JP2015094749A - Power supply system, electric power measuring system, and measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power supply system, an electric power measuring system, and measuring device capable of eliminating time and labor for battery replacement and eliminating a period for which the device is inactive.SOLUTION: A power supply system includes a second current transformer CT2 provided on a first power cable PC1 connected between a distribution board DB and a load LD, detecting a first load AC current flowing in the first power cable PC1, and outputting a second detection AC current in response to a value of the detected first load AC current to a measuring device MD driven by electric power obtained from the second detection AC current.

Description

  The present invention relates to a power supply system, a power measurement system, and a measurement apparatus.

  Conventionally, the first important thing in the energy management system (EMS) aiming at efficient use of energy is to measure and monitor the current of the distribution board. When measuring and monitoring the current of the distribution board, a current sensor such as a current transformer (CT) detects the current (see, for example, Patent Document 1).

The power measurement unit measures the power supplied from the distribution board from the detection value of the current sensor.
The power measurement unit communicates with a HEMS (Home Energy Management System). For this purpose, a power source is required, and a battery is used as the power source, for example. In general, when a wireless LAN is used, power consumption requires 200 mA for transmission and 40 mA for reception. When Bluetooth (registered trademark) 4.0 is used, 10 mA is required for transmission and reception.

JP 2012-89516 A

  However, when a battery is used as a power source, it takes time to replace the battery when the battery runs out. In addition, when the battery runs out, the power measurement unit cannot measure the power transmitted between the distribution board and the load until the battery is replaced. As described above, there is a problem that a device driven by a battery cannot operate until the battery replacement is completed after the battery runs out.

  Accordingly, the present invention has been made in view of the above problems, and provides a power supply system, a power measurement system, and a measurement device that can eliminate the trouble of replacing the battery and the period during which the device cannot operate. With the goal.

A power supply system according to an aspect of the present invention includes:
A current transformer for detecting a load alternating current flowing in a power cable connected between a distribution board and a load, and outputting a detected alternating current signal corresponding to the detected value of the load alternating current; A current transformer is provided for supplying the power obtained from the above to a device driven by this power.

In the power supply system according to one aspect of the present invention,
The current transformer is a split type that can be installed while the power cable is connected to the distribution board and the load.

An electric power measurement system according to an aspect of the present invention includes:
The power supply system;
A measuring device for measuring the power transmitted between the distribution board and the load;
With
The current transformer supplies the detected AC signal to the measurement device that is driven by electric power obtained from the detected AC signal.

In the power measurement system according to one aspect of the present invention,
The measuring device is
A power supply circuit that outputs electric power according to the detected AC signal;
A controller that drives according to the power output from the power supply circuit and generates a current signal according to the value of the detected AC signal;
A communication unit that is driven according to the power output from the power supply circuit and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
With
The turn ratio of the current transformer is set so that the power output from the power supply circuit is less than the maximum power consumption of the measuring device.

In the power measurement system according to one aspect of the present invention,
The measurement device further includes a power storage device that charges the power output from the power supply circuit,
The control unit and the communication unit are driven by electric power supplied from the power storage device.

In the power measurement system according to one aspect of the present invention,
The measuring device is
A power supply circuit that outputs electric power according to the detected AC signal;
A power storage device for charging the power output from the power supply circuit;
A controller that is driven by the power supplied from the power storage device and generates a current signal according to the value of the detected AC signal;
A communication unit that is driven by power supplied from the power storage device and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
With
The turn ratio of the current transformer is set so that the power output from the power supply circuit becomes a preset power.

In the power measurement system according to one aspect of the present invention,
A plurality of current transformers are provided.

In the power measurement system according to one aspect of the present invention,
The current transformer is
A first power cable connected between the distribution board and the load, detecting a first load alternating current flowing through the first power cable, and detecting the detected first load alternating current; A first current transformer that outputs a first detected alternating current according to a value;
The first load alternating current provided in the first power cable and flowing through the first power cable is detected, and a second detected alternating current corresponding to the detected value of the first load alternating current is detected. A second current transformer for outputting,
The control unit generates the current signal based on the first detected alternating current output from the first current transformer,
The power supply circuit outputs electric power corresponding to the second detected alternating current output from the second current transformer,
The control unit and the communication unit are driven according to the power output from the power supply circuit.

A measurement device according to one embodiment of the present invention is provided.
Supplied from a power supply system including a current transformer that detects a load AC current flowing in a power cable connected between a distribution board and a load and generates a detected AC signal according to the detected value of the load AC current Driven by electric power obtained from the detected AC signal, a measurement device that wirelessly transmits a measurement result signal according to the detected AC signal,
A power supply circuit that outputs power according to the detected AC signal output by the current transformer;
A controller that drives according to the power output from the power supply circuit and generates a current signal according to the value of the detected AC signal output from the current transformer that detects the load AC current;
A communication unit that is driven according to the power output from the power supply circuit and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
Is provided.

  Therefore, the power supply system according to the present invention eliminates the trouble of replacing the battery and allows the apparatus to operate continuously.

FIG. 1 is a diagram illustrating an example of a configuration of a power measurement system 1 according to the first embodiment. FIG. 2 is a diagram illustrating an example of a configuration of the power measurement system 2 according to the second embodiment. FIG. 3 is a diagram illustrating an example of the configuration of the power measurement system 3 according to the third embodiment. FIG. 4 is a diagram illustrating an example of the configuration of the power measurement system 4 according to the fourth embodiment. FIG. 5 is a diagram illustrating an example of a configuration of the power measurement system 100 according to the comparative example.

(Comparative example)
Before describing the power measurement system according to each embodiment, a power measurement system 100 according to a comparative example will be described. As shown in FIG. 5, the power measurement system 100 according to the comparative example includes a distribution board DB, a load LD, a first power cable PC1 that electrically connects between the distribution board DB and the load LD, A second power cable PC2 that electrically connects the panel DB and the load LD is provided.

  Furthermore, the power measurement system 100 is provided in the first power cable PC1 connected between the distribution board DB and the load LD, and detects the first load alternating current flowing through the first power cable PC1. The first current transformer CT1 that outputs the first detected alternating current corresponding to the value of the first load alternating current is provided.

  Furthermore, the power measurement system 100 is provided in the second power cable PC2 connected between the distribution board DB and the load LD, and detects the second load alternating current flowing in the second power cable PC2. A second current transformer CT2 is provided that outputs a second detected AC current corresponding to the value of the detected second load AC current.

Furthermore, the power measurement system 100 includes a measurement device MD that measures the power transmitted between the distribution board DB and the load LD. This measuring device MD includes a measuring device MD that wirelessly transmits a measurement result signal corresponding to the first detected alternating current and the second detected alternating current.
Furthermore, the power measurement system 100 includes a HEMS 10 that receives a measurement result signal transmitted by the measurement device MD wirelessly.

The measuring device MD according to the comparative example includes a first terminal T1 electrically connected to the first current transformer CT1, a second terminal T2 electrically connected to the second current transformer CT2, and A battery X is provided.
Furthermore, the measuring apparatus MD according to the comparative example includes a control unit CON that is electrically connected to the battery X and electrically connected to the first terminal T1 and the second terminal T2.

  Here, the controller CON is driven by the power supplied from the battery X. The controller CON determines the polarities of the first load alternating current and the second load alternating current by comparing the phase of the first detected alternating current and the phase of the second detected alternating current. And the control part CON produces | generates the current signal containing the information regarding the magnitude | size of the 1st detection alternating current or the 2nd detection alternating current, and the information of the determined polarity, and outputs the produced | generated current signal to the communication part CM.

  Furthermore, the measuring device MD according to the comparative example includes a communication unit CM that is electrically connected to the battery X and electrically connected to the control unit CON. The communication unit CM is driven by the power supplied from the battery X, and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit CON to the HEMS 10. Here, the information based on the current signal is, for example, the amount of power supplied from the distribution board DB to the load LD. Thereby, HEMS10 can acquire the electric energy supplied to load LD from distribution board DB, and can monitor the electric energy consumed with load LD.

  In the power measurement system 100 according to the comparative example, when the battery X is used as a power source, troubles to replace the battery X occur when the battery runs out. Moreover, when the battery X runs out, there is a problem that the measuring device MD cannot measure the power supplied from the distribution board DB to the load LD until the battery is replaced.

  Therefore, in the following, a power measurement system and a measurement device that can eliminate the trouble of replacing the battery and the period during which the measurement device MD cannot operate will be described. Embodiments according to the present invention will be described below with reference to the drawings.

(First embodiment)
First, a first embodiment which is an aspect of the present invention will be described. The power measurement system 1 according to the first embodiment measures the power supplied to the load. As shown in FIG. 1, the power measurement system 1 according to the first embodiment includes a distribution board DB, a load LD, and a first power cable PC1 that electrically connects the distribution board DB and the load LD. And a second power cable PC2 for electrically connecting the distribution board DB and the load LD.

  Furthermore, the power measurement system 1 includes a power supply system PS that detects a load alternating current flowing through the first power cable PC1 and outputs a detection alternating signal corresponding to the detected value of the load alternating current.

Furthermore, the power measurement system 1 includes a measurement device MD that measures the power transmitted between the distribution board DB and the load LD. The measuring device MD wirelessly transmits a measurement result signal corresponding to the detected AC signal output from the power supply system PS.
Furthermore, the power measurement system 1 includes a HEMS 10 that receives a measurement result signal transmitted by the measurement device MD wirelessly. The HEMS 10 can monitor the power transmitted between the distribution board DB and the load LD based on the measurement result signal.

<About power supply system PS>
Here, the power supply system PS will be described. The power supply system PS is provided in the first power cable PC1 connected between the distribution board DB and the load LD, detects the first load alternating current flowing through the first power cable PC1, and detects the detected first current. A first current transformer CT1 that outputs a first detected AC current corresponding to the value of one load AC current.
Further, the power supply system PS is provided in the first power supply cable PC1, detects the first load alternating current flowing through the first power supply cable PC1, and detects the first load alternating current corresponding to the detected value of the first load alternating current. And a second current transformer CT2 that outputs the second detected AC current to the measuring device MD that is driven by the electric power obtained from the second detected AC signal.

Furthermore, the power supply system PS is provided in the second power cable PC2 connected between the distribution board DB and the load LD, and detects the second load alternating current flowing through the second power cable PC2. A third current transformer CT3 is provided that outputs a third detected alternating current corresponding to the detected value of the second load alternating current.
In addition, when the second current transformer CT2 alone is not sufficient for the amount of power necessary for the power supply, or for the purpose of reducing variation, the power supply system PS is provided in the second power cable PC2, The second load alternating current flowing in the second power cable PC2 is detected, and the fourth detected alternating current corresponding to the detected value of the second load alternating current is driven by the electric power obtained from the fourth detected alternating current signal. And a fourth current transformer CT4 that outputs to the measuring device MD.

  Here, as an example, the first current transformer CT1 and the second current transformer CT2 are clamped to the first power cable PC1 so that the first power cable PC1 is connected to the distribution board DB and the load LD. This is a split-type current transformer (split-type CT) that can be installed while connected. In addition, the third current transformer CT3 and the fourth current transformer CT4 are connected to the distribution board DB and the load LD by clamping the second power cable PC2 to the second power cable PC2, for example. This is a split-type current transformer (split-type CT) that can be installed as it is.

  The turns ratio of the first current transformer CT1 and the turns ratio of the second current transformer CT2 are set so that the second detected alternating current is larger than the first detected alternating current. Here, the turns ratio of the first current transformer CT2 determines the ratio of the first load alternating current and the first detected alternating current, and the turns ratio of the second current transformer CT2 is The ratio between the load alternating current and the second detected alternating current is determined.

  For example, the turn ratio of the first current transformer CT1 is set to 10,000: 1, and the turn ratio of the second current transformer CT2 is set to 10: 1. In this case, if the first load alternating current flowing from the distribution board DB to the load LD is 10 A, the first detected alternating current is 1 mA, whereas the second detected alternating current is 1 A. Thus, the second detected AC current can be made larger than the first detected AC current.

  Further, the turn ratio of the second current transformer CT2 and the turn ratio of the fourth current transformer CT4 are set so that the power output from the power supply circuit PSC is less than or equal to the maximum power consumption of the measuring device MD. As a result, the power output from the power supply circuit PSC becomes equal to or less than the maximum power consumption of the measuring device MD, so that the measuring device MD can be prevented from being damaged by excessive power.

<About measuring device MD>
The measuring device MD includes a first terminal T1 electrically connected to the output of the first current transformer CT1, a second terminal T2 electrically connected to the output of the second current transformer CT2, and a second terminal T2. A third terminal T3 electrically connected to the output of the third current transformer CT3, and a fourth terminal T4 electrically connected to the output of the fourth current transformer CT4.

Further, the measuring device MD includes a power supply circuit PSC that is electrically connected to the second terminal T2 and the fourth terminal T4 and outputs power corresponding to the detected AC signal output from the power supply system PS. Specifically, the power supply circuit PSC outputs power corresponding to the second and fourth detected alternating currents output from the second and fourth current transformers CT2 and CT4.
Further, the measuring device MD is electrically connected to the first terminal T1 and the third terminal T3, is driven according to the power output from the power supply circuit PSC, and is a detection AC signal output from the power supply system PS. The control part CON which produces | generates the electric current signal according to a value is provided. Specifically, the controller CON generates a current signal based on the first and third detected AC currents output from the first and third current transformers CT1 and CT3.

  The control unit CON compares the phase of the first detected AC current output from the first current transformer CT1 with the phase of the third detected AC current output from the third current transformer CT3. The polarities of the first load alternating current and the second load alternating current are determined. And the control part CON produces | generates the current signal containing the information regarding the magnitude | size of the 1st detection alternating current or the 2nd detection alternating current, and the information of the determined polarity, and outputs the produced | generated current signal to the communication part CM. This current signal is, for example, a pulse signal indicating either the first level (for example, “0”) or the second level (for example, “1”) at a constant period.

  Further, the measurement device MD is electrically connected to the power supply circuit PSC and the control unit CON, is driven according to the power output from the power supply circuit PSC, and includes measurement based on the current signal generated by the control unit CON. The result signal is transmitted to the HEMS 10 wirelessly. Here, the information based on the current signal is, for example, the amount of power supplied from the distribution board DB to the load LD. Thereby, HEMS10 can acquire the electric energy supplied to load LD from distribution board DB, and can monitor the electric energy consumed with load LD.

  As mentioned above, the electric power measurement system 1 which concerns on 1st Embodiment is an electric power measurement system which measures the electric power supplied to load, Comprising: The load which flows into the power cable connected between distribution board DB and load LD A power supply system PS that detects an alternating current and outputs a detected alternating current signal corresponding to the detected load alternating current value, and a measurement device MD that wirelessly transmits a measurement result signal corresponding to the detected alternating current signal. The measuring device MD is driven according to the power output from the power supply circuit PSC that outputs power corresponding to the detected AC signal output from the power supply system PS, and the power output from the power supply circuit PSC, and is output from the power supply system PS. A control unit CON that generates a current signal according to the value of the detected AC signal, and a measurement result signal that is driven according to the power output from the power supply circuit PSC and includes information based on the current signal generated by the control unit CON. And a communication unit CM that transmits wirelessly.

  In this way, since the control unit CON and the communication unit CM can be driven with electric power according to the detected AC signal output from the power supply system PS, there is no need for battery replacement. As a result, it is possible to eliminate the trouble of replacing the battery and the period during which the measuring device MD cannot operate.

  Furthermore, in this embodiment, 2nd current transformer CT2 and 4th current transformer CT4 are division | segmentation type CT. Thereby, the electric power for driving the control part CON and the communication part CM can be acquired by sandwiching the first power cable PC1 or the second power cable PC2 in the clamp of the split type CT. In this way, since no new cable routing work is required from the distribution board DB, there is an advantage that even a general user who is not qualified as an electrician can construct the power supply system PS according to the present embodiment.

(Second Embodiment)
Next, the second embodiment will be described. As shown in FIG. 2, the configuration of the power measurement system 2 in the second embodiment is charged with the power output from the power supply circuit PSC to the measurement device MD, compared to the configuration of the power measurement system 1 in the first embodiment. The power storage device SB to be added is added. Note that, in the power measurement system 2 according to the second embodiment, elements that are the same as those in the configuration of the power measurement system 1 according to the first embodiment are denoted by the same reference numerals, and a specific description thereof is omitted.

  Unlike the first embodiment, the control unit CON is electrically connected to the output of the power storage device SB instead of the output of the power supply circuit PSC, and the communication unit CM is not the output of the power supply circuit PSC but the power storage circuit PSC. It is electrically connected to the output of the device SB. Thereby, the control part CON and the communication part CM are driven by the electric power supplied from the power storage device SB.

  As a result, more current flows through the first power cable PC1 and the second power cable PC2 during the time when the power supply from the distribution board DB to the load LD is large, such as in the morning or at night. The alternating current and the third detected alternating current become larger. For this reason, the power storage device SB can store a large amount of electricity in a time zone in which the power supply from the distribution board DB to the load LD is large, such as in the morning or at night. As a result, the power storage device SB can stably supply power to the communication unit CM.

In the present embodiment, as an example, the turns ratio of the second current transformer CT2 and the turns ratio of the fourth current transformer CT4 are set so that the power output from the power supply circuit PSC becomes a preset power. ing. Here, the power output from the power supply circuit PSC may exceed the maximum power consumption of the measurement device MD, but the power supply of the power storage device SB so that the power supplied from the power storage device SB is less than or equal to the maximum power consumption of the measurement device MD. The capacity is set.
Further, as an example, the power storage device SB has a capacity that is equal to or greater than the power necessary for the operation of the communication unit CM. Thereby, the communication unit CM can communicate with the HEMS 10 more stably.

  As described above, the power measurement system 1 according to the second embodiment further includes the power storage device SB that charges the power output from the power supply circuit PSC, and the communication unit CM is driven by the power supplied from the power storage device SB. As a result, the power storage device SB can store more electricity in the time when the power supply from the distribution board DB to the load LD is large, such as in the morning or at night, and supplies power more stably to the communication unit CM. Can do. For this reason, in addition to the effects of the first embodiment, it is possible to prevent the communication unit CM from operating due to insufficient power. As a result, the communication unit CM can more stably transmit the measurement result signal to the HEMS 10 wirelessly, so that the HEMS 10 can always monitor the power transmitted between the distribution board DB and the load LD. it can.

  In the first and second embodiments, as an example, the power measurement systems 1 and 2 include the second current transformer in order to obtain power for driving the control unit CON and the communication unit CM included in the measurement device MD. Although two current sensors CT2 and fourth current transformer CT4 are provided, the present invention is not limited to this. The power measurement systems 1 and 2 may not include the fourth current transformer CT4, and may further include one or more current transformers. The one or more current transformers detect a load alternating current flowing in a power cable connected between the distribution board DB and the load LD, and detect a detected alternating current signal corresponding to the detected value of the load alternating current. The measurement device MD is supplied with electric power obtained from the detected AC signal.

(Third embodiment)
Subsequently, a third embodiment will be described. Note that, in the power measurement system 3 according to the third embodiment, elements common to the configuration of the power measurement system 1 according to the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. The power measurement systems 1 and 2 according to the first and second embodiments include the second current transformer CT2 and the fourth current transformer CT4, and the power supply circuit PSC includes the second and fourth current transformers. The electric power according to the 2nd and 4th detection alternating current which CT4 output was output.

  On the other hand, in the power measurement system 3 according to the third embodiment, the wiring branches from the first terminal T1, the first detected alternating current is input also to the power supply circuit PSC, and the wiring is connected from the third terminal T3. The third detection AC current is branched and input to the power supply circuit PSC. Further, the first terminal T1 and the power supply circuit PSC are electrically connected, and the third terminal T3 and the power supply circuit PSC are electrically connected. As a result, the first detection AC current and the third detection AC current are also input to the power supply circuit PSC.

  The power supply circuit PSC supplies power corresponding to the first and third detected AC currents to the control unit CON and the communication unit CM. This eliminates the need for the second current transformer CT2 and the fourth current transformer CT4, and as shown in FIG. 3, the configuration of the power measurement system 3 in the third embodiment is the same as that in the first embodiment. The configuration in which the second current transformer CT2 and the fourth current transformer CT4 are deleted and the second terminal T2 and the fourth terminal T4 are deleted from the measuring device MD with respect to the configuration of the power measurement system 1 in FIG. It has become.

  As described above, the power measurement system 3 according to the third embodiment does not need to be provided with the second current transformer CT2 and the fourth current transformer CT4 as compared with the power measurement system 1 according to the first embodiment. Therefore, there is an advantage that the trouble of installing them can be eliminated and the cost can be reduced.

(Fourth embodiment)
Subsequently, a fourth embodiment will be described. As shown in FIG. 4, the configuration of the power measurement system 4 in the fourth embodiment is charged with the power output from the power supply circuit PSC to the measurement device MD, compared to the configuration of the power measurement system 3 in the third embodiment. The power storage device SB is added. Note that in the power measurement system 4 according to the fourth embodiment, elements common to the configuration of the power measurement system 3 according to the third embodiment are denoted by the same reference numerals, and a specific description thereof is omitted.

  Unlike the third embodiment, the control unit CON is electrically connected to the output of the power storage device SB instead of the output of the power supply circuit PSC, and the communication unit CM is not the output of the power supply circuit PSC but the power storage circuit PSC. It is electrically connected to the output of the device SB. Thereby, the control part CON and the communication part CM are driven by the electric power supplied from the power storage device SB.

  As a result, more current flows through the first power cable PC1 and the second power cable PC2 during the time when the power supply from the distribution board DB to the load LD is large, such as in the morning or at night. The alternating current and the third detected alternating current become larger. For this reason, the power storage device SB can store a large amount of electricity in a time zone in which the power supply from the distribution board DB to the load LD is large, such as in the morning or at night. As a result, the power storage device SB can supply power to the communication unit CM more stably.

  Similar to the second embodiment, the power storage device SB has, as an example, a capacity that is equal to or greater than the power necessary for the operation of the communication unit CM. Thereby, the communication unit CM can communicate with the HEMS 10 more stably.

  As described above, the power measurement system 4 according to the fourth embodiment further includes a power storage device that charges the power output from the power supply circuit PSC, as in the second embodiment, and the communication unit CM is supplied from the power storage device SB. Driven by the generated power. As a result, the power storage device SB can store a large amount of electricity in a time zone in which the power supply from the distribution board DB to the load LD is large, such as morning or night, and can stably supply power to the communication unit CM. it can. For this reason, in addition to the effects of the first and third embodiments, the power storage device SB can prevent a situation in which the communication unit CM cannot operate due to power shortage. As a result, since the communication unit CM can wirelessly transmit the measurement result signal to the HEMS 10 without stopping, the HEMS 10 can always monitor the power transmitted between the distribution board DB and the load LD. it can.

  In each embodiment, as an example, the power supply system PS detects a load alternating current flowing in a power cable connected between the distribution board DB and the load LD, and according to the detected load alternating current value. However, the present invention is not limited to this, but includes a current transformer that supplies the detected AC signal to a device (here, measuring device MD as an example) that is driven by electric power obtained from the detected AC signal.

  In each embodiment, as an example, the power measurement systems 1 to 4 include the first current transformer CT1 and the third current transformer CT1 in order to determine the polarities of the first load alternating current and the second load alternating current. Although the two current sensors of the current transformer CT3 are provided, the present invention is not limited to this. When it is not necessary to determine the polarity, the power measurement systems 1 to 4 may include either the first current transformer CT1 or the third current transformer CT3. For example, when the power measuring system 1 includes the first current transformer CT1, the control unit CON performs the first detection based on the first detected alternating current output from the first current transformer CT1. A current signal indicating the magnitude of the alternating current may be generated.

  In addition, embodiment is an illustration and the range of invention is not limited to them.

1, 2, 3, 4, 100 Power measurement system DB Distribution board LD Load PC1 First power cable PC2 Second power cable CT1 First current transformer CT2 Second current transformer CT3 Third current transformer CT4 Fourth current transformer PS Power supply system 10 HEMS
MD measuring device T1 first terminal T2 second terminal T3 third terminal T4 fourth terminal PSC power circuit CON control unit CM communication unit SB power storage device

Claims (9)

A current transformer for detecting a load alternating current flowing in a power cable connected between a distribution board and a load, and outputting a detected alternating current signal corresponding to the detected value of the load alternating current; A power supply system that supplies the power obtained from the system to devices driven by this power. The power supply system according to claim 1, wherein the current transformer is a split type that can be installed while the power cable is connected to the distribution board and the load. The power supply system according to claim 1 or 2,
A measuring device for measuring the power transmitted between the distribution board and the load;
With
The current transformer supplies the detected AC signal to the measurement device that is driven by power obtained from the detected AC signal. The measuring device is
A power supply circuit that outputs electric power according to the detected AC signal;
A controller that drives according to the power output from the power supply circuit and generates a current signal according to the value of the detected AC signal;
A communication unit that is driven according to the power output from the power supply circuit and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
With
The power measurement system according to claim 3, wherein a turn ratio of the current transformer is set so that power output from the power supply circuit is equal to or less than a maximum power consumption of the measurement device. The measurement device further includes a power storage device that charges the power output from the power supply circuit,
The power measurement system according to claim 4, wherein the control unit and the communication unit are driven by power supplied from the power storage device. The measuring device is
A power supply circuit that outputs electric power according to the detected AC signal;
A power storage device for charging the power output from the power supply circuit;
A controller that is driven by the power supplied from the power storage device and generates a current signal according to the value of the detected AC signal;
A communication unit that is driven by power supplied from the power storage device and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
With
The power measurement system according to claim 3, wherein a turn ratio of the current transformer is set so that power output from the power supply circuit is preset power. The power measuring system according to claim 3, comprising a plurality of the current transformers. The current transformer is
A first power cable connected between the distribution board and the load, detecting a first load alternating current flowing through the first power cable, and detecting the detected first load alternating current; A first current transformer that outputs a first detected alternating current according to a value;
The first load alternating current provided in the first power cable and flowing through the first power cable is detected, and a second detected alternating current corresponding to the detected value of the first load alternating current is detected. A second current transformer for outputting,
The control unit generates the current signal based on the first detected alternating current output from the first current transformer,
The power supply circuit outputs electric power corresponding to the second detected alternating current output from the second current transformer,
The power measurement system according to claim 3, wherein the control unit and the communication unit are driven according to the power output from the power supply circuit. Supplied from a power supply system including a current transformer that detects a load AC current flowing in a power cable connected between a distribution board and a load and generates a detected AC signal according to the detected value of the load AC current Driven by electric power obtained from the detected AC signal, a measurement device that wirelessly transmits a measurement result signal according to the detected AC signal,
A power supply circuit that outputs power according to the detected AC signal output by the current transformer;
A controller that drives according to the power output from the power supply circuit and generates a current signal according to the value of the detected AC signal output from the current transformer;
A communication unit that is driven according to the power output from the power supply circuit and wirelessly transmits a measurement result signal including information based on the current signal generated by the control unit;
A measuring device comprising:

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