JPWO2013121508A1 - Power meter - Google Patents

Abstract

The main unit M generates a voltage detection signal obtained by stepping down the circuit voltage to be measured, outputs the generated voltage detection signal to the signal line 12, and a correction for correcting an error in the voltage detection signal. A correction information storage unit 14a that stores information, and a calculation unit 14 that corrects the voltage detection signal using the correction information stored in the correction information storage unit 14a and obtains power using the corrected voltage detection signal. The extension unit Si corrects the information acquisition unit 23a that acquires the correction information from the main unit M and the voltage detection signal input via the signal line 21 using the correction information acquired by the information acquisition unit 23a. And an arithmetic unit 23 for obtaining electric power using the corrected voltage detection signal.

Description

  The present invention generally relates to a power meter configured by connecting an extension unit to a main unit.

  2. Description of the Related Art Conventionally, there has been a power measuring instrument composed of a main unit and an extension unit, and this power measuring instrument is configured by connecting (sequentially connecting) one or more extension units to the main unit. Then, the signal path between the main unit and the extension unit is formed by electrically connecting the main unit and the extension unit by a signal line. A conventional power measuring instrument is disclosed in Japanese Patent Application Publication No. 2005-55404.

  The main unit generates a voltage detection signal obtained by stepping down the circuit voltage to be measured, and outputs the generated voltage detection signal to the signal line. The main unit includes a calculation unit connected to the signal line, and the calculation unit calculates the power in the measurement target using the voltage detection signal input via the signal line. Specifically, not only the circuit voltage of the measurement target but also the measurement result of the circuit current of the measurement target is obtained, and the power in the measurement target is measured by performing power calculation using the detected value of the voltage and current. .

  The extension unit receives a voltage detection signal from the main unit via the signal line. The extension unit includes a calculation unit connected to the signal line, and the calculation unit calculates the power in the measurement target using the voltage detection signal input via the signal line. Specifically, not only the circuit voltage of the measurement target but also the measurement result of the circuit current of the measurement target is obtained, and the power in the measurement target is measured by performing power calculation using the detected value of the voltage and current. .

  Then, the main unit acquires power measurement data from each of the extension units, and manages each measurement data of the main unit and the extension unit.

  However, the voltage detection signal output from the main unit to the signal line includes an error with respect to the actual circuit voltage. For example, when the circuit voltage is divided using a resistor, the voltage detection signal includes an error due to the accuracy of the resistor. The voltage detection signal transmitted through the signal line causes a voltage drop due to the impedance of the signal line, and includes an error due to this voltage drop. The power measurement value calculated using the voltage detection signal including such an error has a reduced accuracy.

  Therefore, in order to reduce the error of the voltage detection signal, conventionally, circuit voltage detection means has been configured using highly accurate parts. Moreover, the error of the voltage detection signal is corrected by adjusting the voltage detection signal with a volume (variable resistor). However, these methods have a problem that the cost of parts and the number of adjustment steps increase in order to reduce the error of the voltage detection signal.

  The present invention has been made in view of the above-described reasons, and an object of the present invention is to provide a power measuring instrument that can easily reduce a detection error of a circuit voltage used for power calculation at low cost.

  The power meter of the present invention is a power meter comprising a main unit and an extension unit that are electrically connected to each other via a signal line, and configured to increase or decrease the number of the extension units. The unit generates a voltage detection signal obtained by stepping down the circuit voltage to be measured, outputs the generated voltage detection signal to the signal line, and correction information for correcting an error in the voltage detection signal A correction information storage unit that stores the voltage detection signal, and a first calculation unit that corrects the voltage detection signal using the correction information stored in the correction information storage unit and obtains electric power using the corrected voltage detection signal. The extension unit includes an information acquisition unit that acquires the correction information from the main unit, and the voltage detection signal input via the signal line is acquired by the information acquisition unit. Corrected using the information, characterized in that it comprises a second arithmetic unit for determining the power using the corrected voltage detection signal.

  According to this invention, since the main unit and the extension unit use the voltage detection signal with the error corrected, it is possible to perform highly accurate power calculation. In addition, it is not necessary to use high-precision parts for the voltage detection unit, and it is not necessary to adjust the voltage detection signal with a volume (variable resistor). Thus, it becomes possible to reduce the detection error of the circuit voltage used for the power calculation at a low cost and to perform the power calculation with high accuracy.

  In one embodiment, the correction information is a correction coefficient indicating a deviation of the voltage detection signal with respect to the actual circuit voltage.

  According to this embodiment, the error of the voltage detection signal can be corrected.

  In one embodiment, the correction information storage unit is composed of a nonvolatile memory.

  According to this embodiment, correction information can be held even when the main unit is powered off. Therefore, even when the main unit is restarted after the power is turned off, the correction process using the correction information can be performed.

  In one embodiment, at the time of activation, the main unit transmits the correction information stored in the correction information storage unit to the extension unit, and the information acquisition unit of the extension unit transmits from the main unit. The corrected information is acquired.

  According to this embodiment, it is possible to transmit correction information to all connected extension units regardless of addition or deletion of extension units. That is, the extension unit can correct the voltage detection signal using the correction information received from the main unit even immediately after connection.

  In one embodiment, the correction information is information for correcting an error of the voltage detection signal generated by the voltage detection unit.

  According to this embodiment, a voltage detection signal in which an error caused by the accuracy of the voltage detection unit is corrected can be used.

  In one embodiment, the one main unit and the plurality of extension units are connected in series via the signal line, and the correction information corrects a voltage drop of the voltage detection signal due to the impedance of the signal line. It is information for.

  According to this embodiment, a voltage detection signal in which a voltage drop due to the impedance of the signal line is corrected can be used. The error of the voltage detection signal increases as the extension unit is farther from the main unit, but the error of the voltage detection signal can be accurately corrected regardless of the connection order of the extension units.

  In one embodiment, the main body unit includes a plurality of voltage detection units, and the correction information storage unit stores the correction information corresponding to each of the plurality of voltage detection units.

  According to this embodiment, since the error of the voltage detection signal generated for each phase can be corrected using the correction coefficient for each phase, the accuracy of power calculation for each phase is improved.

Preferred embodiments of the invention are described in further detail. Other features and advantages of the present invention will be better understood with reference to the following detailed description and accompanying drawings.
1 is a block diagram illustrating a configuration of a first embodiment. It is a sequence diagram which shows a communication process same as the above. 6 is a block diagram showing a configuration of Embodiment 2. FIG. (A)-(c) It is a wave form diagram which shows the address signal same as the above.

(Embodiment 1)
As shown in FIG. 1, the power measuring instrument of the present embodiment is composed of one main unit M and one or more extension units Si (i = 1, 2,..., N). One to a plurality of extension units Si are connected (sequentially connected) to the main unit M. This power measuring instrument uses a three-phase four-wire power circuit as a measurement target, three-phase (R, S, T) voltages Vr, Vs, Vt, and three-phase (R, S, T) currents Ir, Is and It are detected and power calculation is performed. Note that the voltages Vr, Vs, and Vt correspond to the circuit voltage of the present invention.

  First, the main unit M includes voltage detection units 11r, 11s, and 11t, signal lines 12r, 12s, and 12t, a signal conversion unit 13, a calculation unit 14 (first calculation unit), and a correction information storage unit 14a. The control unit 15 and the communication line 16 are provided as main components.

  The voltage detectors 11r, 11s, and 11t are connected to each phase of the power circuit and detect circuit voltages Vr, Vs, and Vt. In addition, when not distinguishing the voltage detection parts 11r, 11s, and 11t, it calls the voltage detection part 11. FIG.

  The voltage detection unit 11 includes resistors 111 and 112 connected in series between both ends of the circuit voltages Vr, Vs, and Vt, and an amplification unit 113 to which the voltage (divided voltage) at the connection point of the resistors 111 and 112 is input. Prepare. The amplifying unit 113 places the output voltage waveform in a predetermined range (for example, 0 to 5 V) by applying a bias to the divided voltage. And the output of each amplification part 113 of voltage detection part 11r, 11s, 11t is connected to signal line 12r, 12s, 12t. That is, the output of the voltage detector 11 is a voltage detection signal obtained by stepping down the circuit voltages Vr, Vs, Vt, and this voltage detection signal is output to the signal lines 12r, 12s, 12t.

  The signal conversion unit 13 is connected to the current detection units 17r, 17s, and 17t. The current detection units 17r, 17s, and 17t are configured by a current transformer (CT) and output current values corresponding to the currents Ir1, Is1, and It1 of each phase. The signal conversion unit 13 converts each current output of the current detection units 17r, 17s, and 17t into a voltage, and outputs detection signals (current detection signals) of the currents Ir1, Is1, and It1.

  The calculation unit 14 is configured by a microcomputer, and receives a voltage detection signal via the signal lines 12r, 12s, and 12t, and further receives a current detection signal from the signal conversion unit 13. The calculation unit 14 performs A / D conversion on the voltage detection signal and the current detection signal, and performs power calculation by multiplying the voltage detection signal and the current detection signal.

  An output connector CN1 connected to the signal lines 12r, 12s, and 12t is provided on at least one side surface of the main unit M.

  The control unit 15 is configured by a microcomputer, and is connected to the calculation unit 14 and also to the communication line 16. The communication line 16 is connected to a communication connector CN4 provided on at least one side surface of the main unit M.

  Next, the extension unit Si includes signal lines 21r, 21s, and 21t, a signal conversion unit 22, a calculation unit 23 (second calculation unit), an information acquisition unit 23a, and a communication line 24 as main components. Prepare.

The signal lines 21r, 21s, and 21t are connected to an input connector CN2 provided on one side surface of the extension unit Si and an output connector CN3 provided on the other side surface of the extension unit Si. The input connector CN2 of the extension unit S1 is connected to the output connector CN1 of the main unit M, and the output connector CN3 of the extension unit S1 is connected to the input connector CN2 of the extension unit S2. Furthermore, the output connector CN3 of the extension unit S2 is connected to the input connector CN2 of the extension unit S3. Thereafter, similarly, the input connector CN2 of the extension unit Si is connected to the output connector CN3 of the preceding extension unit S _i-1 .

  Thus, the signal lines 12r, 12s, 12t of the main unit M are electrically connected to the respective signal lines 21r, 21s, 21t of the extension unit Si, and the respective signal lines 21r, 21s, 21t of the extension unit Si. A voltage detection signal is transmitted to.

  The signal conversion unit 22 is connected to the current detection units 25r, 25s, and 25t. The current detection units 25r, 25s, and 25t are configured by a current transformer (CT) and have a function of outputting current values corresponding to the currents Ir2, Is2, and It2 of each phase. The signal converter 22 converts each current output of the current detectors 25r, 25s, and 25t into a voltage, and outputs detection signals (current detection signals) of the currents Ir2, Is2, and It2.

  The calculation unit 23 is configured by a microcomputer, and receives a voltage detection signal via the signal lines 21r, 21s, and 21t, and further receives a current detection signal from the signal conversion unit 22. And the calculating part 23 performs power calculation by A / D-converting a voltage detection signal and a current detection signal, and multiplying a voltage detection signal and a current detection signal.

  The currents Ir1, Is1, It1 detected by the main unit M and the currents Ir2, Is2, It2 detected by the extension unit Si are different currents in the three-phase four-wire power circuit to be measured. It is. For example, the currents Ir1, Is1, and It1 are main currents, and the currents Ir2, Is2, and It2 are branch currents. Furthermore, the detection locations of the currents Ir2, Is2, and It2 are different for each extension unit Si. In addition, in a three-phase four-wire power circuit, a configuration may be employed in which each power of a three-phase four-wire system and a single-phase two-wire system is detected.

The calculation unit 23 includes an information acquisition unit 23 a, and the information acquisition unit 23 a is connected to the communication line 24. The communication line 24 is connected to a communication connector CN5 provided on one side of the extension unit Si and a communication connector CN6 provided on the other side of the extension unit Si. The communication connector CN5 of the extension unit S1 is connected to the communication connector CN4 of the main unit M, and the communication connector CN6 of the extension unit S1 is connected to the communication connector CN5 of the extension unit S2. Further, the communication connector CN6 of the extension unit S2 is connected to the communication connector CN5 of the extension unit S3. Thereafter, similarly, the communication connector CN5 of the expansion unit Si is connected to the communication connector CN6 of the previous expansion unit S _i-1 .

  Thus, each of the main unit M and the plurality of extension units Si is configured to be able to communicate with each other via the communication lines 16 and 24.

  Here, the voltage detection signal generated by the voltage detection unit 11 includes errors due to the accuracy of the resistance values of the resistors 111 and 112, the accuracy of the amplification unit 113, and the like. That is, the voltage detection signal includes an error caused by the voltage detection unit 11. Therefore, the main unit M and the extension unit Si correct the voltage detection signal by performing the following operation. The error in the voltage detection signal includes an error in the magnitude of the voltage detection signal, an error due to the offset of the voltage detection unit 11, and the like.

  First, the calculation unit 14 of the main unit M includes a correction information storage unit 14a that is a nonvolatile memory. The correction information storage unit 14a stores correction information for correcting an error in the voltage detection signal. The correction information is a correction coefficient indicating a deviation of the voltage detection signal (voltage detection signal at the output terminal of the voltage detection unit 11) generated by the voltage detection unit 11 with respect to the actual circuit voltages Vr, Vs, and Vt. The correction coefficient Kr1 for the phase voltage detection signal, the correction coefficient Ks1 for the S phase voltage detection signal, and the correction coefficient Kt1 for the T phase voltage detection signal. Then, the calculation unit 14 multiplies each of the R-phase, S-phase, and T-phase voltage detection signals input via the signal lines 12r, 12s, and 12t by correction coefficients Kr1, Ks1, and Kt1, thereby detecting the voltage. Correct the signal. The corrected voltage detection signal is obtained by correcting errors due to the accuracy of the resistance values of the resistors 111 and 112, the accuracy of the amplifier 113, and the like.

  For example, when the main body unit M is manufactured, how much the voltage detection signal at the output end of the voltage detection unit 11 is deviated from the design (theoretical) value is experimentally measured in advance for the circuit voltages Vr, Vs, and Vt. . The correction coefficients Kr1, Ks1, and Kt1 are set based on the test results and stored in the correction information storage unit 14a. When there is no deviation of the voltage detection signal with respect to the design (theoretical) value, the correction coefficient K1 (Kr1, Ks1, Kt1) is set to “1”.

  Specifically, the correction coefficient K1 is K1 = actual circuit voltage / circuit voltage measurement value. For example, in the state where the correction coefficient K1 = 1, when the actual circuit voltage = 100.0V and the measured value of the circuit voltage = 99.0V, the correction coefficient K1 = 100.0 / 99.0 = 1.010101. Information (correction information) of this correction coefficient K1 = 1.010101 is stored in the correction information storage unit 14a. Thereafter, the calculation unit 14 corrects the voltage detection signal by multiplying the voltage detection signal by the correction coefficient K1 = 1.010101.

  Further, at the start-up when the main unit M is turned on and starts operating, the control unit 15 acquires the data (correction information) of the correction coefficients Kr1, Ks1, and Kt1 from the correction information storage unit 14a, and the extension unit Si. The correction information addressed to each is sent to the communication line 16. This correction information is transmitted from the communication line 16 of the main unit M to the communication line 24 of the extension unit Si. The information acquisition unit 23a of the extension unit Si acquires correction information from the main unit M by receiving correction information addressed to itself among signals on the communication line 24.

  For example, the extension unit Si is supplied with power from the main unit M via a power line (not shown). When the expansion unit Si is added or deleted, the main unit M is turned off and the power supply to the expansion unit Si is also stopped. Then, after the addition unit Si is added or deleted, the main unit M is activated, and power is also supplied to the extension unit Si. Thus, as described above, when the main unit M is started up, the main unit M transmits correction information to the extension unit Si, so that all connected expansions are added regardless of addition or deletion of the extension unit Si. Correction information can be transmitted to the unit Si. That is, the extension unit Si can correct the voltage detection signal using the correction information received from the main unit M even immediately after connection.

  FIG. 2 shows a communication sequence between the main unit M and the extension unit Si.

  First, when the main unit M is activated, the control unit 15 transmits an information acquisition request to the calculation unit 14 (Ya). The calculation unit 14 that has received the information acquisition request transmits the correction information in the correction information storage unit 14a to the control unit 15, and the control unit 15 acquires the correction information (Yb). Then, the control unit 15 sequentially transmits the correction information to each of the extension units Si (Yc1, Yc2, Yc3,...). The information acquisition unit 23a of the extension unit Si that has acquired the correction information returns an acquisition response to the control unit 15 of the main unit (Yd1, Yd2, Yd3,...).

  Then, the arithmetic unit 23 of the extension unit Si multiplies each of the R-phase, S-phase, and T-phase voltage detection signals input via the signal lines 21r, 21s, and 21t by correction coefficients Kr1, Ks1, and Kt1, respectively. To correct the voltage detection signal. The corrected voltage detection signal is obtained by correcting errors due to the accuracy of the resistance values of the resistors 111 and 112, the accuracy of the amplifier 113, and the like.

  Therefore, since the main unit M and the extension unit Si use the voltage detection signal in which the error by the voltage detection unit 11 is corrected, high-accuracy power calculation can be performed. In addition, it is not necessary to use high-precision parts for the voltage detection unit 11, and it is not necessary to adjust the voltage detection signal with a volume (variable resistor). Thus, it becomes possible to reduce the detection error of the circuit voltage used for the power calculation at a low cost and to perform the power calculation with high accuracy.

  Moreover, since the calculating parts 14 and 23 perform power calculation using the digital signal which A / D-converted the voltage detection signal and the current detection signal, the correction process is facilitated and the noise resistance is also improved.

  Further, since the main unit M stores the correction information in the correction information storage unit 14a, which is a nonvolatile memory, the correction information can be held even when the main unit M is powered off. Therefore, even when the main unit M is restarted after the power is turned off, the correction process using the correction information can be performed. Even if the extension unit Si is connected to a host device such as a server (not shown) via a network and acquires correction information from the host device, the same effect as described above can be obtained.

  Further, the correction information may be a voltage value indicating a deviation of the voltage detection signal with respect to the actual circuit voltages Vr, Vs, and Vt. That is, the correction information may be in any form as long as it is information indicating the deviation of the voltage detection signal with respect to the actual circuit voltages Vr, Vs, Vt.

  In addition, voltage detection units 11r, 11s, and 11t that independently detect circuit voltages Vr, Vs, and Vt of three phases (R, S, and T) are provided, and the correction information includes correction coefficients Kr1, Ks1 for each phase. , Kt1. The voltage detection signals for each phase are independently corrected by multiplying the R phase, S phase, and T phase voltage detection signals by correction coefficients Kr1, Ks1, and Kt1, respectively. Therefore, the error of the voltage detection signal generated for each phase can be corrected using the correction coefficient for each phase, so that the accuracy of power calculation for each phase is improved.

(Embodiment 2)
The power measuring instrument of the present embodiment has the configuration shown in FIG. 3, and the same reference numerals are given to the same configurations as those of the first embodiment, and the description thereof is omitted.

  As the correction information of the present embodiment, correction coefficients Kr2, Ks2, and Kt2 that indicate deviations of the voltage detection signals on the signal lines 12r, 12s, and 12t and the signal lines 21r, 21s, and 21t are used.

  The main unit M and the plurality of extension units Si are connected in series via signal lines 12r, 12s, 12t and signal lines 21r, 21s, 21t. Accordingly, the voltage detection signals on the signal lines 12r, 12s, 12t and the signal lines 21r, 21s, 21t increase in voltage drop due to the impedance of the signal line as the distance from the output ends of the voltage detection units 11r, 11s, 11t increases. That is, the amplitude of the voltage detection signal acquired by the extension unit Si from the main unit M is S1, S2, S3,. . . The error gradually becomes smaller and the error becomes larger. Therefore, in the present embodiment, the correction for correcting both the shift of the voltage detection signal due to the accuracy of the voltage detection unit 11 and the voltage drop of the voltage detection signal due to the impedance of the signal lines 12r, 12s, 12t and the signal lines 21r, 21s, 21t. Coefficients Kr2, Ks2, and Kt2 are used.

  These correction coefficients Kr2, Ks2, and Kt2 are correction coefficients Kr20, Ks20, and Kt20 of the main unit M and correction coefficients Kr2i, Ks2i, and Kt2i of the extension unit Si, and are stored in the correction information storage unit 14a. The correction coefficients Kr2i, Ks2i, and Kt2i of the extension unit Si are set according to the connection order of the extension units Si. Specifically, the correction coefficients Kr21, Ks21, Kt21 of the extension unit S1, the correction coefficients Kr22, Ks22, Kt22 of the extension unit S2, the correction coefficients Kr23, Ks23, Kt23,. . . It becomes. When the correction coefficients Kr20, Ks20, Kt20 and the correction coefficients Kr2i, Ks2i, Kt2i are not distinguished, they are referred to as correction coefficients Kr2, Ks2, Kt2.

  For example, when the main body unit M is manufactured, how much the voltage detection signal at the output terminal of the voltage detection unit 11 deviates from the actual circuit voltages Vr, Vs, Vt is experimentally measured in advance. Further, voltage drops in the signal lines 12r, 12s, and 12t of the main unit M are derived in advance. At this time, since the extension unit Si that is actually combined with the main unit M is not specified, the voltage drop in the signal lines 21r, 21s, and 21t uses, for example, an average value based on a number of actual measurement results, simulations, and the like. The correction coefficients Kr2, Ks2, and Kt2 are set based on these measurement results and simulation results, and stored in the correction information storage unit 14a.

  Then, the calculation unit 14 of the main unit M reads the correction coefficients Kr20, Ks20, and Kt20 from the correction information storage unit 14a. The calculation unit 14 multiplies each of the R-phase, S-phase, and T-phase voltage detection signals input via the signal lines 12r, 12s, and 12t by the correction coefficients Kr20, Ks20, and Kt20, thereby obtaining the voltage detection signal. to correct. The corrected voltage detection signal is obtained by correcting the error due to the voltage drop due to the accuracy of the voltage detection unit 11 and the impedance of the signal lines 12r, 12s, and 12t.

  Here, the extension unit Si has different correction coefficients Kr2i, Ks2i, and Kt2i used for correcting the voltage detection signal depending on the connection order. Therefore, in order for the extension unit Si to recognize its own connection order, the following processing is performed.

  First, the main unit M includes a signal generation unit 18, and an output connector CN 7 connected to the output of the signal generation unit 18 is provided on at least one side surface of the main unit M.

  On the other hand, the extension unit Si includes an address generation unit 26. The input of the address generator 26 is connected to an input connector CN8 provided on one side of the extension unit Si, and the output of the address generator 26 is connected to an output connector CN9 provided on the other side of the extension unit Si.

The input connector CN8 of the extension unit S1 is connected to the output connector CN7 of the main unit M, and the output connector CN9 of the extension unit S1 is connected to the input connector CN8 of the extension unit S2. Further, the output connector CN9 of the extension unit S2 is connected to the input connector CN8 of the extension unit S3. Thereafter, similarly, the input connector CN8 of the expansion unit Si is connected to the output connector CN9 of the previous expansion unit S _i-1 .

  The signal generation unit 18 of the main unit M transmits an address signal having a cycle T1 that alternately repeats the H level and the L level shown in FIG. 4A to the next expansion unit S1. The address generation unit 26 of the extension unit S1 recognizes the connection order “1” by receiving the address signal of the period T1. Then, the address generation unit 26 of the extension unit S1 transmits an address signal having a cycle T2 (= T1 × 2) in which the H level and the L level shown in FIG. 4B are alternately repeated to the next-stage extension unit S2. To do. The address generation unit 26 of the extension unit S2 recognizes the connection order “2” by receiving the address signal having the period T2. Then, the address generation unit 26 of the extension unit S2 transmits an address signal having a period T3 (= T1 × 3) in which the H level and the L level shown in FIG. 4C are alternately repeated to the next-stage extension unit S3. To do.

  Thereafter, similarly, the address generation unit 26 of the extension unit Si can recognize its own connection order with respect to the main unit M by the cycle of the address signal received from the previous stage.

  Then, when the main unit M is turned on and starts operating, the control unit 15 acquires the data (correction information) of the correction coefficients Kr2i, Ks2i, and Kt2i from the correction information storage unit 14a. Send it out. This correction information is transmitted from the communication line 16 of the main unit M to the communication line 24 of the extension unit Si. That is, the communication line 24 of the extension unit Si has correction coefficients Kr21, Ks21, Kt21, correction coefficients Kr22, Ks22, Kt22, correction coefficients Kr23, Ks23, Kt23,. . . Each piece of information is transmitted.

  The information acquisition unit 23a of the extension unit Si receives correction coefficients Kr2i, Ks2i, and Kt2i corresponding to its own connection order among signals on the communication line 24 based on the connection order recognized by the address generation unit 26. Thus, the extension unit Si can acquire its own correction information from the main unit M. For example, the extension unit S1 receives the correction coefficients Kr21, Ks21, Kt21 corresponding to its own connection order “1”, and the extension unit S2 receives the correction coefficients Kr22, Ks22, Kt22 corresponding to its own connection order “2”. Receive.

  Then, the arithmetic unit 23 of the extension unit Si multiplies each of the R-phase, S-phase, and T-phase voltage detection signals input via the signal lines 21r, 21s, and 21t by correction coefficients Kr2i, Ks2i, and Kt2i, respectively. To correct the voltage detection signal. The corrected voltage detection signal is obtained by correcting the error due to the voltage drop due to the accuracy of the voltage detection unit 11, the impedance of the signal lines 12r, 12s, and 12t, and the signal lines 21r, 21s, and 21t.

  Therefore, the main body unit M and the extension unit Si use voltage detection signals in which not only errors due to the voltage detection unit 11 but also voltage drops due to the impedance of the signal lines are corrected, so that more accurate power calculation can be performed. Further, the error of the voltage detection signal becomes larger as the extension unit Si is farther from the main unit M. However, by using the correction information considering the connection order of the extension units Si, the voltage detection signal is used regardless of the connection order of the extension units Si. Can be accurately corrected.

  Further, in each of the above-described embodiments, the main unit M and the extension unit Si include the signal conversion units 13 and 22 that detect circuit current, one by one. However, a plurality of signal conversion units 13 and 22 may be provided so that a single unit can measure a circuit current at a plurality of locations.

  The measurement target of the power meter may be, for example, a three-phase three-wire type, a single-phase three-wire type, or a single-phase two-wire type power circuit other than the three-phase four-wire type power circuit.

  While the invention has been described in terms of several preferred embodiments, various modifications and variations can be made by those skilled in the art without departing from the true spirit and scope of the invention, ie, the claims.

Claims (7)

A power measuring instrument comprising a main unit and an extension unit that are electrically connected to each other via a signal line, and configured to increase or decrease the number of the extension units,
The main unit is
A voltage detection unit that generates a voltage detection signal obtained by stepping down a circuit voltage to be measured, and outputs the generated voltage detection signal to the signal line;
A correction information storage for storing correction information for correcting an error of the voltage detection signal;
A first calculation unit that corrects the voltage detection signal using the correction information stored in the correction information storage unit and obtains electric power using the corrected voltage detection signal;
The extension unit is
An information acquisition unit for acquiring the correction information from the main unit;
A second calculation unit that corrects the voltage detection signal input via the signal line using the correction information acquired by the information acquisition unit and obtains power using the corrected voltage detection signal; A power meter characterized by comprising.   The power measuring device according to claim 1, wherein the correction information is a correction coefficient indicating a deviation of the voltage detection signal with respect to an actual circuit voltage.   The power measuring device according to claim 1, wherein the correction information storage unit includes a nonvolatile memory. The main unit, upon startup, transmits the correction information stored in the correction information storage unit to the extension unit,
The power meter according to any one of claims 1 to 3, wherein the information acquisition unit of the extension unit acquires the correction information transmitted from the main unit.   5. The power measuring instrument according to claim 1, wherein the correction information is information for correcting an error of the voltage detection signal generated by the voltage detection unit.   One main unit and a plurality of extension units are connected in series via the signal line, and the correction information is information for correcting a voltage drop of the voltage detection signal due to the impedance of the signal line. The power measuring instrument according to any one of claims 1 to 5, wherein   The main body unit includes a plurality of the voltage detection units, and the correction information storage unit stores the correction information corresponding to each of the plurality of voltage detection units. Power meter.

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