 to the concentrator 200.

  The health check control unit 2016 performs various controls for performing a health check of the power meter 101. The health check communication unit 2015 transmits a health check request to the power meter 101 and receives a health check response from the power meter 101. The health check storage unit 2017 stores various data necessary for performing the health check.

<A-2. Operation>
When the distribution line 11d is disconnected, the power consumer 2 loses power. At the time of the power failure of the power customer 2, although the non-battery-powered power meter 102 can not operate, the battery-powered gas meter 202 can operate. Therefore, the power failure detection system according to the first embodiment detects a power failure of each of the power customers 1, 2, 3 using the gas meters 201, 202, 203 installed in each of the power customers 1, 2, 3. Therefore, in the power failure detection system according to the first embodiment, the gas meter and the power meter are paired for each power consumer.

  In FIG. 2, the power meter 101 and the gas meter 201 are both enclosed by a dotted line frame, which indicates that they are paired. The same applies to the power meter 102 and the gas meter 202, and the power meter 103 and the gas meter 203. Thus, the gas meters 201, 202, and 203 are associated with the power meters 101, 102, and 103 in a one-to-one correspondence. In the present specification, the power meters 101, 102, and 103 corresponding to the gas meters 201, 202, and 203 are also referred to as "corresponding power meters" of the gas meters 201, 202, and 203, respectively. Basically, such pairing is performed for each power consumer.

  As shown in FIG. 4, when the power consumer 2 loses power, communication between the power meter 102 and the power meter 101 becomes impossible. Therefore, the concentrator 100 can not collect meter reading data of the power meter 102 and the power meter 103. Therefore, in the prior art which detects a power failure using the meter reading data of an electric power meter, in such a case, it could not but judge whether the power consumer 3 had a power failure by estimation. On the other hand, in the power failure detection system according to the first embodiment, the power consumer 3 's power failure presence / absence is accurately determined by the method described below using the health check function of the gas meter.

  FIG. 5 shows the sequence of the power failure detection process in the power customer 2. The power meter 102 and the gas meter 202 are paired. The gas meter 202 transmits a health check request, which is a wireless signal, to the power meter 102, which is a corresponding power meter (step S101). When the power meter 102 receives the health check request, the power meter 102 transmits a health check response to the gas meter 202 (step S102). When the gas meter 202 receives the health check response from the power meter 102, the gas meter 202 confirms that the power meter 102 is in an energized state, that is, the power customer 2 does not have a power failure. Thus, the gas meter 202 determines the power failure status of the power customer 2 in which the power meter 102 is installed based on the response status of the health check request.

  Next, it is assumed that a power failure occurs in the power customer 2 (step S103). Thereafter, the gas meter 202 transmits a health check request to the power meter 102 (step S104). The gas meter 202 transmits a health check request to the power meter 102 at a beacon period T [s]. That is, the time interval from step S101 to step S104 is T [s]. Since the power consumer 2 has a power failure, the power meter 102 that operates by obtaining power from the power system is in an inoperable state. Therefore, the health check response from the power meter 102 to the gas meter 202 is not performed (step S105).

  Even so, although the gas meter 202 transmits a health check request to the power meter 102 at beacon period T [s], there is no health check response from the power meter 102 to the gas meter 202 during power outage of the power customer 2. The gas meter 202 transmits the Nth (N is an integer of 2 or more) health check request counted from the health check request in step S104 to the power meter 102 (step S106), and there is no health check response from the power meter 102 in response thereto. (Step S107). The gas meter 202 determines that the power consumer 2 has a power failure because there is no health check response from the power meter 102 continuously for N times. Here, N is referred to as a power failure detection frequency threshold. Thus, the gas meter 202 determines the power failure status of the power customer 2 in which the power meter 102 is installed based on the response status of the health check request. Then, the gas meter 202 transmits a power failure detection notification, which is information indicating that the power consumer 2 has a power failure, to the gas meter 201 (step S108). The power failure detection notification is transmitted from the gas meter 201 to the gas network 204 via the concentrator 200, and transmitted from the gas network 204 to the power network 104. Thus, the power network 104 recognizes that the power consumer 2 has a power failure.

  Since communication between the gas meter 202 and the power meter 102 is wireless communication, packets are lost at a certain probability. As a result, even if a power failure does not occur, the gas meter 202 may not receive the health check response from the power meter 102. However, as described above, since the gas meter 202 detects a power failure only for N consecutive non-responses of the health check, it is possible to prevent a packet loss from being erroneously detected as a power failure. The time required for power failure detection is determined by the transmission interval of the health check response and the power failure detection frequency threshold N. The transmission period of the health check response is equal to the beacon period T [s] of the health check request. The beacon period T [s] and the power failure detection frequency threshold N are set to appropriate values depending on the application of each system. For example, in the case of T = 5 [s] and N = 5, the time required for power failure detection is It is about T × N = 25 [s].

  According to the conventional technique for detecting a power failure using meter reading data, the time required to detect a power failure is determined by the meter reading interval, and the meter reading interval is generally 15 minutes, 30 minutes, 1 hour, or the like. According to the power failure detection system of the first embodiment, a power failure can be detected much faster than such a prior art.

  Although the power failure detection process in the power customer 2 has been described above, the same power failure detection process is performed in the other power customers 1 and 3. That is, if the power customer 3 has a power failure, the gas meter 203 does not continuously receive the health check response from the power meter 103 N times, so a power failure of the power customer 3 is detected, and a power failure detection notification is given by the gas meter 202. Notify The power failure information of the power customer 3 is notified from the gas meter 202 to the gas network 204 via the gas meter 201 and the concentrator 200, and is notified from the gas network 204 to the power network 104. Thereby, the gas network 204 recognizes that the power consumer 2 has a power failure. On the other hand, if the power customer 3 does not have a power failure, the gas meter 203 receives a health check response from the power meter 103, and thus does not perform a power failure detection notification. Therefore, the power network 104 can grasp the presence or absence of a power failure for each power consumer.

  Next, the pairing of the power meter and the gas meter will be described. FIG. 6 shows how the setting device 401 sets the pairing on the gas meter 201 by wireless communication with the gas meter 201. Such setting is performed, for example, when installing the gas meter 201 in the power consumer 1.

  FIG. 7 shows the setting contents of pairing. The setting contents include the wireless connection frequency with the power meter 101, the beacon cycle of the health check request to be transmitted to the power meter 101, the power failure detection frequency threshold for the power meter 101, MAC (Media Access Control) of the power meter 101 that is the other party. Contains the address The contents of these settings are stored in the non-volatile memory constituting the health check storage unit 2017 of the gas meter 201. Here, the pairing in the power consumer 1 has been described, but the pairing in the power consumers 2 and 3 is the same as this.

  FIG. 8 shows a protocol stack 1101 mounted on the power meter 101 and a protocol stack 1201 mounted on the gas meter 201. In the protocol stacks 1101 and 1202, RF-PHY (Physical) serving as a physical layer has a common specification. It is general that the protocol stacks 1101 and 1202 differ between the MAC (Media Access Control) layer, the NET (Network) layer, the SM (System Management) layer, and the APL (Application) layer, which are layers higher than that. Let the former be MAC-B, NET-B, SM-B, APL-B, and the latter be MAC-A, NET-A, SM-A, APL-A. However, since the gas meter 201 performs wireless communication with the power meter 101, the MAC layer of the protocol stack 1201 is equipped with MAC-B common to the protocol stack 1101 in addition to MAC-A.

  When the number of consecutive unresponsiveness of the health check from the power meter 101 to the gas meter 201 exceeds the power failure detection number threshold N, the MAC-B in the gas meter 201 notifies the SM-A, and the communication protocol of the gas meter 201 notifies the concentrator 200 Report a power failure.

  In the above description, power failure detection using a health check packet has been described. However, the health check packet is an example of a packet periodically transmitted from the gas meter to the power meter. Other periodically transmitted packets may be used instead of the health check packet.

<A-3. Effect>
The blackout detection system according to the first embodiment is a blackout detection system that detects blackouts of a plurality of power customers 1, 2, and 3. The power failure detection system is installed in each of the power customers 1, 2, 3 and includes a plurality of power meters 101, 102, 103, which constitute a first communication network by wireless connection, and the power customers 1, 2, 3, 2. Gas meters 201, 202, and 203, which are battery-powered battery-powered meters that are installed in a wireless network and that constitute a second communication network by wireless connection, and a first upper network existing above the first communication network. A power network 104 and a gas network 204 which is a second upper network existing above the second communication network. And each gas meter 201, 202, 203 is matched with each power meter 101, 102, 103 on a one-on-one basis, and wireless signals are periodically transmitted to the corresponding power meter which is the corresponding power meter 101, 102, 103. Based on the response status of the corresponding power meter with respect to the wireless signal, the power failure status of the power customers 1, 2 and 3 in which the corresponding power meter is installed is determined. Then, when each gas meter 201, 202, 203 determines that there is a power failure in the power consumer in which the corresponding power meter is installed, a power failure detection notification, which is information to that effect, is transmitted from the second communication network via the gas network 204. It is communicated to the power network 104. Therefore, according to the blackout detection system of the first embodiment, it is possible to accurately grasp the blackout situation of each power customer using the network constituted by the battery-powered meter.

  Further, in the power failure detection system according to the first embodiment, each of the gas meters 201, 202, and 203 does not respond to the wireless signal from the power meters 101, 102, and 103 which are the corresponding power meters continuously a predetermined number of times. The blackout of the power customers 1, 2, 3 where the power meters 101, 102, 103, which are the corresponding power meters, are installed is detected. Therefore, according to the power failure detection system of the first embodiment, it is possible to prevent a packet loss from being erroneously detected as a power failure.

  Further, in the power failure detection system according to the first embodiment, the wireless signal may be a health check packet. The transmission period of the health check packet is, for example, 5 seconds, which is shorter than the meter reading interval of the power meter. Therefore, according to the blackout detection system of the first embodiment, the blackout can be detected earlier than when the blackout detection is performed using the meter reading value of the electric power meter.

<B. Second Embodiment>
<B-1. Configuration>
FIG. 9 is an entire configuration diagram of a power failure detection system according to a second embodiment. In addition to the configuration of the power failure detection system according to the first embodiment, the power failure detection system according to the second embodiment includes HEMS (Home Energy Management System) devices 301, 302, and 303 installed in power consumers 1, 2 and 3, respectively. Is equipped. FIG. 10 shows the connection between the components of the power failure detection system according to the second embodiment. The HEMS devices 301, 302, and 303 are connected to the HEMS network 304, respectively.

  In FIG. 10, the power meter 101, the gas meter 201, and the HEMS device 301 are all surrounded by a dotted line frame, which indicates that they are paired. More precisely, the gas meter 201 is paired with both the power meter 101 and the HEMS device 301. Similarly, gas meter 202 is paired with both power meter 102 and HEMS instrument 302, and gas meter 203 is paired with both power meter 103 and HEMS instrument 303. Thus, each gas meter 201, 202, 203 is associated with each power meter 101, 102, 103 and each HEMS apparatus 301, 302, 302 in a one-to-one correspondence. In the present specification, the HEMS devices 301, 302, 302 corresponding to the gas meters 201, 202, 203 are also referred to as "corresponding HEMS devices" of the gas meters 201, 202, 203, respectively. Basically, such pairing is performed for each power consumer. The corresponding HEMS devices of the gas meters 201, 202, and 203 need to be set to the same power consumer as the corresponding power meter.

<B-2. Operation>
In the first embodiment, the gas meter 201 performs a health check on the power meter 101, which is a corresponding power meter. However, in the second embodiment, the gas meter 201 also applies to the HEMS device 301, which is a corresponding HEMS device, in addition to the power meter 101. Perform a health check. Then, the gas meter 201 determines the occurrence of a power failure in the power consumer 1 based on the health check response status of both the power meter 101 and the HEMS device 301. The gas meters 202 and 203 perform the same operation as the gas meter 201. As a result, blackout information with higher reliability than that of the first embodiment can be obtained.

  FIG. 11 shows the connection between the components of the power failure detection system of the second embodiment when the power consumer 2 fails. When the power consumer 2 loses power, communication between the power meter 102 and the power meter 101 is not possible. Also, the health check response can not be performed from the power meter 102 and the HEMS device 302 to the gas meter 202. On the other hand, in the power consumer 3 in which a power failure has not occurred, it is possible to perform a health check response from the power meter 103 and the HEMS device 303 to the gas meter 203.

  FIG. 12 shows the sequence of the gas meter 202 and the like when a power failure occurs. The power meter 102 and the HEMS device 302 are paired with the gas meter 202. The gas meter 202 transmits a health check request, which is a wireless signal, to the power meter 102 (step S201). When the power meter 102 receives the health check request from the gas meter 202, the power meter 102 transmits a health check response to the gas meter (step S202).

  Next, the gas meter 202 transmits a health check request, which is a wireless signal, to the HEMS device 302 (step S203). When the HEMS device 302 receives the health check request from the gas meter 202, the HEMS device 302 transmits a health check response to the gas meter 202 (step S204).

  Next, it is assumed that a power failure occurs in the power consumer 2 (step S205). Thereafter, the gas meter 202 transmits a health check request to the power meter 102 (step S206). The gas meter 202 transmits a health check request to the power meter 102 at a constant beacon period T [s]. That is, the time interval from step S201 to step S206 is T [s]. Since the power consumer 2 has a power failure, the power meter 102 that operates by obtaining power from the power system is in an inoperable state. Therefore, the health check response from the power meter 102 to the gas meter 202 is not performed (step S207).

  Next, the gas meter 202 transmits a health check request to the HEMS device 302 (step S208). The gas meter 202 transmits a health check request to the HEMS device 302 at a constant beacon period T [s]. That is, the time interval from step S203 to step S208 is T [s]. Since the power consumer 2 has a power failure, the power meter 102 that operates by obtaining power from the power system is in an inoperable state. Therefore, the health check response from the power meter 102 to the gas meter 202 is not performed (step S207).

  Nevertheless, the gas meter 202 repeatedly transmits the health check request to the power meter 102 and the HEMS device 302 at the beacon cycle T [s]. However, during the power failure of the power customer 2, there is no health check response from the power meter 102 and the HEMS device 302 to the gas meter 202. The gas meter 202 transmits the N-th (N is a power failure detection frequency threshold) health check request counted from the health check request in step S206 to the power meter 102 (step S210), and the health check response from the power meter 102 is It is assumed that there is no (step S211). After that, the gas meter 202 transmits the Nth (N is a power failure detection frequency threshold) health check request counted from the health check request in step S208 to the HEMS device 302 (step S212), and the health check from the HEMS device 302 corresponding thereto. It is assumed that there is no response (step S213).

  At this time, the gas meter 202 determines that the power consumer 2 has a power failure because there is no health check response from the power meter 102 and the HEMS device 302 continuously for N times, and the power failure is information to that effect. A detection notification is sent to the gas meter 201 (step S214). The power failure detection notification is transmitted from the gas meter 201 to the gas network 204 via the concentrator 200, and transmitted from the gas network 204 to the power network 104. Thus, the power network 104 recognizes that the power consumer 2 has a power failure.

  FIG. 13 shows the sequence of the gas meter 202 and the like when no power failure occurs. Steps S301 to S304 are the same as steps S201 to S204 in FIG. 12, and thus the description thereof is omitted here. In step S305, the gas meter 202 sends a health check request to the power meter. Here, although the power consumer 2 has not performed a power failure, it is assumed that the power meter 102 can not transmit a health check response to the gas meter 202 due to a packet loss or the like (step S306).

  Next, the gas meter 202 transmits a health check request to the HEMS device 302 (step S307). When receiving the health check request from the gas meter 202, the HEMS device 302 transmits a health check response to the gas meter 202 (step S308).

  Although the gas meter 202 repeatedly transmits the health check request to the power meter 102 at the beacon cycle T [s], the power meter 102 can not transmit the health check response to the gas meter 202 for reasons other than a power failure such as packet loss. . The gas meter 202 transmits the N-th (N is a power failure detection frequency threshold) health check request to the power meter 102 counting from the health check request in step S305 (step S309), and the health check from the power meter 102 also It is assumed that there is no response (step S310). Thereafter, the gas meter 202 transmits a health check request to the HEMS device 302 (step S311). When the HEMS device 302 receives the health check request from the gas meter 202, the HEMS device 302 transmits a health check response to the gas meter 202 (step S312).

  Here, the gas meter 202 has not received the health check response from the power meter 102 N consecutive times. On the other hand, the gas meter 202 receives a health check response from the HEMS device 302. Therefore, the gas meter 202 does not determine that the power consumer 2 has detected a power failure, and does not transmit a power failure detection notification to the gas meter 201. In the first embodiment, even if the health check response can not be received from the power meter 102 for reasons other than a power failure, such as packet loss, the power failure detection is performed if it continues N times. However, in the second embodiment, since the power failure detection is performed only when the health check response can not be received N times continuously from both the power meter 102 and the gas meter 202, the power failure detection can be performed more accurately.

  Next, pairing of the power meter and the HEMS device with the gas meter will be described. FIG. 14 shows how the setting device 401 performs setting of pairing with the gas meter 201 by wireless communication with the gas meter 201. Such setting is performed, for example, when installing the gas meter 201 in the power consumer 1.

  FIG. 15 shows the setting contents of pairing. The setting content includes the setting content for the power meter 101 and the setting content for the HEMS device 301, and includes the wireless connection frequency, the beacon period of the health check request, the power failure detection frequency threshold, and the MAC address of the pairing partner, respectively. . The contents of these settings are stored in the non-volatile memory constituting the health check storage unit 2017 of the gas meter 201. Here, the pairing in the power consumer 1 has been described, but the pairing in the power consumers 2 and 3 is the same as this.

<B-3. Effect>
The power failure detection system according to the second embodiment includes a plurality of HEMS devices 301, 302, and 303 installed in each of power consumers 1, 2, and 3, and the respective gas meters 201, 202, and 203, which are battery-powered meters, correspond to each other. HEMS devices 301, which correspond to the corresponding HEMS devices, correspond to HEMS devices 301, 302, 303 installed in the same power consumers 1, 2, 3 as the power meters 101, 102, 103 which are power meters. Wireless signals are periodically transmitted to the power meters 101, 102, and 103 that are the corresponding power meters 302 and 303, and the corresponding power meters are installed based on the response status of the corresponding power meter and the corresponding HEMS device to the wireless signal. It detects the power failure of the power consumers 1, 2 and 3. Therefore, for example, even if the gas meter 202 does not respond from the power meter 102 for reasons other than a power failure, if there is a response from the HEMS device 302, the power consumer 2 recognizes that no power failure has occurred. it can. As a result, when the power meter 102 can not respond to the wireless signal for reasons other than the power failure, it is possible to prevent the gas meter 202 from erroneously detecting the power failure.

  Further, in the power failure detection system according to the second embodiment, each of the gas meters 201, 202, 203 is a power meter 101, 102, 103 that is a corresponding power meter continuously for a predetermined number of times and a HEMS device 301 that is a corresponding HEMS device. , 302, 303 when there is no response to the wireless signal, it is determined that there is a power failure in the power demander in which the power meters 101, 102, 103, which are the corresponding power meters, are installed. For example, even if the gas meter 202 does not receive a response from the power meter 102 several times in a row for reasons other than a power failure, if there is a response from the HEMS device 302, the power consumer 2 recognizes that a power failure has not occurred. can do. As a result, when the power meter 102 can not respond to the wireless signal for reasons other than the power failure, it is possible to prevent the gas meter 202 from erroneously detecting the power failure.

<C. Third Embodiment>
<C-1. Configuration>
FIG. 16 is an entire configuration diagram of the power failure detection system according to the third embodiment. The power failure detection system of the third embodiment is provided with power meters 101A, 102A and 103A instead of the power meters 101, 102 and 103 in the power failure detection system of the first embodiment shown in FIG. FIG. 17 shows the configuration of the power meter 101A. Although the configuration of the power meter 101A is representatively shown in FIG. 17, the configurations of the power meters 102A and 103A are similar to this. The power meter 101A includes a wireless set 1010A and a main body 1011. The wireless device 1010A includes a capacitor 1016 in addition to the configuration of the wireless device 1010 of the power meter 101 according to the first and second embodiments.

  The power meter 101A of the third embodiment normally operates with the power of the power system supplied to the power consumer 1. However, when a power failure occurs in the power consumer 1, the power meter 101A operates for a fixed time by the power stored in the capacitor 1016. Assuming that the operating time of the capacitor 1016 of the power meter 101A is Tc [s], then Tc> T. Therefore, after a power failure of the power customer 1, the power meter 101A can receive a health check request from the gas meter 201 at least once, and can make a health check response thereto.

<C-2. Operation>
FIG. 18 shows the sequence of the gas meter 202 and the power meter 102A in the power consumer 2. In FIG. 18, the sequence in power consumer 2 will be representatively described, but the sequences in other power consumers 1 and 3 are the same.

  The gas meter 202 transmits a health check request to the power meter 102A at beacon period T (step S401). When the power meter 102A receives the health check request from the gas meter 202, it transmits a health check response to the gas meter 202 (step S402). Here, the power meter 102A includes information indicating the presence or absence of a power failure in the power customer 2 in the health check response. Information indicating the presence or absence of a power failure in the power consumer 2 can be included, for example, using a flag or the like in the health check response. Since no power failure has occurred in the power customer 2 at the time of step S402, the health check response in step S402 includes information indicating that no power failure has occurred in the power customer 2. Upon receiving the health check response from the power meter 102A, the gas meter 202 recognizes from the flag or the like that the power customer 2 has not experienced a power failure. Thus, the gas meter 202 determines the power failure status of the power customer 2 in which the power meter 102 is installed based on the response status of the health check request.

  Next, it is assumed that a power failure occurs in the power customer 2 (step S403). Thereafter, at the timing when the beacon period T has elapsed from step S401, the gas meter 202 transmits a health check request to the power meter 102A (step S404). The power meter 102A operates with a capacitor built in the radio for a time Tc [s] after a power failure occurs. When a health check request is received from the gas meter 202, a power failure occurs in the power customer 2 in response to the health check response. To the gas meter 202 including the power failure information which is information indicating that it is present (step S405).

  Upon receiving the health check response from the power meter 102A, the gas meter 202 recognizes from the flag or the like that the power customer 2 has a power failure. Then, a power failure detection notification, which is information indicating that the power customer 2 has a power failure, is transmitted to the gas meter 201 (step S406). The power failure detection notification is transmitted from the gas meter 201 to the gas network 204 via the concentrator 200, and transmitted from the gas network 204 to the power network 104. Thus, the power network 104 recognizes that the power consumer 2 has a power failure. Thus, the gas meter 202 determines the power failure status of the power customer 2 in which the power meter 102 is installed based on the response status of the health check request.

  Generally, multi-hop communication is used for wireless communication of a power meter. In order to transmit a power failure notification to the power network 104 by multi-hop communication, the radio of each power meter needs to operate for about one minute after the power failure. Therefore, each power meter radio must be equipped with a large capacity battery or capacitor. However, in the power failure detection system according to the third embodiment, each power meter may operate longer than the beacon cycle T of the health check after the power failure, since the wireless network of the battery powered battery meter is used. For example, if the beacon period T is 5 seconds, the power meter may operate with a capacitor for about 5 seconds to 10 seconds after a power failure. Therefore, the capacitance of the capacitor can be reduced. As a result, the cost of the power meter can be reduced, and power failure notification to the power network 104 can be reliably performed.

<C-3. Effect>
In the power failure detection system according to the third embodiment, each power meter 101, 102, 103 has a built-in capacitor, and when a power failure occurs in the power consumer in which each power meter 101, 102, 103 is installed, the transmission period of the wireless signal It operates with a capacitor for a longer time than before and includes power failure information which is information indicating that power consumers 1, 2 and 3 in which each power meter 101, 102 and 103 is installed has a power failure in the response wireless signal to the wireless signal. Each of the gas meters 201, 202, 203 is a power demander 1, 2,... With the corresponding power meter installed, when the response wireless signal from each power meter 101, 102, 103, which is the corresponding power meter, includes blackout information. It is judged that there is a power failure in 3). Therefore, in the blackout detection system of the third embodiment, blackout detection can be performed at high speed and accurately by transmitting and receiving radio signals once. In addition, since it is only necessary for the capacitors incorporated in each of the power meters 101, 102, and 103 to store power for operating for a longer time than the transmission period of the wireless signal, the power failure notification is transmitted to the power network 104 by multihop communication. It requires less capacity than in the case of Therefore, it is possible to reduce the cost of the power meters 101, 102, and 103.

  In the present invention, within the scope of the invention, each embodiment can be freely combined, or each embodiment can be appropriately modified or omitted.

  N power failure detection frequency threshold, T beacon period, 1, 2, 3 power demander, 11a, 11b, 11c, 11d, 11e distribution line, 21 high voltage line, 31 transformer, 100, 200 concentrator, 101, 101A, 102, 102A, 103, 103A power meter, 104 power network, 201, 202, 203, 204 gas network, 301, 302, 303 HEMS device, 304 HEMS network, 401 setter, 1010, 1010A, 2010 wireless set, 1011, 2011 main unit 1012, 2012 Meter communication unit, 1013, 2013 Meter control unit, 1014, 2014 Meter storage unit, 1015, 2016 Health check control unit, 1016 capacitor, 1101, 1201 protocol stack, 015 health check for the communication unit, 2017 health check for the storage unit.

Claims (6)

A blackout detection system for detecting blackouts of multiple power consumers, comprising:
A plurality of power meters installed in each of the power consumers and constituting a first communication network by wireless connection;
A plurality of battery-powered battery-powered meters installed at each of the power consumers and configuring a second communication network by wireless connection;
A first upper network existing above the first communication network;
A second upper network existing above the second communication network;
Each of the battery-powered meters is in a one-to-one correspondence with each of the power meters, and periodically transmits a wireless signal to a corresponding power meter that is the corresponding power meter, and the corresponding power meter for the wireless signal Based on the response status, determine the power outage status of the power consumer having the corresponding power meter installed,
When each of the battery powered meters determines that the power consumer having the corresponding power meter has a power failure, the power failure detection notification, which is information to that effect, determines the second upper network from the second communication network. Transmitted to the first upper network via
Power failure detection system. Each of the battery-powered meters determines that the power customer having the corresponding power meter installed has a power failure when there is no response from the corresponding power meter to the wireless signal continuously a predetermined number of times.
The power failure detection system according to claim 1. It further comprises a plurality of HEMS devices installed in each of the power consumers,
Each of the battery-powered meters is associated one-to-one with the HEMS device installed in the same power consumer as the corresponding power meter, and the corresponding HEMS device as the corresponding HEMS device and the corresponding power meter The wireless signal is periodically transmitted, and the power failure status of the power consumer in which the corresponding power meter is installed is determined based on the response status of the corresponding power meter and the corresponding HEMS device to the wireless signal.
The power failure detection system according to claim 1. Each of the battery-powered meters is connected to the power demander in which the corresponding power meter is installed when there is no response to the wireless signal from both the corresponding power meter and the corresponding HEMS device continuously a predetermined number of times. Judging that there is a power failure,
The power failure detection system according to claim 3. Each of the power meters incorporates a capacitor, and when a power failure occurs in the power consumer in which each of the power meters is installed, the power meter operates with the capacitor for a longer time than the transmission period of the wireless signal, and The response wireless signal includes power failure information which is information indicating that the power consumer having each of the power meters installed is out of power,
When the response wireless signal from the corresponding power meter includes the power failure information, each of the battery-powered meters determines that the power customer having the corresponding power meter installed has a power failure.
The power failure detection system according to claim 1. The wireless signal is a health check packet,
The power failure detection system according to any one of claims 1 to 5.

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