JP2019030138A - Watt-hour meter - Google Patents

Abstract

To effectively utilize information in regards to a localization position of an own watt-hour meter by knowing the newest localization position of the own watt-hour meter, and transmitting the information in regards to the localization position to an external device.SOLUTION: A watt-hour meter 100 comprises: an electric power usage amount measurement part 301 that measures an electric power usage amount, and stores them; a localization position calculation part 302 that receives an electric wave from a satellite, and calculates the localization position on the basis of the electric wave; a transmission part 303 that transmits information in regards to the electric power usage amount and the localization position to a management server; and a reception part 304 that receives a request of the localization position from the management server or a terminal device. When receiving the request, the localization position calculation part 302 calculates the localization position, and the transmission part 303 transmits the localization position calculated by the localization position calculation part 302 to the management server or the terminal device that have requested.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a watt-hour meter such as a smart meter having a communication function with an external device.

  By introducing a smart meter that is a watt-hour meter with a communication function, the amount of power used in a facility for power demand can be confirmed by remote control. This eliminates the need to visit each power demand facility for checking the electricity usage every month (measuring a meter) and to witness the meter reading when moving. Can be reduced. Moreover, the smart meter can confirm the energization state to the smart meter at the time of a power failure by remote control, thereby shortening the time until recovery.

  In addition, since the smart meter can measure the amount of electricity used every 30 minutes every day, by using the smart meter, it is possible to grasp the electricity usage pattern for each facility for electricity demand. As a result, it is possible to diversify the electricity rate menu and provide an electricity rate menu suitable for each facility for electricity demand.

  In addition, smart meters are expected to contribute to energy conservation in society as a whole and to suppress future capital investment in power supply by introducing HEMS (Home Energy Management System). Such smart meters are planned to be installed in facilities for electrical demand.

  As a related technique, specifically, for example, based on a date and time measured based on a standard radio wave, for example, in a certain measurement period from a predetermined measurement start date and time to a measurement end date and time after a predetermined time has elapsed. A two-dimensional code indicating the amount of power used is generated. One of the information to be included in the two-dimensional code may include point information indicating the installation point of the watt-hour meter, and there is a technology related to the watt-hour meter that can display the generated two-dimensional code on the display screen ( For example, see the following Patent Document 1.)

JP2013-152122A

  However, the conventional technology cannot grasp the latest location of the electricity meter itself. Therefore, for example, even if the location of the own device is deviated, it is not possible to remotely know whether it is deviated, how much it is, why it is deviated. Therefore, there is a problem that the position of the target watt hour meter cannot be accurately grasped, and it takes a long time to search for the target watt hour meter. As described above, the conventional technology has a problem that even if the watt-hour meter is capable of remote monitoring, the function cannot be fully utilized.

  In order to solve the above-described problems caused by the prior art, the present invention grasps the latest location of the self-power meter, and transmits information related to the location to an external device, thereby relating to the location of the self-power meter. An object is to provide a watt-hour meter capable of effectively utilizing information.

  In order to solve the above-described problems and achieve the object, the watt-hour meter according to the present invention measures the power consumption, stores the power usage measurement unit to store the radio wave from the satellite, and based on the radio wave. A location calculation unit that calculates the location, and a transmission unit that transmits information on the power usage amount and the location to the management server.

  In addition, the watt-hour meter according to the present invention includes a receiving unit that receives a request for a location from the management server or the terminal device in the above invention, and the location calculation is performed when the request is received. The unit calculates a location, and the transmission unit transmits the location calculated by the location calculation unit to the management server or the terminal device that requested it.

  Further, the watt-hour meter according to the present invention is the power consumption meter according to the above-described invention, wherein the transmission unit uses the location calculated by the location calculation unit when the transmission unit transmits the power usage to the management server. Transmit with quantity.

  In the watt-hour meter according to the present invention, in the above invention, the location calculation unit receives radio waves from a satellite at a predetermined timing, calculates a location based on the radio waves, and calculates the location When the position is different from the previously calculated location, the transmission unit sends an abnormality notification to the management server.

  The watt-hour meter according to the present invention further includes a detection unit that detects occurrence of an abnormality in the above-described invention, and when the occurrence of the abnormality is detected, the location position calculation unit calculates a location position and transmits the transmission. The unit transmits the location calculated by the location calculation unit to the management server.

  Further, the watt hour meter according to the present invention is characterized in that, in the above invention, the detection unit detects that the power usage measurement unit is unable to measure the power usage as the occurrence of the abnormality. To do.

  In the watt-hour meter according to the present invention as set forth in the invention described above, the detection unit detects that the supply of power has been stopped as the occurrence of an abnormality.

  The watt-hour meter according to the present invention is characterized in that, in the above-described invention, the detection unit detects that the vibration, inclination, or temperature exceeds a predetermined value as the occurrence of the abnormality.

  Moreover, the watt-hour meter concerning this invention is provided with a power supply in said invention, The said location calculation part or the said transmission part receives the electric power supply from the said power supply.

  According to the watt-hour meter according to the present invention, the latest location position of the own watt-hour meter is grasped, and information on the location position of the own watt-hour meter is transmitted to an external device, so that the information on the location position can be effectively used. There is an effect that it can be achieved.

It is explanatory drawing which shows an example of the whole structure of the watt-hour meter management system containing the watt-hour meter of embodiment concerning this invention. It is a block diagram which shows an example of the hardware constitutions of the watt-hour meter of embodiment concerning this invention. It is a block diagram which shows an example of a functional structure of the watt-hour meter of embodiment concerning this invention. It is explanatory drawing which shows an example of the display screen displayed on the display of a terminal device. It is explanatory drawing which shows another example of the display screen displayed on the display of a terminal device. It is a flowchart (the 1) which shows an example of the procedure of the process which the watt-hour meter of embodiment concerning this invention performs. It is a flowchart (the 2) which shows an example of the procedure of the process which the watt-hour meter of embodiment concerning this invention performs. It is a flowchart (the 3) which shows an example of the procedure of the process which the watt-hour meter of embodiment concerning this invention performs. It is a flowchart (the 4) which shows an example of the procedure of the process which the watt-hour meter of embodiment concerning this invention performs.

  Exemplary embodiments of a watt-hour meter according to the present invention will be described below in detail with reference to the accompanying drawings.

(Entire configuration of watt-hour meter management system)
First, the structure of the watt-hour meter management system including the watt-hour meter according to the embodiment of the present invention will be described. FIG. 1 is an explanatory diagram showing an example of the overall configuration of a watt-hour meter management system including a watt-hour meter according to an embodiment of the present invention.

  1, the watt-hour meter management system includes a watt-hour meter 100 according to an embodiment of the present invention, a management server 101, a handy terminal 102, a smartphone 103, and a car navigation device 104 as examples of terminal devices, A power outage management system 105 and a HEMS (Home Energy Management System) 106 are included.

  The watt-hour meter 100 is an electronic watt-hour meter referred to as a so-called “smart meter”, for example, and is supplied to a power demand facility such as a detached house or a condominium via a lead-in wire from a wire supported by a power pole or the like. The measured power (power consumption) is digitally measured (measured). For example, the electric power supplied to the equipment for electric demand is measured every 30 minutes.

  In addition, a communication unit (not shown) of the watt-hour meter 100 communicates with a circuit that communicates with the management server 101 (A route), which is an electric contract management apparatus managed by the power supply company, and the communication. It can be realized by a substrate on which various circuits such as a circuit for converting (modulating) data to be provided are mounted.

  Communication in the A route can be realized by, for example, wireless multi-hop communication in which communication is performed by multi-hop transfer to the aggregation device. Communication in the A route can be realized by using various known communication methods such as 1: N communication (multi-point communication) and power line communication (PLC: Power Line Communication).

  Specifically, the communication unit of the watt-hour meter 100 performs, for example, data conversion processing for converting (modulating) the power amount calculated by the central control unit described later into a format that can be transmitted to the management server 101. More specifically, the communication unit of the watt-hour meter 100 transmits, for example, converted data (power amount) to the management server 101 or receives data transmitted from the management server 101. To do. Specifically, the communication unit of the watt-hour meter 100 performs conversion (modulation) of data transmitted from the management server 101, for example.

  Further, the communication unit of the watt-hour meter 100 can communicate with a load (B route) such as a home appliance installed in a facility for electricity demand to which electricity measured by the watt-hour meter 100 is supplied. Good. In this case, communication in the B route can be realized by, for example, Wi-SUN or PLC (Power Line Communication).

  The management server 101 can be realized by a general-purpose computer device such as a personal computer or a workstation. Specifically, a computer device that realizes the management server 101 includes a CPU (Central Processing Unit) that controls the entire computer device, a memory such as a program that stores a program such as a boot program, and data that constitutes various databases, a computer A network I / F (Interface) that controls an interface between the inside of the device and an external device is provided. The components of the management server 101 are not shown.

  The watt-hour meter 100 starts supplying power when receiving the use start notification output from the management server 101, and stops supplying power when receiving the use stop notification. In addition, the watt-hour meter 100 starts supplying power or supplies power when power supply is started in response to each notification output from the management server 101 and when power supply is stopped. Is sent to the management server 101. Thereby, the management server 101 can grasp | ascertain that the electric power supply in the applicable electricity demand installation is performed normally.

  The handy terminal 102, the smartphone 103, and the car navigation device 104, which are specific examples of the terminal device, can communicate with the watt-hour meter 100 wirelessly. Further, these terminal devices 102 to 104 may be able to communicate with the management server 101. In that case, communication with the watt-hour meter 100 can be performed via the management server 101.

  The handy terminal 102 is an example of a terminal device provided in a meter reader or a worker of an electric power company. The handy terminal 102 mainly includes an input unit, a display unit, a printer, a memory (storage unit), and a transmission / reception unit (transmission unit) (not shown), and is configured by a control unit that controls these units. ing. The handy terminal 102 receives input of each measured value such as the measured value of the watt-hour meter 100 and the measured value of the watt-hour meter, and outputs information about each measured value that has been received.

  The input unit is a device for inputting customer identification information (for example, customer ID) and various types of information, and includes, for example, a keypad having various keys such as a numeric keypad and an on / off key. The display unit is a device that displays customer information (for example, name, etc.) and various types of information, and includes, for example, a liquid crystal panel. Information on the location of the target watt-hour meter 100 is displayed on the display unit. The information regarding the location may be address information, or the location of the house where the watt-hour meter 100 is installed may be shown on the displayed map.

  The printer prints the meter reading result on paper in order to notify the customer of the meter reading result when the meter is read. The memory stores customer information, meter reading results and various information. The transmission / reception unit is a communication interface for communicating with a host server (not shown) via a network, receives customer information from the host server, and transmits a meter reading result and various information stored in the memory.

  The control unit is a device for program-controlling the input unit, the display unit, the printer, the memory, and the transmission / reception unit, and includes, for example, a CPU (Central Processing Unit).

  The smartphone 103 is another example of a terminal device included in a meter reader or a worker of an electric power company, and a CPU that controls the entire smartphone 103 and a memory that stores various applications and data used for the control of the CPU (Both are not shown).

  In addition, the smartphone 103 controls data input / output with an external device via a network, or is connected to a telephone line network and is a communication terminal device such as another smartphone (or a portable phone, PHS). And a network I / F that realizes voice communication with a fixed telephone.

  Furthermore, the smartphone 103 includes a display that displays various types of information including map information, an operation unit that receives an input operation by a user, a microphone and a speaker that perform input and output of sound, and the like. Therefore, the position of the target watt-hour meter 100 may be displayed by displaying the map information, or the position may be notified by voice or the like.

  The car navigation device 104 is an example of a terminal device provided in a vehicle or the like used by a meter reader or worker of an electric power company. The car navigation device 104 is used for a CPU that controls the entire car navigation device 104 or for the control of the CPU. A memory for storing various applications and data is provided (all are not shown). Since the car navigation device 104 can be easily realized by using a known technique, the description thereof is omitted.

  The power outage management system 105 is a system that manages information related to power outages such as the status of a power outage that is currently occurring and information about a power outage schedule that is planned to occur in the future, and provides the information through the Internet. Promptly notify the municipality, the number of units, and our recovery response status. By using the watt-hour meter 100 according to the embodiment of the present invention, the location information of each watt-hour meter 100 is received from the management server 101, the area of the power failure is specified, and various information regarding the power failure is provided. To do. Based on the information collected from each watt-hour meter 100, a more accurate blackout area or the like can be grasped, and accurate information can be provided.

  The HEMS 106 is a home power management system, and can control home electrical devices and check power usage through the operation of a liquid crystal monitor screen. Further, it is communicably connected to the watt-hour meter 100, and can send and receive signals and data with the outside. Since the HEMS 106 can be easily realized by using a known technique, the description thereof is omitted.

(Hardware configuration of watt-hour meter 100)
FIG. 2 is a block diagram showing an example of the hardware configuration of the watt-hour meter according to the embodiment of the present invention. In FIG. 2, the watt hour meter 100 includes a CPU 201, a memory 202, a GPS (Global Positioning System) receiver 203, an I / F 204, a battery 205, a display 206, an input device 207, and a vibration sensor 208. A tilt sensor 209 and a temperature sensor 210.

  The CPU 201 controls the entire apparatus of the watt-hour meter 100 by executing a program stored in the memory 202. The memory 202 stores programs executed by the CPU 201 and stores various types of acquired information. Instead of using the CPU 201, for example, an electronic circuit (IC: Integrated Circuit) (not shown) mounted on the watt hour meter 100 may be realized.

  The GPS receiver 203 receives radio waves from three to five GPS satellites and obtains a geometric position with respect to the GPS satellites, and can be measured anywhere on the earth. The radio wave is generated using a L1 radio wave carrying a C / A (Coarse and Access) code and a navigation message with a carrier wave of 1,575.42 MHz. The C / A code has a bit rate of 1.023 Mbps, and the code length is 1023 bits = 1 ms. The navigation message has a bit rate of 50 bps, the code length is 300 bits = 6 s for a subframe, 1500 bits = 30 s for a main frame, 5 main frames are 1 main frame, and 25 main frames are 1 master. It is a frame. That is, it receives radio waves from GPS satellites and outputs GPS positioning data.

  The I / F 204 is an interface connected to the management server 101 through a communication line. For example, a modem or a LAN adapter may be employed as the I / F 204. The I / F 204 may be a wireless communication interface such as a mobile phone line, PHS, Wi-Fi, or Bluetooth (registered trademark). Further, the I / F 204 may be an interface connected to a network such as the Internet through a communication line and connected to another device via this network. The I / F 204 controls an internal interface with the network and controls input / output of data from an external device.

  The battery 205 is a rechargeable battery, and for example, a lithium ion secondary battery can be employed. The battery 205 is charged with power from the power line, and is switched to the charged power when the power from the power line is stopped. Therefore, the location can be calculated and transmitted only for a predetermined time even during a power failure.

  The display 206 is implemented by a liquid crystal display (LCD) that displays various amounts of power and other information, an organic EL (Electro-Luminescence) display, and the like. The latest position information calculated may be displayed on the display 206.

  The input device 207 includes keys for inputting characters, numbers, various instructions, and the like, and inputs data. Specifically, the input device 207 can be realized by, for example, a numeric keypad or an enter key for inputting a specific code. Or, specifically, the input device 207 is, for example, an operation key or numeric keypad for specifying the input operation content such as a “meter reading date setting” key, “meter reading date addition” key, “meter reading date change” key, etc. It may be realized by.

  Alternatively, the input device 207 may be realized by, for example, a liquid crystal display that displays operation keys or numeric keys for specifying input operation content, and a touch panel stacked on the liquid crystal display. In this case, by changing the display content of the liquid crystal display, a plurality of types of input operations can be performed via the touch panel without providing a plurality of keys.

  The vibration sensor 208 is a sensor that detects vibration. There are many methods for detecting vibration, and one example is a piezoelectric vibration sensor. Piezoelectric vibration sensors measure vibration using the piezoelectric effect of piezoelectric elements. When an external force is applied to the piezoelectric element, an electric charge proportional to the force is generated. Conversely, when a voltage is applied, the piezoelectric element is distorted. By applying this piezoelectric effect, vibration is detected.

  The tilt sensor 209 is a sensor that detects the tilt of the watt hour meter 100, and measures the gravitational acceleration of the earth to measure the tilt. Specifically, since the gravitational acceleration measured by the tilt sensor 209 is equal to the sine (sin) × 1G of the tilt angle, the angle can be obtained by back calculation. If the gravitational acceleration is 0G, the tilt angle is 0 degree.

  The temperature sensor 210 is a sensor that measures the ambient temperature of the watt-hour meter 100. There are many methods for measuring temperature. For example, contact-type temperature sensors such as thermocouples / resistance temperature detectors, thermistors, IC temperature sensors, and non-contact type pyroelectric temperature sensors. Various temperature sensors such as a thermopile and a radiation thermometer can be used.

(Functional configuration of watt-hour meter 100)
FIG. 3 is a block diagram showing an example of a functional configuration of the watt-hour meter according to the embodiment of the present invention. In FIG. 3, the watt-hour meter 100 includes a power source 300, a power usage measurement unit 301, a location calculation unit 302, a transmission unit 303, a reception unit 304, and a detection unit 305. Yes.

  The power supply 300 supplies power to each component of the power usage amount measurement unit 301, the location calculation unit 302, the reception unit 303, the transmission unit 304, and the detection unit 305.

  Specifically, for example, the power supply 300 receives power supply from an electric wire (not shown) and supplies power to each component. Further, the power supply 300 may realize its function by the battery 205 shown in FIG. In particular, the battery 205 may be used when the supply of power from the transmission line is stopped.

  The power consumption measuring unit 301 measures and stores the power usage. Specifically, for example, the CPU 201 shown in FIG. 2 executes the program stored in the memory 202 or the like to realize its function. Or you may make it implement | achieve by the electronic circuit (IC: Integrated Circuit) which is mounted in the watt-hour meter 100 and abbreviate | omits illustration, for example.

  More specifically, the power usage amount measuring unit 301 includes, for example, a voltage conversion unit, a current conversion unit, a power calculation unit, a central control unit, and a display unit, although illustration is omitted. The voltage converter is realized by a transformer that accurately lowers the voltage of the load to a voltage that can be handled by the electronic circuit. The current converter is realized by a current transformer that accurately converts the load current into a current that can be handled by the electronic circuit.

  The power calculation unit calculates power consumption based on the voltage value output by the voltage conversion unit and the current value output by the current conversion unit. The central control unit integrates the power consumption obtained by the power calculation unit, and calculates the power amount of the load. The display unit displays the amount of power obtained by the power calculation unit. Specifically, the function is realized by, for example, the display 206 shown in FIG.

  The location calculation unit 302 receives radio waves from the satellite and calculates the location based on the radio waves. Specifically, the location calculation unit 302 realizes its function by, for example, the GPS receiver 203 shown in FIG.

  The transmission unit 303 transmits information regarding the power usage amount and the location to the management server 101. The information on the location includes, for example, latitude and longitude information of the watt-hour meter 100 and altitude information (information on the height from the ground) of the watt-hour meter 100. Moreover, the information regarding the user of the watt-hour meter 100 and the identification information of the watt-hour meter 100 may be included. Specifically, the transmission unit 303 can realize its function by, for example, the I / F 204 shown in FIG.

  The receiving unit 304 receives a request for a location from the management server 101 or a terminal device (handy terminal 102, smartphone 103, car navigation 104). Specifically, the receiving unit 304 can realize its function by, for example, the I / F 204 shown in FIG.

  The request for the location from the management server 101 may be received via a connected communication line, and may be received using the wireless communication function when the wireless server has a wireless communication function. . The wireless communication function is effective when the communication line is disconnected. Further, the location request from the terminal devices 102 to 104 is received using the wireless communication functions provided to each other. Alternatively, it may be received via the management server 101.

  When the request is received, the location calculation unit 302 calculates the location, and the transmission unit 303 uses the management server 101 or the terminal device 102 that requested the location calculated by the location calculation unit 302. To 104. The information on the location can be transmitted using the same method (communication line or wireless communication function) as the method of receiving the location request. Further, the information on the location may be transmitted by a method different from the method of receiving the location request. When a communication failure occurs, it may be transmitted by another method. Moreover, in order to transmit reliably, you may make it transmit by several methods.

  The transmitting unit 303 may transmit the location calculated by the location calculating unit 302 together with the power usage when transmitting the power usage to the management server 101. By transmitting the location with the power usage amount, the credibility of the power usage amount received from the watt-hour meter 100 (reliability that there is no numerical error due to device failure or fraud) can be improved.

  The location calculation unit 302 may receive radio waves from a satellite at a predetermined timing and calculate the location based on the radio waves. The transmission unit 303 may notify the management server 101 of an abnormality when the location calculated by the location calculation unit 302 is different from the previously calculated location. In this way, it is possible to self-check that there is no abnormality in the watt-hour meter 100, and when there is an abnormality, the management server 101 can be immediately notified. Therefore, it is possible to quickly and surely perform a recovery response to the occurrence of an abnormality in the watt-hour meter 100.

  The detection unit 305 detects the occurrence of an abnormality. Specifically, the detection unit 305 realizes its function by, for example, the CPU 201 illustrated in FIG. 2 executing a program stored in the memory 202 or the like. When the detection unit 305 detects the occurrence of an abnormality, the location calculation unit 302 calculates the location, and the transmission unit 303 transmits the location calculated by the location calculation unit 302 to the management server 101. You may make it do.

  In this way, the abnormality detected by the detecting unit 305 can be notified to the management server 101 together with the location information, so that it is possible to accurately grasp the situation of the abnormality that can be estimated from the location information. .

  The detection unit 305 may detect that the power usage amount measurement unit 301 cannot measure the power usage amount as an abnormality. In addition, the detection unit 305 may detect that the supply of power from the power transmission line is stopped as an abnormality.

  Further, the detection unit 305 may detect that the vibration is greater than or equal to a predetermined value as the occurrence of an abnormality. Therefore, the detection unit 305 may realize its function by the vibration sensor 208 shown in FIG.

  Further, the detection unit 305 may detect that an inclination is equal to or greater than a predetermined value as an abnormality. Therefore, the detection unit 305 may realize its function by the inclination sensor 209 shown in FIG.

  Further, the detection unit 305 may detect that the temperature has become equal to or higher than a predetermined value as the occurrence of an abnormality. Therefore, the detection unit 305 may realize its function by the temperature sensor 210 shown in FIG.

(Display example in terminal device)
4 and 5 are explanatory diagrams illustrating an example of a display screen displayed on the display of the terminal device. In FIG. 4, information on the location of the watt hour meter 100 transmitted from the watt hour meter 100, specifically, latitude / longitude information and altitude information (related to the height from the ground) are displayed on the displays of the terminal devices 102 to 104. Information), based on information such as the name of the owner of the house where the watt-hour meter 100 is installed, information about the position of the house on the map is displayed along with the map information around it.

  In FIG. 4, “Taro Momoi” house, which is the name of the owner of the target house, is displayed, and its address is also displayed. This map information can be enlarged or reduced by a predetermined operation, similarly to the known car navigation and smartphone maps.

  FIG. 5 shows an enlarged state of the map information shown in FIG. In FIG. 5, “Taro Momoi” home is displayed in a large size. Moreover, in FIG. 5, the installation location of the watt-hour meter 100 in the house is also displayed. From FIG. 5, it can be easily understood that the watt-hour meter 100 is installed on the back side of the house.

  Moreover, in FIG. 5, based on the acquired altitude information, it is possible to easily grasp how high the watt-hour meter 100 is set from the ground. Accordingly, the location of the watt-hour meter 100 can be immediately confirmed without having to confirm the positions of the heights that are likely to be installed, such as high places and low places. Moreover, even if the watt-hour meter 100 is detached or removed, the state can be easily grasped.

  Note that the information regarding the location of the watt-hour meter 100 received from the watt-hour meter 100 is information calculated by the location calculation unit 302 each time there is a request from the terminal devices 102 to 104. Alternatively, it may be information calculated and stored within a predetermined period. Further, the information regarding the altitude of the watt-hour meter 100 may be information registered by the installer at the time of installation, or may be information calculated by the location calculation unit 302.

  Thus, since the information regarding the location of the watt-hour meter 100 can be displayed on the display of the terminal devices 102 to 104 together with the map information, the target watt-hour meter 100 can be found accurately. Moreover, the time for searching for the target watt-hour meter 100 can be further shortened.

(Processing procedure of watt-hour meter 100)
6 to 9 are flowcharts showing an example of a procedure of processing executed by the watt-hour meter according to the embodiment of the present invention.

  The flowchart of FIG. 6 is a procedure of processing for measuring the location of the watt-hour meter 100 using a GPS receiver and notifying the location. In the flowchart of FIG. 6, the receiving unit 304 determines whether a request for the location of the watt-hour meter 100 has been received from the management server 101 or the terminal devices 102 to 104 (step S601).

  In step S601, waiting for the request for the location (step S601: No), and if there is a request for the location (step S601: Yes), the location calculation unit 302 uses three to five satellites. A radio wave is received (step S602).

  Then, the location calculation unit 302 calculates the location of the watt-hour meter 100 based on the received satellite radio wave (step S603). Thereafter, the transmission unit 303 transmits (replies) the information on the calculated location to the requested management server 101 or the terminal devices 102 to 104 (step S604), and ends a series of processing. In this way, the location of the measured watt-hour meter 100 can be notified in response to a request.

  The flowchart in FIG. 7 is a procedure of processing for transmitting information on the power usage amount to the management server 101. In the flowchart of FIG. 7, the receiving unit 304 determines whether there is a request for information regarding the power usage amount from the management server 101 (step S <b> 701). The request for information related to the power consumption from the management server 101 may be a request at a regular timing, for example, once a month, or a request that is executed irregularly as necessary. May be.

  If there is a request from the management server 101 in step S701 (step S701: Yes), the process proceeds to step S703. On the other hand, if there is no request from the management server 101 in step S701 (step S701: No), the power consumption measuring unit 301 determines whether or not a predetermined timing has come (step S702). The predetermined timing is, for example, a predetermined date and time (for example, midnight on the first day of every month).

  In step S702, when the predetermined timing is not reached (step S702: No), the process returns to step S701. Then, step S701 and step S702 are repeatedly executed. In step S702, when the predetermined timing is reached (step S702: Yes), the process proceeds to step S703.

  In step S703, the location calculation unit 302 receives three to five satellite radio waves (step S703). Then, the location calculation unit 302 calculates the location of the watt-hour meter 100 based on the received satellite radio wave (step S704).

  Thereafter, the transmission unit 303 transmits the information on the calculated location, together with the information on the power usage amount, to the management server 101 (step S705), and ends the series of processes. In this way, the watt-hour meter 100 can notify the location of the measured watt-hour meter 100 when transmitting information related to the power consumption to the management server 101.

  As a result, the management server 101 can easily recognize that the position of the watt hour meter 100 is not shifted from the previous time, no abnormality has occurred in the watt hour meter 100, and It is possible to judge (guess) that fraud has not been carried out. Therefore, the management server 101 also determines (guesses) that the amount of power used is obtained from the watt-hour meter 100 operating normally without fraud, and that the number is an accurate number. Can do.

  The flowchart of FIG. 8 is a procedure of processing for confirming whether the location of the watt-hour meter 100 has changed. In the flowchart of FIG. 8, the location calculation unit 302 determines whether or not a predetermined timing has come (step S801). The predetermined timing is, for example, a predetermined date and time (for example, 12:00 am on the 15th of every month). The timing may be the same as or different from the predetermined timing shown in step S702 of the flowchart of FIG.

  Waiting for the predetermined timing (step S801: No), and when the predetermined timing is reached (step S801: Yes), the location calculation unit 302 executes reception processing of three to five satellite radio waves. (Step S802). Then, it is determined whether or not satellite radio waves have been received (step S803).

  In step S803, if the satellite radio wave cannot be received (step S803: No), it is determined that there is an abnormality in the satellite radio wave reception processing function (for example, an antenna failure or the like). 101 (step S809), and a series of processing ends.

  On the other hand, when the satellite radio wave can be received in step S803 (step S803: Yes), the location calculation unit 302 executes the calculation process of the location of the watt-hour meter 100 based on the received satellite radio wave ( Step S804). Then, it is determined whether the location position has been calculated (step S805).

  If the location position cannot be calculated in step S805 (step S805: No), it is assumed that there is an abnormality in the location position calculation processing function (for example, the watt-hour meter 100 has failed, the watt-hour meter 100 has been tampered with, etc.). Then, the process proceeds to step S809, where an abnormality notification is transmitted to the management server 101 (step S809), and the series of processing ends.

  On the other hand, when the location position can be calculated in step S805 (step S805: Yes), the location position calculation unit 302 stores information on the calculated location position in a predetermined storage area (step S806). Thereafter, it is compared with the information regarding the location calculated and stored previously (step S807). Then, as a result of the comparison, it is determined whether or not the location of the two is different (step S808).

  If the location of the watt-hour meter 100 has not moved, the location of both should be the same. If the location of the two is different as a result of the comparison (step S808: Yes), the watt-hour meter 100 If there is an abnormality (for example, the watt-hour meter 100 is dropped, the watt-hour meter 100 is removed, or the house where the watt-hour meter 100 is attached (collapse, inclination, etc.)), the process proceeds to step S809. Then, an abnormality notification is transmitted to the management server 101 (step S809), and a series of processing is terminated.

  On the other hand, as a result of the comparison, if the location positions of the two are not different (step S808: No), it is determined that there is no abnormality, and a series of processing is terminated without doing anything. In this manner, the watt-hour meter 100 periodically checks the location itself periodically and can notify the management server 101 of an abnormality when the location location is shifted. As a result, the management server 101 can quickly grasp whether there is an abnormality in the watt-hour meter 100, and can more reliably collect information related to the power usage amount.

  The flowchart of FIG. 9 is a procedure of processing for confirming whether the watt-hour meter 100 or the house where the watt-hour meter 100 is set is normal. In the flowchart of FIG. 9, the detection unit 305 continues to monitor the power usage amount measurement unit 301 and determines whether or not the power usage amount measurement unit 301 cannot measure the power usage amount ( Step S901).

  Here, when it is determined that the measurement of the power consumption is impossible (step S901: Yes), the process proceeds to step S906. In this case, it can be estimated that the power usage measurement function by the power usage measurement unit 301 is abnormal. On the other hand, when it is determined that the measurement of the power consumption is not impossible (step S901: No), the process proceeds to step S902.

  Next, the detection unit 305 continues to monitor the power supply 300, and determines whether or not the supply of power from the power transmission line is stopped (step S902). Here, when supply of electric power is stopped (step S902: Yes), the process proceeds to step S906. In this case, it can be estimated that a power failure has occurred or that intentional power transmission has been stopped. On the other hand, when the supply of power is not stopped (step S902: No), the process proceeds to step S903.

  Next, the detection unit 305 determines whether there has been a vibration greater than a predetermined value (step S903). Here, when there is a vibration of a predetermined value or more (step S903: Yes), the process proceeds to step S906. In this case, an earthquake has occurred and the electricity meter 100 has been removed from the house, the house has collapsed or collapsed, or the electricity meter 100 has been removed (unauthorized). Can be estimated. On the other hand, when there is no vibration more than a predetermined value (step S903: No), it transfers to step S904.

  Next, the detection unit 305 determines whether or not the watt-hour meter 100 has tilted beyond a predetermined value (step S904). Here, when it inclines more than predetermined value (step S904: Yes), it transfers to step S906. In this case, it can be estimated that the watt-hour meter 100 has been detached from the house, the (unauthorized) removal work of the watt-hour meter 100 has been performed, or the house itself has collapsed or collapsed. On the other hand, when it is not inclined beyond the predetermined value (step S904: No), the process proceeds to step S905.

  Next, the detection unit 305 determines whether or not the watt-hour meter 100 has reached a temperature equal to or higher than a predetermined value (step S905). Here, when the temperature is equal to or higher than the predetermined value (step S905: Yes), the process proceeds to step S906. In this case, it can be estimated that a fire has occurred from the house where the watt-hour meter 100 is installed or the vicinity thereof. On the other hand, when the temperature is not equal to or higher than the predetermined value (step S905: No), the process returns to step S901, and thereafter, steps S901 to S905 are repeated.

  In step S906, the location calculation unit 302 receives three to five satellite radio waves (step S906). Then, the location calculation unit 302 calculates the location of the watt-hour meter 100 based on the received satellite radio wave (step S907).

  Thereafter, the transmission unit 303 transmits information regarding the calculated location to the management server 101 (step S908), and ends a series of processing. In this way, when an abnormality occurs in the watt-hour meter 100 or the house where the watt-hour meter 100 is installed, the location can be accurately grasped. In particular, even when a disaster or the like occurs, the position can be easily grasped, and relief activities can be accurately supported. In particular, even if the house itself is washed away due to floods or landslides, and the location is unknown, the location is reliably communicated, so more efficient relief activities are possible.

  As described above, the watt-hour meter 100 according to the embodiment of the present invention receives the electric wave from the electric power consumption measuring unit 301 that measures and stores the electric power consumption and the satellite, and based on the electric wave. A location calculation unit 302 that calculates the location, and a transmission unit 303 that transmits information about the power usage amount and the location to the management server 101. The location of can be remotely known.

  The watt-hour meter 100 according to the embodiment of the present invention includes a receiving unit 304 that receives a request for a location from the management server 101 or the terminal devices 102 to 104. The position calculation unit 302 calculates the location, and the transmission unit 303 transmits the location calculated by the location calculation unit 302 to the management server 101 or the terminal devices 102 to 104 that requested the management server. When the terminal 101 or the terminal devices 102 to 104 requests, it can acquire the latest location information, and can use the location information more effectively.

  Moreover, the watt-hour meter 100 according to the embodiment of the present invention includes the location calculated by the location calculation unit 302 together with the power usage when the transmission unit 303 transmits the power usage to the management server 101. Since it transmits, information with higher credibility can be acquired regarding power consumption.

  In the watt-hour meter 100 according to the embodiment of the present invention, the location calculation unit 302 receives radio waves from the satellite at a predetermined timing, calculates the location based on the radio waves, and calculates the location When the position is different from the previously calculated location, the transmission unit 303 can notify the management server 101 of an abnormality, so that an abnormality that the management server 101 cannot detect is detected by itself, and the management server 101 is automatically detected. Can be notified. Thereby, a quicker response to the abnormality can be achieved.

  Moreover, the watt-hour meter 100 according to the embodiment of the present invention includes a detection unit 305 that detects the occurrence of an abnormality, and the occurrence of an abnormality (power supply has been stopped, vibration greater than a predetermined value, inclination, or temperature). The location calculation unit 302 calculates the location, and the transmission unit 303 transmits the location calculated by the location calculation unit 302 to the management server 101. The management server 101 can more accurately grasp the detected abnormality occurrence situation (particularly, the situation of the watt-hour meter 100 and the situation of the house where the watt-hour meter 100 is installed) from a remote location.

  In addition, the watt-hour meter 100 according to the embodiment of the present invention includes a power supply 300, and the location calculation unit 302 or the transmission unit 303 receives power supply from the power supply 300, so that supply of power is stopped. Even so, information regarding the location of the watt-hour meter 100 can be transmitted to the management server 101.

  In this way, the latest location of the watt-hour meter is grasped, and information on the location of the watt-hour meter is communicated to an external device, so that the information on the location of the watt-hour meter can be effectively used (for fraud monitoring and disasters. Detection of house damage and collapse).

  As described above, the watt-hour meter according to the present invention is useful for a watt-hour meter that grasps the latest location of the own watt hour meter and transmits information related to the location to an external device. It is suitable for a watt hour meter that makes effective use of information on the location of the meter.

DESCRIPTION OF SYMBOLS 100 Electricity meter 101 Management server 102 Handy terminal 103 Smart phone 104 Car navigation system 105 Power failure management system 106 HEMS
201 CPU
202 Memory 203 GPS Receiver 204 I / F
205 Battery 208 Vibration Sensor 209 Tilt Sensor 210 Temperature Sensor 300 Power Supply 301 Power Usage Measurement Unit 302 Location Location Calculation Unit 303 Transmission Unit 304 Reception Unit 305 Detection Unit

Claims (9)

A power usage measurement unit that measures and stores power usage; and
A location calculation unit that receives radio waves from a satellite and calculates a location based on the radio waves;
A transmission unit for transmitting information on the power consumption and the location to the management server;
A watt hour meter characterized by comprising: A receiving unit that receives a request for a location from the management server or terminal device;
When receiving the request,
The location calculation unit calculates the location,
The watt-hour meter according to claim 1, wherein the transmission unit transmits the location calculated by the location calculation unit to the management server or the terminal device that has made a request.   3. The transmission unit according to claim 1, wherein the transmission unit transmits the location calculated by the location calculation unit together with the power usage when transmitting the power usage to the management server. 4. Watt hour meter. The location calculation unit receives radio waves from a satellite at a predetermined timing, calculates the location based on the radio waves,
If the calculated location is different from the previously calculated location,
The watt-hour meter according to claim 1, wherein the transmission unit sends an abnormality notification to the management server. It has a detector that detects the occurrence of an abnormality,
When the occurrence of the abnormality is detected,
The location calculation unit calculates the location,
The watt-hour meter according to claim 1, wherein the transmission unit transmits the location calculated by the location calculation unit to the management server.   The watt-hour meter according to claim 5, wherein the detection unit detects that the power usage amount measurement unit cannot measure the power usage amount as the occurrence of the abnormality.   The watt-hour meter according to claim 5, wherein the detection unit detects that the supply of power is stopped as the occurrence of the abnormality.   The watt-hour meter according to claim 5, wherein the detection unit detects that the vibration, the inclination, or the temperature is equal to or greater than a predetermined value as the occurrence of the abnormality. With power supply,
The watt-hour meter according to claim 1, wherein the location calculation unit or the transmission unit is supplied with power from the power source.

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