JP2014092392A - Power measuring system, power measuring slave unit and power measuring method - Google Patents

Abstract

Power consumption is measured at low cost in a home provided with a power generation device capable of supplying power to an electric power system.
A power measurement system measures a current flowing through a first power line and a second power line on a power system side with respect to a connection point between the first power line and the second power line. A first power measuring slave unit 101A for measuring the current flowing through the first power line 91 and the second power line 92 on the power generation device 106 side with respect to the connection point. Of the current flowing through one of the first power line 91 and the second power line 92 on the machine 101B and the power system side, and the current flowing through one of the first power line 91 and the second power line 92 on the power generation apparatus 106 side. A third power measuring slave unit 101C for comparing the phase.
[Selection] Figure 2

Description

  The present invention relates to a power measurement system, a power measurement slave unit, and a power measurement method, and more particularly, to a power measurement system, a power measurement slave unit, and a power measurement method for measuring power consumption of a load in a house provided with a power generation device. .

  Various devices have been developed that measure the amount of power consumed at home and work for the purpose of power saving, etc., and allow the user to confirm the amount of power consumed.

  As an example of such a device, for example, JP 2010-145095 A (Patent Document 1) discloses the following configuration. That is, the electric energy sensor is attached to an AC cable of an electrical product connected to a power line and generates an electromotive force by electromagnetic induction caused by a current flowing through the AC cable, and an electromotive force generated by the current transformer unit. A power storage circuit unit that stores power; and a signal transmission unit that wirelessly transmits a signal using the stored power when the amount of power stored in the power storage circuit unit reaches a certain operating voltage.

JP 2010-145095 A

  In recent years, the installation of solar cells has been on the rise in the home, and a system has been established in which electric power companies purchase surplus power out of the power generated by solar cells.

  In order to measure the amount of power consumed in a home where such a solar cell is installed, whether the surplus power is being sold to the power grid, or the generated power is not enough, and the power from the power grid to the home It is necessary to determine whether the power is being purchased.

  In order to make such a determination, a method of measuring both current and voltage at home with a distribution board or the like is conceivable.

  However, it is difficult for the user to perform such measurement, and the number of persons who can perform measurement and installation of measuring instruments is often limited to qualified persons, which is expensive.

  This invention was made in order to solve the above-mentioned subject, and the object is to measure the amount of power consumption at low cost in a house provided with a power generator capable of supplying power to the power system. A power measurement system, a power measurement slave unit, and a power measurement method are provided.

  (1) A power measurement system according to an aspect of the present invention is provided with a first power line and a second power line connected to a power system, and a power generation device capable of supplying generated power to the power system. A power measurement system for measuring power consumption of a load in a house, wherein the power generation device is electrically connected to a connection point between the first power line and the second power line and the load. For measuring a current flowing through the first power line and the second power line and transmitting a signal indicating the measurement result to the power information processing apparatus. A current flowing through the first power line and the second power line is measured on the first power measuring slave unit and the power generation device side with respect to the connection point, and a signal indicating the measurement result is displayed. , A phase of current flowing through one of the first power line and the second power line on the power system side, and the power generator side A third power measuring slave unit for comparing a phase of a current flowing through one of the first power line and the second power line and transmitting a signal indicating a comparison result to the power information processing apparatus. Prepare.

  With such a configuration, it is possible to easily measure each current in the house and the direction of the current between the power system and the power generation device. In addition, the configuration for comparing the current phase using the third power measuring slave unit eliminates the need for a circuit and wiring for synchronizing the current measurement timing between the power measuring slave units, for example. Simplification can be achieved. Further, in order to measure the current and the direction of current in the home, for example, in a method using a measuring device having more current sensors than a power measuring slave unit, there are a considerable number of households that have not yet introduced solar cells. It is necessary to develop separate devices in the home where the battery is introduced and the home where the battery is not yet introduced, which increases the manufacturing cost. On the other hand, it is only necessary to develop a common device for households where the solar cells are introduced and for households where the solar cells are not introduced, by using three power measuring slave units including two current sensors as described above. Cost can be reduced. Therefore, the amount of power consumption can be measured at low cost in a home where power can be supplied to the power system.

  (2) Preferably, the power measurement system further includes the power information processing device, and the power information processing device is based on a comparison result of the third power measurement slave unit, from the power generation device. It is determined whether power is supplied to the power system, and the consumption is based on the determination result, the measurement result of the first power measurement slave unit, and the measurement result of the second power measurement slave unit. Calculate power.

  With such a configuration, it is possible to determine the power purchase state and the power sale state using the comparison result of the current phase by the third power measuring slave unit, and to correctly calculate the power consumption in the home.

  (3) More preferably, when the power information processing apparatus determines that power is being supplied from the power generation apparatus to the power system, from the current measured by the second power measurement slave unit. The power consumption is calculated based on a value obtained by subtracting the current measured by the first power measuring slave unit, and the power information processing apparatus is not supplying power from the power generation apparatus to the power system. Is determined, the power consumption based on the sum of the current measured by the first power measurement slave unit and the current measured by the second power measurement slave unit is calculated.

  With such a configuration, it is possible to correctly calculate the power consumption in the home by an appropriate calculation method according to the current phase comparison result by the third power measuring slave unit.

  (4) Preferably, the power measurement system further includes the power information processing device, and the power information processing device is provided by the first power measurement slave unit or the third power measurement slave unit. Based on the identification information included in the signal including the measurement result or the comparison result, the measurement position including the measurement result or the comparison result included in the signal is determined, and based on the determined measurement position Calculate power consumption.

  With such a configuration, the measurement position corresponding to the current measurement result and the current phase comparison result received from each power measurement slave can be specified.

  (5) More preferably, the power information processing apparatus includes a storage unit for storing information indicating a correspondence relationship between the identification information and the measurement position.

  With such a configuration, it is possible to acquire the correspondence between the measurement result of the current received from the power measuring slave unit and the comparison result of the current phase and the measurement position with a simple configuration.

  (6) Preferably, the third power measurement slave unit includes a presentation unit for presenting information based on the comparison result.

  With such a configuration, the user can easily grasp whether the power purchase state or the power sale state is present, and thus the convenience for the user can be improved.

  (7) A power measurement slave device according to an aspect of the present invention is a power measurement slave device used in the power measurement system of (1) above, and includes two current measurement units and each of the current measurement units. A phase comparison unit for comparing the phase of the measured current, and a transmission unit for transmitting a signal indicating the measurement result of each current measurement unit and the comparison result of the phase comparison unit to the power information processing apparatus. Prepare.

  With such a configuration, it is possible to easily measure each current in the house and the direction of the current between the power system and the power generation device. Further, since the current phase can be compared by one power measuring slave unit, for example, a circuit and wiring for synchronizing the current measurement timing between the power measuring slave units becomes unnecessary, and the device and system configuration are simplified. Can be achieved. Further, in order to measure the current and the direction of current in the home, for example, in a method using a measuring device having more current sensors than a power measuring slave unit, there are a considerable number of households that have not yet introduced solar cells. It is necessary to develop separate devices in the home where the battery is introduced and the home where the battery is not yet introduced, which increases the manufacturing cost. On the other hand, the configuration using the power measuring slave unit including two current sensors as described above makes it possible to develop a common device for use in homes where solar cells are introduced and for homes where no solar cells are introduced, thereby reducing manufacturing costs. Can be reduced. Therefore, the amount of power consumption can be measured at low cost in a home where power can be supplied to the power system.

  (8) A power measurement method according to an aspect of the present invention includes a first power line and a second power line connected to a power system, and a power generation device capable of supplying generated power to the power system. A power measurement method for measuring power consumption of a load in a house, wherein the power generation device is electrically opposite to the power system with respect to a connection point between the first power line and the second power line and the load. And a first power measurement slave unit measures a current flowing through the first power line and the second power line on the power system side with respect to the connection point, and outputs a signal indicating the measurement result as a power A step of transmitting to the information processing device, and a second power measurement slave unit measures the current flowing through the first power line and the second power line on the power generation device side with respect to the connection point; A step of transmitting a signal indicating a fixed result to the power information processing apparatus, and a phase of a current that the third power measurement slave unit flows through one of the first power line and the second power line on the power system side And a phase of a current flowing through one of the first power line and the second power line on the power generation device side, and transmitting a signal indicating the comparison result to the power information processing device.

  With such a configuration, it is possible to easily measure each current in the house and the direction of the current between the power system and the power generation device. In addition, the configuration for comparing the current phase using the third power measuring slave unit eliminates the need for a circuit and wiring for synchronizing the current measurement timing between the power measuring slave units, for example. Simplification can be achieved. Further, in order to measure the current and the direction of current in the home, for example, in a method using a measuring device having more current sensors than a power measuring slave unit, there are a considerable number of households that have not yet introduced solar cells. It is necessary to develop separate devices in the home where the battery is introduced and the home where the battery is not yet introduced, which increases the manufacturing cost. On the other hand, it is only necessary to develop a common device for households where the solar cells are introduced and for households where the solar cells are not introduced, by using three power measuring slave units including two current sensors as described above. Cost can be reduced. Therefore, the amount of power consumption can be measured at low cost in a home where power can be supplied to the power system.

  According to the present invention, power consumption can be measured at low cost in a home provided with a power generator capable of supplying power to the power system.

It is a figure which shows the structure of the electric power measurement system which concerns on embodiment of this invention. It is a figure which shows the detailed usage example of CT sensor in the electric power measurement system which concerns on embodiment of this invention. It is a figure which shows the measurement position etc. of CT sensor in the electric power measurement system which concerns on embodiment of this invention in detail. It is a figure which shows the structure of CT sensor in the electric power measurement system which concerns on embodiment of this invention. It is a figure which shows an example of the calculation method of the power consumption in the electric power purchase state in the electric power measurement system which concerns on embodiment of this invention. It is a figure which shows the other example of the calculation method of the power consumption in the power sale state in the electric power measurement system which concerns on embodiment of this invention. It is a figure which shows an example of the measurement position table in the server of the electric power measurement system which concerns on embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Configuration and basic operation]
FIG. 1 is a diagram showing a configuration of a power measurement system according to an embodiment of the present invention.

  Referring to FIG. 1, a power measurement system 201 is constructed in a home such as a home or a workplace, and includes a CT sensor (power measurement slave unit) 101, a wireless adapter 103, a home gateway 104, and power information display. A terminal 105, a power generation device 106, and a server (power information processing device) 151 are provided. Here, the power generation device 106 includes a PCS (power conditioner) 111 and a solar cell 112. The power generation device 106 may be another device capable of supplying power.

  The CT sensor 101 and the wireless adapter 103 transmit and receive wireless signals in accordance with, for example, the ZigBee standard. The home gateway 104 and the power information display terminal 105 transmit and receive radio signals according to, for example, a wireless LAN (Local Area Network) system conforming to the IEEE 802.11 standard. Note that these communication standards in the power measurement system 201 are examples, and for example, only wireless LAN communication may be performed. Further, wired communication may be performed between the devices.

  The electric device 121 operates using power received from the power system via the distribution board 102 and a power strip (not shown).

  The CT sensor 101 is attached to, for example, the distribution board 102, measures current consumed in an electrical device 121 such as an air conditioner and a television in the house, and transmits measurement information indicating the amount of power calculated based on the measurement result to the wireless adapter. It transmits to 103 by a radio signal. Note that the CT sensor 101 may transmit measurement information indicating the measured current to the wireless adapter 103.

  The wireless adapter 103 performs communication protocol conversion processing and transmits the measurement information received from the CT sensor 101 to the home gateway 104. Note that a function corresponding to the wireless adapter 103 can be incorporated in the home gateway 104.

  The home gateway 104 transmits the measurement information received from the wireless adapter 103 to the server 151 via the power information display terminal 105 and the Internet 301.

  Based on the measurement information received from the home gateway 104, the server 151 creates power consumption information indicating the total power consumption in the home where the home gateway 104 is installed, and transmits the power consumption information to the home gateway 104. The server 151 may calculate the total power consumption or the like based on the measurement information indicating the power consumption calculated by the CT sensor 101, or may calculate the total power based on the measurement information indicating the current measured by the CT sensor 101. A power consumption amount or the like may be calculated.

  For example, the home gateway 104 transmits the power consumption information received from the server 151 to the power information display terminal 105.

  The power information display terminal 105 outputs audio and video indicating the power consumption information received from the home gateway 104.

  The home gateway 104, as a power information processing apparatus, creates power consumption information indicating the total power consumption in the home based on the measurement information received from the wireless adapter 103, and displays the created power consumption information as power information display It may be configured to transmit to the server 151 via the terminal 105 and the Internet 301.

  FIG. 2 is a diagram illustrating a detailed usage example of the CT sensor in the power measurement system according to the embodiment of the present invention.

  Referring to FIG. 2, single-phase three-wire power lines 91 and 92 and a neutral line 93 connected to the power system are wired in the house. L1-phase AC power is supplied from the power system to the home via the power line 91, and L2-phase AC power is supplied via the power line 92. The L1 phase AC power and the L2 phase AC power have, for example, opposite phases. The neutral wire 93 is grounded, for example.

  Distribution board 102 includes a main breaker 81, a branch breaker 82, and a PV breaker 83.

  Main power breaker 81, branch breaker 82, PV breaker 83, and power generator 106 are connected to power lines 91, 92 and neutral line 93.

  More specifically, main breaker 81 is connected to power lines 91 and 92 and neutral line 93 from the power system, and branch breaker 82 is connected to power lines 91 and 92 and neutral line 93 via main breaker 81. The PV breaker 83 is connected to the power lines 91 and 92 and the neutral line 93 via the branch breaker 82. The power generation apparatus 106 is connected to power lines 91 and 92 and a neutral line 93 via a PV breaker 83.

  The branch breaker 82 includes a plurality of breakers, and each breaker is connected to an electric device 121 that is an example of a load in the house. The PV breaker 83 is connected to the power generator 106.

  The power measurement system 201 measures the power consumption of the load 121 in the home provided with the power line 91 and the power line 92 connected to the power system in this way and the power generation device 106 capable of supplying the generated power to the power system. To do.

  More specifically, the power measurement system 201 includes three CT sensors 101A, 101B, and 101C. The CT sensor 101A is connected to power lines 91 and 92 between the main breaker 81 and the branch breaker 82. CT sensor 101B is connected to power lines 91 and 92 between branch breaker 82 and PV breaker 83. The CT sensor 101C is connected to a power line 92 between the main breaker 81 and the branch breaker 82 and a power line 92 between the branch breaker 82 and the PV breaker 83. Hereinafter, each of the CT sensors 101A, 101B, and 101C may be referred to as a CT sensor 101.

  The connection positions of the CT sensors 101A, 101B, and 101C may be outside the main breaker 81 and the PV breaker 83. That is, CT sensors 101A, 101B, and 101C may be connected to a power line between the power system and main breaker 81 or a power line between PV breaker 83 and power generation device 106.

  FIG. 3 is a diagram showing in detail the measurement position and the like of the CT sensor in the power measurement system according to the embodiment of the present invention. In FIG. 3, the main breaker 81 and the PV breaker 83 are not shown for the sake of simplicity.

  Referring to FIG. 3, branch breaker 82 in distribution board 102 includes breakers 71 </ b> A, 71 </ b> B, 71 </ b> C. The distribution board 102 may include a small number or a larger number of breakers. Load 121A is connected to power line 91 and neutral line 93 via breaker 71A, and receives, for example, an AC voltage of 100V. Load 121B is connected to power line 92 and neutral line 93 via breaker 71B, and receives, for example, an AC voltage of 100V. Load 121C is connected to power line 91 and power line 92 via breaker 71C and receives, for example, an AC voltage of 200V. Hereinafter, each of the loads 121A, 121B, and 121C may be referred to as a load 121.

  The power generation apparatus 106 is electrically provided on the opposite side of the power system with respect to the connection points between the power lines 91 and 92 and the neutral line 93 and the load 121.

  CT sensor 101 </ b> A measures the current flowing through power line 91 and power line 92 on the power system side with respect to the connection point, and transmits a signal indicating the measurement result to server 151 via wireless adapter 103.

  The CT sensor 101 </ b> B measures the current flowing through the power line 91 and the power line 92 on the power generation device 106 side with respect to the connection point, and transmits a signal indicating the measurement result to the server 151 via the wireless adapter 103.

  The CT sensor 101C compares the phase of the current flowing through the power line 92 on the power system side with the phase of the current flowing through the power line 92 on the power generation apparatus 106 side, and transmits a signal indicating the comparison result to the server 151 via the wireless adapter 103. To do.

  More specifically, the CT sensor 101A measures the current flowing through the measurement position m1 and the current flowing through the measurement position m2. The measurement positions m1 and m2 are set between the power system and the distribution board 102. Specifically, the measurement position m1 is set on the power system side with respect to the connection point between the power line 91 and the loads 121A and 121C via the branch breaker 82. The measurement position m2 is set on the power system side with respect to the connection point between the power line 92 and the loads 121B and 121C via the branch breaker 82.

  The CT sensor 101B measures the current flowing through the measurement position m3 and the current flowing through the measurement position m4. The measurement positions m3 and m4 are set between the distribution board 102 and the power generation device 106. Specifically, the measurement position m3 is set on the power generation device 106 side with respect to the connection point between the power line 91 and the loads 121A and 121C via the branch breaker 82. The measurement position m4 is set on the power generation device 106 side with respect to the connection point between the power line 92 and the loads 121B and 121C via the branch breaker 82.

  The CT sensor 101C measures the current flowing through the measurement position m5 and the current flowing through the measurement position m6, and compares the phases of the currents. The measurement position m5 is set between the power system and the distribution board 102, and the measurement position m6 is set between the distribution board 102 and the power generator 106. Specifically, the measurement position m5 is set on the power system side with respect to the connection point between the power line 92 and the loads 121B and 121C via the branch breaker 82. The measurement position m6 is set on the power generation device 106 side with respect to the connection point between the power line 92 and the loads 121B and 121C via the branch breaker 82.

  FIG. 4 is a diagram showing a configuration of a CT sensor in the power measurement system according to the embodiment of the present invention.

  Referring to FIG. 4, CT sensor 101 includes current measuring units 11 and 12, a wireless transmission unit 13, a phase comparison unit 14, a presentation unit 15, a power calculation unit 16, and an antenna 17.

  The current measurement units 11 and 12 measure the current flowing through the corresponding measurement positions, and output a signal indicating the measurement result to the power calculation unit 16 and the phase comparison unit 14.

  The power calculation unit 16 calculates power from the current flowing through each measurement position based on the signals received from the current measurement units 11 and 12, and outputs a signal indicating the calculation result to the wireless transmission unit 13.

  The phase comparison unit 14 compares the phases of the currents measured by the current measurement units 11 and 12 based on the signals received from the current measurement units 11 and 12, and sends a signal indicating the comparison result to the wireless transmission unit 13 and the presentation unit. 15 is output.

  The wireless transmission unit 13 transmits a signal indicating the measurement results of the current measurement units 11 and 12 and the comparison result of the phase comparison unit 14 to the server 151. Specifically, the wireless transmission unit 13 converts the signal received from the power calculation unit 16 and the signal received from the phase comparison unit 14 into a wireless signal, and transmits the wireless signal to the wireless adapter 103 via the antenna 17.

  The presentation unit 15 presents information based on the comparison result by the phase comparison unit 14. Specifically, the presentation unit 15 includes, for example, an LED, and turns on or off the LED according to the comparison result by the phase comparison unit 14. Note that the presentation unit 15 may be configured to transmit information indicating the comparison result to the power information display terminal 105 via the wireless transmission unit 13 and present the information to the user in the power information display terminal 105, for example. Good. Further, the presentation unit 15 may include a button, and may be configured to turn on and off the LED for a certain period of time or transmit information to the power information display terminal 105 when the user presses the button.

  The CT sensor 101 may be configured not to include the power calculation unit 16 and to transmit the current measurement results by the current measurement units 11 and 12 to the wireless adapter 103.

  Further, the CT sensors 101A and 101B may be configured not to include the phase comparison unit 14 and the presentation unit 15. The CT sensor 101C may be configured not to include the power calculation unit 16.

  Based on the comparison result of the CT sensor 101C, the server 151 determines whether or not power is being supplied from the power generation device 106 to the power system. The determination result, the measurement result of the CT sensor 101A, and the CT sensor 101B Based on the measurement result, the power consumption of the load 121 in the house is calculated.

  FIG. 5 is a diagram illustrating an example of a method of calculating the power consumption amount in the power purchase state in the power measurement system according to the embodiment of the present invention.

  Referring to FIG. 5, in the power purchase state, that is, in a state where the generated power of solar cell 112 is insufficient and power is supplied from the power system to power via power lines 91 and 92 and neutral line 93, the power system Current Im1 is supplied to the loads 121A and 121C from the power line 91, and current Im2 is supplied from the power system to the loads 121B and 121C via the power line 92. Further, the current Ip1 is supplied from the power generator 106 to the loads 121A and 121C via the power line 91, and the current Ip2 is supplied from the power generator 106 to the loads 121B and 121C via the power line 92.

  In this case, the CT sensor 101C determines that the relationship between the phase of the current Im1 and the phase of the current Ip1 is an opposite phase, and transmits the fact that it is an opposite phase to the server 151 as a comparison result.

  The server 151 determines from the comparison result of the current phase received from the CT sensor 101C that power is not supplied from the power generation apparatus 106 to the power system. In this case, the server 151 calculates power consumption based on the sum of the current measured by the CT sensor 101A and the current measured by the CT sensor 101B.

  Specifically, the server 151 calculates the L1 phase power consumption in the home based on the sum of the current Ip1 and the current Im1. Further, the server 151 calculates the L2 phase power consumption in the home based on the sum of the current Ip2 and the current Im2. Then, the server 151 calculates the sum of the L1 phase power consumption and the L2 phase power consumption in the home as the total power consumption in the home.

  FIG. 6 is a diagram showing another example of a method for calculating the power consumption amount in the power sale state in the power measurement system according to the embodiment of the present invention.

  Referring to FIG. 6, in the power selling state, that is, in the state where the power generation amount of solar cell 112 is large and power is supplied from power generation device 106 to power system via power lines 91 and 92 and neutral line 93. The shunt current Im1 of the current Ip1 is supplied from the device 106 to the power system via the power line 91, and the shunt current (Ip1-Im1) of the current Ip1 is supplied to the loads 121A and 121C. Further, a shunt current Im2 of current Ip2 is supplied from the power generator 106 to the power system via the power line 92, and a shunt current (Ip2-Im2) of current Ip2 is supplied to the loads 121B and 121C.

  In this case, the CT sensor 101C determines that the relationship between the phase of the current Im1 and the phase of the current Ip1 is the same phase, and transmits the fact that it is the same phase to the server 151 as a comparison result.

  The server 151 determines that the power supply from the power generation apparatus 106 to the power system is performed from the comparison result of the current phase received from the CT sensor 101C. In this case, the server 151 calculates power consumption based on a value obtained by subtracting the current measured by the CT sensor 101A from the current measured by the CT sensor 101B.

  Specifically, the server 151 calculates the L1 phase power consumption in the home based on a value obtained by subtracting the current Im1 from the current Ip1. Further, the server 151 calculates the L2 phase power consumption in the home based on a value obtained by subtracting the current Im2 from the current Ip2. Then, the server 151 calculates the sum of the L1 phase power consumption and the L2 phase power consumption in the home as the total power consumption in the home.

  The CT sensor 101C compares the phase of the current flowing through the power line 91 on the power system side with the phase of the current flowing through the power line 91 on the power generation apparatus 106 side, and transmits a signal indicating the comparison result to the server 151. There may be.

  In this case, similarly to the above, the server 151 determines that the power supply from the power generation device 106 to the power system is performed when the comparison result of the current phase received from the CT sensor 101C indicates the same phase. On the other hand, the server 151 determines that the power supply from the power generation device 106 to the power system is not performed when the comparison result of the current phase received from the CT sensor 101C indicates an opposite phase.

  In addition, the CT sensor 101C compares the phase of the current flowing through the power line 91 on the power system side with the phase of the current flowing through the power line 92 on the power generation device 106 side, and transmits a signal indicating the comparison result to the server 151. There may be. Alternatively, the CT sensor 101C compares the phase of the current flowing through the power line 92 on the power system side with the phase of the current flowing through the power line 91 on the power generation apparatus 106 side, and transmits a signal indicating the comparison result to the server 151. There may be.

  In this case, contrary to the above, when the comparison result of the current phase received from the CT sensor 101C indicates the reverse phase, the server 151 determines that the power supply from the power generation apparatus 106 to the power system is being performed. On the other hand, the server 151 determines that the power supply from the power generation device 106 to the power system is not performed when the comparison result of the current phase received from the CT sensor 101C indicates the same phase.

  FIG. 7 is a diagram showing an example of a measurement position table in the server of the power measurement system according to the embodiment of the present invention.

  Referring to FIG. 7, in server 151, storage unit 161 shown in FIG. 1 stores a measurement position table, which is information indicating the correspondence between identification information and measurement positions.

  Specifically, in the measurement position table 61, the measurement positions m1 and m2 correspond to ID1, the measurement positions m3 and m4 correspond to ID2, and the measurement positions m5 and m6 correspond to ID3.

  In addition to the current measurement result and the phase comparison result, the wireless transmission unit 13 in the CT sensor 101 transmits the ID of its own CT sensor 101 in a wireless signal.

  The server 151 discriminates the measurement position where the measurement result or the comparison result included in the signal is obtained based on the ID included in the signal including the measurement result or the comparison result from the CT sensor 101A to the CT sensor 101C. Based on the measurement position, the power consumption is calculated by the method described with reference to FIGS.

  By the way, for example, in order to measure the amount of power consumption in a home where a solar cell is installed, whether the surplus power is being sold to the power system, or the generated power is not enough, and the power is sent from the power system to the home. It is necessary to determine whether the power is being purchased. In order to make such a determination, a method of measuring both current and voltage at home with a distribution board or the like is conceivable. However, it is difficult for the user to perform such measurement, and the number of persons who can perform measurement and installation of measuring instruments is often limited to qualified persons, which is expensive.

  On the other hand, in the power measurement system according to the embodiment of the present invention, CT sensor 101A measures the current flowing through power line 91 and power line 92 on the power system side with respect to the connection point between power lines 91 and 92 and load 121. Then, a signal indicating the measurement result is transmitted to the server 151. CT sensor 101 </ b> B measures the current flowing through power line 91 and power line 92 on the power generation device 106 side with respect to the connection point, and transmits a signal indicating the measurement result to server 151. The CT sensor 101C compares the phase of the current flowing through one of the power line 91 and the power line 92 on the power system side with the phase of the current flowing through one of the power line 91 and the power line 92 on the power generation device 106 side, and compares the comparison result. The indicated signal is transmitted to the server 151.

  With such a configuration, it is possible to easily measure each current in the house and the direction of the current between the power system and the power generation device 106.

  In addition, the configuration in which the current phase is compared using one CT sensor 101C eliminates the need for a circuit and wiring for synchronizing the current measurement timing between CT sensors, for example, and simplifies the device and system configuration. Can do.

  Further, in order to measure the current and the direction of the current in the house, for example, in a method using a measuring device having more current sensors than the CT sensor 101, there are a considerable number of homes where solar cells are not introduced. It is necessary to develop separate devices in introduced and unintroduced homes, which increases manufacturing costs. In contrast, the configuration using three CT sensors 101 having two current sensors as described above, it is only necessary to develop a common device for solar cell introduction homes and non-introduction homes, which reduces the manufacturing cost. Can be reduced.

  Therefore, in the power measurement system according to the embodiment of the present invention, the amount of power consumption can be measured at a low cost in a home where power can be supplied to the power system.

  In the power measurement system according to the embodiment of the present invention, the server 151 determines whether power is supplied from the power generation device 106 to the power system based on the comparison result of the CT sensor 101C. Based on the determination result, the measurement result of the CT sensor 101A, and the measurement result of the CT sensor 101B, the power consumption of the load 121 in the house is calculated.

  With such a configuration, it is possible to determine the power purchase state and the power sale state using the comparison result of the current phase by the CT sensor 101C, and to correctly calculate the power consumption in the house.

  Further, in the power measurement system according to the embodiment of the present invention, when the server 151 determines that power is supplied from the power generation device 106 to the power system, the server 151 calculates the CT sensor from the current measured by the CT sensor 101B. The power consumption based on the value obtained by subtracting the current measured by 101A is calculated. In addition, when the server 151 determines that the power supply from the power generation device 106 to the power system is not performed, the server 151 calculates power consumption based on the sum of the current measured by the CT sensor 101A and the current measured by the CT sensor 101B. calculate.

  With such a configuration, it is possible to correctly calculate the power consumption in the home by an appropriate calculation method according to the comparison result of the current phase by the CT sensor 101C.

  In the power measurement system according to the embodiment of the present invention, the server 151 performs measurement included in the signal based on identification information included in the signal including the measurement result or the comparison result from the CT sensor 101A to the CT sensor 101C. The measurement position where the result or the comparison result is obtained is determined, and the power consumption is calculated based on the determined measurement position.

  With such a configuration, the measurement position corresponding to the measurement result of the current received from each CT sensor 101 and the comparison result of the current phase can be specified.

  In the power measurement system according to the embodiment of the present invention, the server 151 includes a storage unit 161 for storing information indicating the correspondence between the identification information and the measurement position.

  With such a configuration, it is possible to acquire the correspondence between the measurement result and the measurement result of the current received from the CT sensor 101 and the comparison result of the current phase with a simple configuration.

  In the power measurement system according to the embodiment of the present invention, the presentation unit 15 in the CT sensor 101C presents information based on the comparison result.

  With such a configuration, the user can easily grasp whether the power purchase state or the power sale state is present, and thus the convenience for the user can be improved.

  In the CT sensor according to the embodiment of the present invention, the phase comparison unit 14 compares the phases of the currents measured by the current measurement units 11 and 12. The wireless transmission unit 13 transmits a signal indicating the measurement results of the current measurement units 11 and 12 and the comparison result of the phase comparison unit 14 to the server 151.

  With such a configuration, it is possible to easily measure each current in the house and the direction of the current between the power system and the power generation device 106.

  In addition, since the current phase can be compared by one CT sensor, for example, a circuit and wiring for synchronizing the current measurement timing between the CT sensors are not required, and the device and system configuration can be simplified. .

  Further, in order to measure the current and the direction of the current in the house, for example, in a method using a measuring device having more current sensors than the CT sensor 101, there are a considerable number of homes where solar cells are not introduced. It is necessary to develop separate devices in introduced and unintroduced homes, which increases manufacturing costs. On the other hand, the configuration using the CT sensor 101 having two current sensors as described above makes it possible to develop a common device for solar cell introduction homes and non-introduction homes, thereby reducing manufacturing costs. be able to.

  Therefore, the CT sensor according to the embodiment of the present invention can measure the amount of power consumption at low cost in a house where power can be supplied to the power system.

  The above embodiment should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 11, 12 Current measurement part 13 Wireless transmission part 14 Phase comparison part 15 Presentation part 16 Power calculation part 17 Antenna 71A, 71B, 71C Breaker 81 Master breaker 82 Branch breaker 83 PV breaker 91, 92 Power line 93 Neutral line 101, 101A , 101B, 101C CT sensor (power measurement slave unit)
102 Power distribution board 103 Wireless adapter 104 Home gateway 105 Power information display terminal 106 Power generation device 111 PCS
112 Solar cell 121 Electrical equipment (load)
121A, 121B, 121C load 151 server (power information processing apparatus)
161 Storage Unit 201 Power Measurement System 301 Internet

Claims (8)

A power measurement system for measuring power consumption of a load in a home provided with a first power line and a second power line connected to the power system, and a power generation device capable of supplying the generated power to the power system Because
The power generator is provided on the opposite side of the power system electrically with respect to a connection point between the first power line and the second power line and a load.
A first power measuring element for measuring a current flowing through the first power line and the second power line on the power system side with respect to the connection point and transmitting a signal indicating a measurement result to a power information processing apparatus. Machine,
Second power measurement for measuring the current flowing through the first power line and the second power line on the power generation device side with respect to the connection point, and transmitting a signal indicating the measurement result to the power information processing device With the handset,
The phase of the current flowing through one of the first power line and the second power line on the power system side, and the phase of the current flowing through one of the first power line and the second power line on the power generator side A power measurement system comprising: a third power measurement slave unit for comparing and transmitting a signal indicating a comparison result to the power information processing apparatus. The power measurement system further includes the power information processing apparatus,
The power information processing apparatus determines whether power is supplied from the power generation apparatus to the power system based on a comparison result of the third power measurement slave unit. The power measurement system according to claim 1, wherein the power consumption is calculated based on a measurement result of the first power measurement slave unit and a measurement result of the second power measurement slave unit. When the power information processing apparatus determines that power is supplied from the power generation apparatus to the power system, the power information processing apparatus uses the current measured by the second power measurement slave unit for the first power measurement. Calculate the power consumption based on the value obtained by subtracting the current measured by the slave unit,
When the power information processing apparatus determines that power is not supplied from the power generation apparatus to the power system, the current information measurement apparatus and the second power measurement apparatus use the current measured by the first power measurement slave unit. The power measurement system according to claim 2, wherein the power consumption is calculated based on a sum of currents measured by the slave units. The power measurement system further includes the power information processing apparatus,
The power information processing apparatus is configured to output the signal based on identification information included in the signal including the measurement result or the comparison result from the first power measurement slave unit to the third power measurement slave unit. 4. The power according to claim 1, wherein a measurement position where the measurement result or the comparison result included in the measurement result is obtained is determined, and the power consumption is calculated based on the determined measurement position. Measuring system. The power information processing apparatus
The power measurement system according to claim 4, further comprising a storage unit for storing information indicating a correspondence relationship between the identification information and the measurement position. The third power measuring slave unit is:
The power measurement system according to any one of claims 1 to 5, further comprising a presentation unit for presenting information based on the comparison result. A slave unit for power measurement used in the power measurement system according to claim 1,
Two current measuring units;
A phase comparison unit for comparing the phase of the current measured by each of the current measurement units;
A power measurement slave device comprising: a transmission unit configured to transmit a signal indicating a measurement result of each of the current measurement units and a comparison result of the phase comparison unit to a power information processing apparatus. A power measurement method for measuring power consumption of a load in a home provided with a first power line and a second power line connected to the power system and a power generation device capable of supplying the generated power to the power system. And
The power generator is provided on the opposite side of the power system electrically with respect to a connection point between the first power line and the second power line and a load.
The first power measurement slave unit measures the current flowing through the first power line and the second power line on the power system side with respect to the connection point, and transmits a signal indicating the measurement result to the power information processing apparatus. And steps to
A second power measuring slave unit measures the current flowing through the first power line and the second power line on the power generation device side with respect to the connection point, and sends a signal indicating the measurement result to the power information processing device. Sending, and
The third power measuring slave unit has a phase of a current flowing through one of the first power line and the second power line on the power system side, and the first power line and the second power line on the power generation device side. Comparing the phase of the current flowing through one of the power lines and transmitting a signal indicating the comparison result to the power information processing apparatus.

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