JP2020112510A - Computer program for determining wire connection state of electronic watthour meter - Google Patents

Abstract

To provide means capable of easily determining presence/absence of erroneous wire connection of wires to be connected to an electronic watthour meter.SOLUTION: Measurement value input means 21 inputs various types of measurement data from an electronic watthour meter 2 as measurement values. Calculation means 23 calculates theoretical values of the measurement values on the basis of a load value input by load value input means 22. Table creation means 24 creates a table of prescribing a relation between a combination of the theoretical values and the respective connection states of the wires. Comparison means 25 compares the combination of the measurement values input by the measurement value input means 21 with each combination of theoretical values prescribed to the table created by the table creation means 24. Determination means 26 determines a combination of the theoretical values having respective values compatible with the combination of the measurement values from the comparison result of the comparison means 25, and specifies a connection state of wires according to the determined combination of the theoretical values.SELECTED DRAWING: Figure 2

Description

The present invention relates to a computer program that determines the connection state of wiring connected to an electronic watt hour meter.

2. Description of the Related Art Conventionally, for example, there is a normal weighing confirmation device disclosed in Patent Document 1 as a device for determining a connection state of wiring connected to an electronic watt hour meter. This normal weighing confirmation device combines a simulated power supply device and a watt hour meter error measuring device to determine instrument failure and incorrect wiring of the weighing device even when the load at the time of new customer installation is not in operation. .. The simulated power supply device includes a test plug that fits into the test SW1 connected between the instrument and the VCT, and a simulated load circuit formed by a step-down Tr. Based on the error threshold stored in advance, the normal weighing confirmation device determines "no misconnection" and "no instrument failure" when the error calculated by the watt-hour meter error measuring device is less than or equal to the threshold value. If the error calculated by the meter error measuring device exceeds the threshold value, it is determined that "misconnection" or "failure of meter".

Patent No. 6373019

However, the above-described conventional normal weighing confirmation apparatus requires the simulated power supply apparatus and the watt-hour meter error measuring device to determine whether or not there is a misconnection in the watt-hour meter. Therefore, it is necessary to prepare these devices in order to determine whether or not there is a misconnection in the watt-hour meter, and complicated work such as connecting the devices is required, so that the misconnection can be easily performed. The presence or absence could not be determined.

The present invention has been made to solve such problems,
Computer,
Measurement value input means for inputting the active power value and reactive power value of the load measured by the electronic watt-hour meter as measurement values, load value input means for inputting the load value of the load, and the load is electronic power Connected to the electronic watt-hour meter, and a calculation means for calculating the theoretical value of the measurement value measured by the electronic watt-hour meter when connected to the meter based on the load value input by the load-value input means. Table creating means for creating a table defining the relationship between the combination of theoretical values calculated by the calculating means when the load is connected to the electronic watt-hour meter in each connection state of the wiring and each connection state of the wiring And comparison means for comparing the combination of the measurement values input by the measurement value input means with each combination of the theoretical values defined in the table created by the table creation means, and each value matching the combination of the measurement values. A program was constructed to determine the combination of theoretical values from the comparison result of the comparison means and to function as a determination means for specifying the connection state of the wiring according to the determined combination of the theoretical values.

According to this configuration, the effective power value of the load measured by the electronic watt-hour meter when the load of the load value input by the load-value input means is connected to the electronic watt-hour meter in each connection state of the wiring. A table that defines the relationship between the combination of the theoretical value of the reactive power value and each connection state of the wiring is created by the table creating means. Then, the combination of the measured values of the active power value and the reactive power value of the load input by the measured value input means and the active power value and the reactive power value of the load defined in the table created by the table creation means Each theoretical combination is compared by the comparison means. From the comparison result of the comparison means, the determination means determines the combination of theoretical values having respective values corresponding to the combination of the measured values, and the connection state of the wiring specified in the table is specified for the determined combination of theoretical values. To be done.

Therefore, by causing the computer to execute a program that causes the computer to function as each of the above means, it becomes possible to determine the connection state of the wiring connected to the electronic watt hour meter. For this reason, it is not necessary to prepare a special device as in the conventional case, and the complicated work of connecting each device is not performed, and the wiring connected to the electronic watt-hour meter can be easily configured. It is possible to determine the presence/absence of misconnection.

Further, the present invention is
The measurement value input means inputs, as the second measurement value, the active power value and the reactive power value of the load and the voltage phase difference between the plurality of phases measured by the electronic watt hour meter for the plurality of phases of the three-phase power supply,
The calculation means inputs, by the load value input means, a theoretical value of the second measurement value measured by the electronic watt hour meter for a plurality of phases of the three-phase power source when the load is connected to the electronic watt hour meter. Calculate as the second theoretical value based on the load value,
A table for defining a relationship between a combination of the second theoretical values calculated by the calculating unit when the load is connected to the electronic watt-hour meter in each connection state of the wiring and each connection state of the wiring. Create
The comparing means compares the combination of the second measured values input by the measured value inputting means with each combination of the second theoretical values defined in the table created by the table creating means,
The discriminating means discriminates a combination of the second theoretical values having respective values suitable for the combination of the second measured values from the comparison result of the comparing means, and the wiring of the wiring specified in the table is discriminated for the discriminated combination of the second theoretical values. It is characterized by specifying the connection state.

According to this configuration, the types of measured values measured by the electronic watt-hour meter and their theoretical values increase. Therefore, in the table created by the table creating means, the combination of theoretical values can be defined for more connection states of the wirings connected to the electronic watt hour meter. Therefore, it is possible to increase the number of wiring connection states that can be identified by the determination unit, and it is possible to identify the wiring connection state in more detail.

In addition, the present invention further includes a computer, an information input unit for inputting meter information of the electronic watt-hour meter and setting information set in the electronic watt-hour meter, and a connection state of the wiring specified by the determination unit. It is characterized by functioning as data output means for outputting information as data together with instrument information and setting information inputted by the information input means.

According to this configuration, when the electronic watt hour meter is installed, the load is connected to the electronic watt hour meter as the simulated load, and the combination of the measured values of the simulated load input by the measured value input means is defined in the table. By comparing with each combination of theoretical values, before connecting the actual load to the electronic watt-hour meter, before connecting the actual load to the electronic watt-hour meter, along with the connection status of the wiring connected to the electronic watt-hour meter, the instrument information and setting information of the electronic watt-hour meter are set. Can be obtained as data. Therefore, before connecting the actual load to the electronic watt-hour meter, it is possible to accurately grasp the installation state of the electronic watt-hour meter and objectively and accurately convey the installation state to a third party. Will be possible. In addition, even after the electronic watt-hour meter is installed, the load connection state of the electronic watt-hour meter can be accurately grasped and the load connection state can be objectively and accurately transmitted to a third party. It becomes possible to do.

According to the present invention, it is possible to provide a means capable of easily determining the presence or absence of misconnection of wiring connected to an electronic watt hour meter.

1 is a connection diagram of a personal computer to which a computer program according to an embodiment of the present invention is applied and an electronic watt-hour meter. 2 is a block diagram showing an internal configuration of the personal computer shown in FIG. 1. FIG. It is a 1st table figure which compares with the table created by the computer program by one embodiment, and the measured value input from an electronic watt-hour meter. It is a 2nd table figure which shows the table created by the computer program by one embodiment, and the measured value input from an electronic watt-hour meter for comparison. It is a 3rd table figure which compares with the table created by the computer program by one embodiment, and the measured value input from an electronic watt-hour meter.

Next, a mode for carrying out the computer program for determining the wiring connection state of the electronic watt hour meter according to the present invention will be described.

FIG. 1 shows a personal computer (hereinafter referred to as a PC) 1 to which a wiring connection state determination computer program of an electronic watt hour meter according to an embodiment of the present invention is applied as an application, and an electronic watt hour meter 2. It is a connection diagram.

The electronic watt-hour meter 2 is configured by incorporating parts such as an electronic circuit board in a rectangular parallelepiped casing. The electronic watt-hour meter 2 includes a display unit 2a for displaying the measured value on the front surface thereof, and a terminal unit 2b below which each wiring is connected. The electronic watt-hour meter 2 in the present embodiment is a three-phase, three-wire type, and the P1 terminal of the terminal portion 2b is connected from the power supply wiring of the one-phase, two-phase, and three-phase power supplies of the three-phase power supply through the VT (voltage converter). , P2 terminals and P3 terminals are supplied with power supply voltage. The P1 terminal is connected to the VT output terminal 1u, the P2 terminal is grounded to the output terminals 1v and 3u, and the P3 terminal is connected to the output terminal 3v. Between the output terminals 1u and 1v of the VT, the voltage between the first and second phases of the three-phase power source appears, and between the output terminals 3u and 3v, the voltage between the two and three phases of the three-phase power source appears. Therefore, the voltage between the first and second phases of the three-phase power supply is applied between the terminals P1 and P2, and the voltage between the three and two phases of the three-phase power supply is applied between the terminals P3 and P2.

The simulated load 3 is connected to the three-phase power supply. The simulated load 3 is a load for confirming the wiring connection when the electronic watt-hour meter 2 is installed, and its load capacity is known in advance. By connecting the simulated load 3, a phase current according to the load capacity of the simulated load 3 flows in the first phase and the third phase of the three-phase power supply. The phase current flowing in one phase of the three-phase power supply is detected between the 1S terminal and the 1L terminal of the terminal portion 2b through the output terminals 1K and 1L of the CT (current converter) from the power wiring of the one phase, and the three phases are detected. The phase current flowing in the terminal is detected between the 3S and 3L terminals of the terminal portion 2b through the output terminals 3K and 3L of the CT from the three-phase power supply wiring. The 1L terminal and the 3L terminal are grounded together with the P2 terminal.

The electronic watt-hour meter 2 multiplies the 1-side voltage V1 applied between the P1 terminal and the P2 terminal by the 1-side current detected between the 1S terminal and the 1L terminal to obtain the signed 1-side active power. W1 and 1-side reactive power var1 are calculated. Further, by multiplying the 3 side voltage V3 applied between the P3 terminal and the P2 terminal by the 3 side current detected between the 3S terminal and the 3L terminal, the signed 3 side active power W3 and the 3 side reactive power are added. Calculate var3. Then, the combined active power ΣW of the 1-side active power W1 and the 3-side active power W3, and the combined reactive power Σvar of the 1-side reactive power var1 and the 3-side reactive power var3 are calculated and displayed on the display unit 2a. The electronic watt-hour meter 2 also calculates a voltage phase difference θp1-p3 between the first-side voltage V1 and the third-side voltage V3.

The electronic watt-hour meter 2 has an infrared communication port and a metering pulse output port (not shown) on its front surface. From this infrared communication port, various measurement data measured by the electronic watt-hour meter 2 is output to the outside of the electronic watt-hour meter 2 by infrared rays. In the present embodiment, as the measurement data, active power amount, reactive power amount, active power (total active power ΣW), reactive power (total reactive power Σvar), and the like are output. The infrared communication port also outputs meter information of the electronic watt hour meter 2 and setting information set in the electronic watt hour meter 2. In the present embodiment, as the meter information, a meter ID for identifying the manufacturing number and the manufacturing year of the electronic watt-hour meter 2, the phase line type of the electronic watt-hour meter 2, the rated voltage, and the rated current are output. Further, as the setting information, the multiplication factor for the display value of the display unit 2a, the transformation ratio constant of VT/CT, the pulse type of the metering pulse output from the metering pulse output port, the pulse constant and the pulse width are output.

The PC 1 detects the infrared rays output from the infrared communication port by the sensor 4, and inputs various measurement data measured by the electronic watt-hour meter 2 via the cable 5 together with the instrument information and the setting information. In this embodiment, the communication between the electronic watt-hour meter 2 and the PC 1 is performed by infrared communication, but the same applies to other communication methods such as a serial communication method such as RS485, a current loop communication method, and a wireless communication method. Can be done.

FIG. 2 is a block diagram showing a schematic configuration in the PC 1. In the PC 1, a CPU (Central Processing Unit) 13 performs various calculations according to a program stored in a ROM (Read Only Memory) 11 using a RAM (Read/Write Memory) 12 as a temporary storage work area. By this calculation according to the program stored in the ROM 11, the CPU 13 causes the PC 1 which is a computer to change the measured value input unit 21, the load value input unit 22, the calculation unit 23, the table creation unit 24, the comparison unit 25, the determination unit 26, It functions as the information input means 27 and the data output means 28.

The measured value input means 21 includes various kinds of active power values and reactive power values of the simulated load 3 measured by the electronic watt-hour meter 2 from the electronic watt-hour meter 2 via the sensor 4 and the cable 5. Enter the measurement data as the measurement value. The load value input means 22 inputs the load value of the simulated load 3 from the keyboard 14 of the PC 1 or the like. The calculation means 23 uses the theoretical value of the measured value measured by the electronic watt-hour meter 2 when the simulated load 3 is connected to the electronic watt-hour meter 2 as the load value input by the load-value input means 22. Calculate based on The table creating means 24 is a combination of theoretical values calculated by the calculating means 23 when the simulated load 3 is connected to the electronic watt-hour meter 2 in each connection state of the wires connected to the electronic watt-hour meter 2. , Create a table that defines the relationship between each wiring connection state. The comparison means 25 compares the combination of measured values input by the measured value input means 21 with each combination of theoretical values defined in the table created by the table creation means 24. The discriminating means 26 discriminates a combination of theoretical values having respective values matching the combination of measured values input by the measured value inputting means 21 from the comparison result of the comparing means 25. Then, the connection state of the wiring corresponding to the determined combination of theoretical values is specified by referring to the table created by the table creating means 24.

In this embodiment, the measured value input means 21 uses the signed 1-side active power W1 [W] of the simulated load 3 measured by the electronic watt-hour meter 2 on the one-phase side and the three-phase side of the three-phase power supply. 1-side reactive power var1[var], signed 3-side active power W3[W] and 3-side reactive power var3[var], and voltage phase difference θp1-p3 between 1-side voltage V1 and 3-side voltage V3 Each value is input as the second measurement value. The calculation means 23 is a theoretical value of the second measured value measured by the electronic watt-hour meter 2 on the first-phase side and the three-phase side of the three-phase power source when the simulated load 3 is connected to the electronic watt-hour meter 2. Is calculated as the second theoretical value based on the load value input by the load value input means 22. The table creating means 24 combines the combination of the second theoretical values calculated by the calculating means 23 when the simulated load 3 is connected to the electronic watt-hour meter 2 in each wiring connection state and each wiring connection state. Create a table that defines the relationship. The comparison means 25 compares the combination of the second measurement values input by the measurement value input means 21 with each combination of the second theoretical values defined in the table created by the table creation means 24. The discriminating means 26 discriminates a combination of the second theoretical values having respective values corresponding to the combination of the second measured values from the comparison result of the comparing means 25, and the discriminated combination of the second theoretical values is defined in the table. Specify the wiring connection status.

The information input unit 27 inputs the instrument information of the electronic watt-hour meter 2 and the setting information set in the electronic watt-hour meter 2 from the electronic watt-hour meter 2 via the sensor 4 and the cable 5. The data output unit 28 outputs the information on the connection state of the wiring specified by the determination unit 26 as data together with the instrument information and the setting information input by the information input unit 27. This data is output from the USB port 15 provided in the PC 1 according to the USB standard and output as PDF data or table data, or to the printer 16 and output on paper.

3 to 5 show a part of the table created by the table creating means 24. In this table, a connection diagram showing each connection state of the wiring connected to the electronic watt-hour meter 2 and a connection terminal correspondence table showing the connection relationship between each terminal corresponding to the connection diagram are shown. Although the combination of the second theoretical values calculated by the calculation means 23 when the simulated load 3 is connected to the electronic watt-hour meter 2 in each connection state of the wiring is not shown in the table, the table does not show the combination. , And the relationship between each connection state of the illustrated wirings and the combination of the second theoretical values (not shown) calculated by the calculation means 23.

Each value of the combination of the second theoretical values defined in the table is compared with the second measurement value input by the measurement value input means 21 by the comparison means 25. The measurement results shown in the same figure next to the table indicate values such as the second measurement value input by the measurement value input means 21 when the wirings shown in the side by side table are connected. Each of these second measured values shown in the measurement result is obtained when the simulated load 3 is an R load in the image of a pure resistance such as a dryer having a power factor of 1.0 and when the simulated load 3 has a power factor of 0. The values are measured for the case where the C load is an image of a 0 capacitor and the case where it is a C load. In order to simplify the calculation, the simulated load 3 has a secondary line voltage of 100 [V] and a load current of 5 [A]. Therefore, in the present embodiment, the line voltage 100 [V] and the load current 5 [A] are input to the load value input means 22 as load values.

To identify the connection state of the wiring connected to the electronic watt-hour meter 2, the 1-side active power W1 [W] and the 1-side reactive power var1 [var] and the 3-side active power W3, which are represented by the measurement results, are shown. Only the second measured values of [W] and the three-side reactive power var3[var] and the voltage phase difference θp1-p3 are referred to. That is, the measured values of the total active power ΣW[W] and the total reactive power Σvar[var], and the first-side voltage V1[V] and the third-side voltage V3[V] are not referred to when the connection state of the wiring is specified. The values of the first-side voltage V1 and the third-side voltage V3 are used to confirm that the three-phase power supply wiring is connected to the electronic watt-hour meter 2.

The table shown at the top of FIG. 3 shows a connection diagram and a connection terminal correspondence table when the wiring connected to the electronic watt-hour meter 2 is normally connected.

The measurement results arranged in the table when the wiring is normally connected are the values input from the electronic watt-hour meter 2 by the measurement value input means 21 when the wiring is normally connected. These values are defined in a table created by the table creating means 24 with respect to a normal connection state of the wiring, and are within a predetermined range of respective values of a combination of second theoretical values (not shown), for example, a combination of the second theoretical values. Is within ±10% of each value of.

Therefore, the 1st side active power W1 and the 1st side reactive power var1 and the 3rd side active power W3 of the comparison result of the comparison means 25 and the second measurement value input from the electronic watt-hour meter 2 by the measurement value input means 21. And the three-side reactive power var3, and all the measured values of the voltage phase difference θp1-p3 among the combinations of the second theoretical values (not shown) specified in the table for the normal connection state of the wiring. When the value is within the range of ±10% of each value corresponding to the value, the determining unit 26 determines that the combination of the second theoretical values is a value matching the combination of the measurement values input by the measurement value input unit 21. Is determined to have. In this case, the discriminating means 26 identifies the normal connection state of the wiring as the connection state of the wiring connected to the electronic watt-hour meter 2.

In addition, the table No. of FIG. E1 shows a connection diagram and connection terminal correspondence table when only the voltage circuit wiring is erroneously connected. The connection diagram and connection terminal correspondence table at the time of erroneous connection of only the voltage circuit wiring include the following table in addition to the illustrated table NoE1, but the illustration thereof is omitted.

Table No. E1 stipulates that the wiring connection between the output terminal 1u and the output terminal 1v of the VT has an erroneous connection. That is, the wiring shown by the broken line in the connection diagram, and the P1 terminal should be connected to the output terminal 1u of the VT, but is erroneously connected to the output terminal 1v, as shown by the bold italic type in the connection terminal correspondence table. Where the terminals should be connected to the output terminals 1v, 3u and G (ground/ground) of the VT, they are erroneously connected to the output terminals 1u, 3u and G.

Table No. The measurement result lined up in E1 is a value input from the electronic watt-hour meter 2 by the measurement value input means 21 when the wiring connection between the output terminal 1u and the output terminal 1v of the VT has the above-mentioned erroneous connection. Of these values, the measured values of the 1-side active power W1 and 1-side reactive power var1 and the voltage phase difference θp1-p3 of the R load, which are shown in italicized bold type in the figure, and the 1-side of the C load The measured values of the active power W1, the one-side reactive power var1 and the voltage phase difference θp1-p3 are defined for the connection state having the above-mentioned erroneous connection in the table created by the table creating means 24. Of the respective values of the combination of theoretical values, the values are out of the range of ±10% of the respective values corresponding to the respective measured values. The respective values of the second measured values other than these input by the measured value input means 21 are within ±10% of the respective values corresponding to the respective measured values among the respective values of the combination of the second theoretical values (not shown). It fits inside.

Therefore, the 1 side active power W1 of the R load, the 1 side reactive power var1 and the voltage level of the second measurement value input from the electronic watt-hour meter 2 by the measurement value inputting means 21 as a result of the comparison by the comparing means 25. Only the measured values of the phase difference θp1-p3 or only the measured values of the 1-side active power W1 and 1-side reactive power var1 and the voltage phase difference θp1-p3 of the C load for the connection state in which the above-mentioned misconnection is made. When the combination of the second theoretical values (not shown) defined in the table is out of the range of ±10% of each value corresponding to each measured value, the determining unit 26 determines that the combination of the second theoretical values is It is determined that each of the values has a value that matches the combination of the measured values input by the measured value input means 21. In this case, the determining unit 26 identifies a connection state in which the above-mentioned erroneous connection is present in the wiring connection between the output terminal 1u and the output terminal 1v of the VT, as the connection state of the wiring connected to the electronic watt hour meter 2.

Further, the table No. of FIG. A1 and No. A2 shows a connection diagram and connection terminal correspondence table when only the current circuit wiring is erroneously connected. The connection diagram and connection terminal correspondence table at the time of incorrect connection of only the current circuit wiring are shown in the illustrated table No. A1 and No. In addition to A2, there are also subsequent tables, but their illustration is omitted.

Table No. A1 stipulates that there is an erroneous connection in the wiring connection between the 1S terminal and the 1L terminal. That is, the wiring shown by the broken line in the connection diagram, and the 1S terminal should be connected to the output terminal 1K of the CT, as shown by the italicized bold type in the connection terminal correspondence table, but are erroneously connected to the output terminals 1L and G. , 1L terminals should be connected to the CT output terminals 1L and G, but are erroneously connected to the output terminal 1K.

Table No. The measurement results lined up in A1 are the values input from the electronic watt-hour meter 2 by the measurement value input means 21 when the wiring connection between the 1S terminal and the 1L terminal has the above-mentioned erroneous connection. Of these values, the measured values of the 1-side active power W1 and the 1-side reactive power var1 of the R load, and the 1-side active power W1 and the 1-side reactive of the C load, which are indicated by bold italics in the figure, are shown. Each measured value of the electric power var1 is a measured value among the respective values of the combination of the second theoretical values (not shown) that are defined for the connection state having the above-mentioned incorrect connection in the table created by the table creation means 24. Is outside the range of ±10% of each value corresponding to. The respective values of the second measured values other than these input by the measured value input means 21 are within ±10% of the respective values corresponding to the respective measured values among the respective values of the combination of the second theoretical values (not shown). It fits inside.

Therefore, each of the 1-side active power W1 and the 1-side reactive power var1 of the R load in the second measurement value input from the electronic watt-hour meter 2 by the measurement value input means 21 by the comparison result of the comparison means 25. Only the value, or each measured value of the 1-side active power W1 and the 1-side reactive power var1 of the C load is a combination of a second theoretical value (not shown) defined in the table for the connection state with the above-mentioned incorrect connection. When the value is out of the range of ±10% of each value corresponding to each measured value, the determination unit 26 determines that the combination of the second theoretical values is the combination of the measured values input by the measured value input unit 21. It is determined that each value is matched. In this case, the discriminating means 26 identifies the connection state in which the above-mentioned erroneous connection is present in the wiring connection between the 1S terminal and the 1L terminal as the connection state of the wiring connected to the electronic watt-hour meter 2.

Table No. A2 stipulates that there is an erroneous connection in the wiring connection between the 3S terminal and the 3L terminal. That is, the wiring shown by the broken line in the connection diagram, and the 3S terminal should be connected to the output terminal 3K of the CT, but is erroneously connected to the output terminals 3L and G, as shown by the bold italic type in the connection terminal correspondence table. Where the 3L terminal should be connected to the CT output terminals 3L and G, it is erroneously connected to the output terminal 3K.

Table No. The measurement results lined up in A2 are the values input from the electronic watt-hour meter 2 by the measurement value input means 21 when the wiring connection between the 3S terminal and the 3L terminal has the above-mentioned erroneous connection. Of these values, the measured values of the R-side three-side active power W3 and the three-side reactive power var3, and the three-side active power W3 and the three-side reactive of the C load, which are shown in italicized bold type in the figure, are shown. Each measured value of the electric power var3 is a measured value out of the respective values of the combination of the second theoretical values (not shown) defined for the connection state in which the above-mentioned misconnection is made in the table created by the table creation means 24. Is outside the range of ±10% of each value corresponding to. The respective values of the second measured values other than these input by the measured value input means 21 are within ±10% of the respective values corresponding to the respective measured values among the respective values of the combination of the second theoretical values (not shown). It fits inside.

Therefore, among the comparison result of the comparison means 25 and the second measurement value input from the electronic watt-hour meter 2 by the measurement value input means 21, each measurement of the 3 side active power W3 and the 3 side reactive power var 3 of the R load is performed. Only the values, or only the measured values of the three-side active power W3 and the three-side reactive power var3 of the C load, are the combinations of the second theoretical values (not shown) defined in the table for the connection state with the above-mentioned incorrect connection. When the value is out of the range of ±10% of each value corresponding to each measured value, the determination unit 26 determines that the combination of the second theoretical values is the combination of the measured values input by the measured value input unit 21. It is determined that each value is matched. In this case, the discriminating means 26 identifies the connection state in which the above-mentioned erroneous connection is present in the wiring connection between the 3S terminal and the 3L terminal as the connection state of the wiring connected to the electronic watt-hour meter 2.

Further, the table No. of FIG. EA1, No. EA2 and No. EA3 shows a connection diagram and a connection terminal correspondence table at the time of incorrect connection of the combination of the voltage circuit wiring and the current circuit wiring. The connection diagram and connection terminal correspondence table at the time of these incorrect connections are shown in Table No. EA1, No. EA2 and No. Other than EA3, there are also subsequent tables, but their illustration is omitted.

Table No. In EA1, it is specified that the wirings on the 1st phase side and the 3rd phase side are exchanged to be in the reverse phase connection state, and there is an erroneous connection in the wiring connection between the 1st phase side P1 terminal and the 3rd phase side P3 terminal. There is. That is, the wiring shown by the broken line in the connection diagram, and the P1 terminal should be connected to the output terminal 1u of the VT, but is erroneously connected to the output terminal 3v, as shown by the bold italic type in the connection terminal correspondence table. Where the terminal should be connected to the output terminal 3v of the VT, it is erroneously connected to the output terminal 1u. Due to this erroneous connection of the voltage circuit wiring, the 1S terminal is erroneously connected to the output terminal 3K where it should be connected to the CT output terminal 1K, and the 1L terminal is where it should be connected to the CT output terminals 1L and G. And G are erroneously connected. Further, the 3S terminal should be connected to the output terminal 3K of the CT, and the 3L terminal should be connected to the output terminals 3L and G of the CT, and the 3L terminal should be connected to the output terminals 1L and G. There is.

Table No. The measurement results lined up in EA1 are values input from the electronic watt-hour meter 2 by the measurement value input means 21 when the above-mentioned erroneous connection is made in the wiring connection between the P1 terminal on the one-phase side and the P3 terminal on the three-phase side. .. Among these values, the measured values of the 1-side reactive power var1 and the 3-side reactive power var3 of the R load, and the 1-side active power W1 and the 3-side effective of the C load, which are indicated by bold italics in the figure, are shown. Each measurement value of the electric power W3 is a measurement value among the respective values of the combination of the second theoretical values (not shown) that is defined for the connection state in which the above-mentioned misconnection is made in the table created by the table creating means 24. Is outside the range of ±10% of each value corresponding to.

Note that the measured value of the voltage phase difference θp1-p3 of the R load and the measured value of the voltage phase difference θp1-p3 of the C load input by the measured value input means 21 are also combinations of the second theoretical values (not shown). Of each value, it is outside the range of ±10% of each value corresponding to each measured value. However, since the connection state of the above-mentioned incorrect connection of the wiring can be identified without referring to the measured value of the voltage phase difference θp1-p3, the measured value of the voltage phase difference θp1-p3 is compared by the comparison means 25 here. Not included in the target. The respective values of the second measured values other than these input by the measured value input means 21 are within ±10% of the respective values corresponding to the respective measured values among the respective values of the combination of the second theoretical values (not shown). It fits inside.

Therefore, of the comparison result of the comparison means 25 and each of the first-side reactive power var1 and the third-side reactive power var3 of the R load in the second measurement value input from the electronic watt-hour meter 2 by the measurement value input means 21. Only the values or only the measured values of the 1-side active power W1 and the 3-side active power W3 of the C load are the combinations of the second theoretical values (not shown) defined in the table for the connection state with the above-mentioned incorrect connection. When the value is out of the range of ±10% of each value corresponding to each measured value, the determination unit 26 determines that the combination of the second theoretical values is the combination of the measured values input by the measured value input unit 21. It is determined that each value is matched. In this case, the determination unit 26 determines that the wiring connected to the electronic watt-hour meter 2 has the above-mentioned erroneous connection in the wiring connection between the P1 terminal on the one-phase side and the P3 terminal on the three-phase side. Specified.

Table No. EA2 has a table No. Erroneous connection of the voltage circuit wiring specified in E1 and table No. It is specified that there is an erroneous connection that is a combination of the erroneous connection of the current circuit wiring specified in A1. That is, the wiring shown by the broken line in the connection diagram and the wiring connection between the output terminal 1u of the VT and the output terminal 1v are switched as shown by the italicized bold type in the connection terminal correspondence table, and the P1 terminal is the output terminal of the VT. Where it should be connected to 1u, it is erroneously connected to the output terminal 1v, and the P2 terminal is erroneously connected to the output terminals 1u, 3u and G where it should be connected to the output terminals 1v, 3u and G of the VT. Furthermore, the wiring connection between the 1S terminal and the 1L terminal is exchanged, and the 1S terminal should be connected to the CT output terminal 1K, but is incorrectly connected to the output terminals 1L and G, and the 1L terminal is connected to the CT output terminals 1L and G. Where it should be done, it is erroneously connected to the output terminal 1K.

Table No. The measurement results lined up in EA2 are measured by the measured value inputting means 21 when the VT output terminal 1u and the output terminal 1v and the 1S terminal and the 1L terminal are incorrectly connected. It is the value input from the total 2. Of these values, the measured value of the voltage phase difference θp1-p3 of the R load and the measured value of the voltage phase difference θp1-p3 of the C load, which are indicated by bold italic letters in the figure, are the table creating means 24. Out of the range of ±10% of each value corresponding to each measured value among the respective values of the combination of the second theoretical values (not shown) defined for the connection state having the above-mentioned incorrect connection in the table created by It is in. The respective values of the second measured values other than these input by the measured value input means 21 are within ±10% of the respective values corresponding to the respective measured values among the respective values of the combination of the second theoretical values (not shown). It fits inside.

Therefore, only the measured value of the voltage phase difference θp1-p3 of the R load among the second measured value input from the electronic watt-hour meter 2 by the measured value inputting means 21 by the comparison result of the comparing means 25, or C Only the measured value of the voltage phase difference θp1-p3 of the load is ± of each value corresponding to the measured value in the combination of the second theoretical values (not shown) defined in the table for the connection state with the above-mentioned incorrect connection. When it is out of the range of 10%, the determination unit 26 determines that the combination of the second theoretical values has each value that matches the combination of the measurement values input by the measurement value input unit 21. In this case, the discriminating means 26 determines the connection state of the wiring connected to the electronic watt-hour meter 2 as the wiring connection between the output terminal 1u and the output terminal 1v of the VT and the wiring connection between the 1S terminal and the 1L terminal. A connection state having the above-mentioned incorrect connection is specified.

Table No. EA3 has a table No. Erroneous connection of the voltage circuit wiring specified in E1 and table No. It is specified that there is an erroneous connection that is a combination of the erroneous connection of the current circuit wiring specified in A2. That is, the wiring shown by the broken line in the connection diagram and the wiring connection between the output terminal 1u of the VT and the output terminal 1v are switched as shown by the italicized bold type in the connection terminal correspondence table, and the P1 terminal is the output terminal of the VT. Where it should be connected to 1u, it is erroneously connected to the output terminal 1v, and the P2 terminal is erroneously connected to the output terminals 1u, 3u and G where it should be connected to the output terminals 1v, 3u and G of the VT. Further, the wiring connection between the 3S terminal and the 3L terminal is exchanged, and the 3S terminal should be connected to the output terminal 3K of the CT, but is erroneously connected to the output terminals 3L and G, and the 3L terminal is connected to the output terminals 3L and G of the CT. Where it should be done, it is erroneously connected to the output terminal 3K.

Table No. The measurement results lined up in EA3 are measured by the measured value input means 21 when the wiring connection between the output terminal 1u and the output terminal 1v of the VT and the wiring connection between the 3S terminal and the 3L terminal are incorrect. It is the value input from the total 2. Of these values, the 1-side active power W1, 1-side reactive power var1, 3-side active power W3, 3-side reactive power var3, and voltage phase difference θp1-p3 of the R load, which are indicated by bold italics in the figure, are shown. And all the measured values of the C-load 1-side active power W1, 1-side reactive power var1, 3-side active power W3, 3-side reactive power var3, and voltage phase difference θp1-p3, ±10 of each value corresponding to each measured value among the respective values of the combination of the second theoretical values (not shown) defined for the connection state having the above-mentioned incorrect connection in the table created by the table creating means 24. It is outside the range of %.

Therefore, among the comparison results of the comparison means 25 and the second measurement values input from the electronic watt-hour meter 2 by the measurement value input means 21, all measurement values of R load or all measurement values of C load. Is out of the range of ±10% of each value corresponding to each measured value in the combination of the second theoretical values (not shown) defined in the table for the connection state having the above-mentioned erroneous connection, the determination means 26 determines that the combination of the second theoretical values has each value matching the combination of the measurement values input by the measurement value input means 21. In this case, the determination means 26 determines the connection state of the wiring connected to the electronic watt-hour meter 2 as the wiring connection between the output terminal 1u and the output terminal 1v of the VT and the wiring connection between the 3S terminal and the 3L terminal. A connection state having the above-mentioned incorrect connection is specified.

It should be noted that the combination of the respective values of the second measured value input from the electronic watt-hour meter 2 by the measured value input means 21 does not correspond to the erroneous connection state on a one-to-one basis and is the same for the two erroneous connection states. It may be a combination of measurement results. In this case, since the wiring connection state cannot be discriminated, it is necessary to narrow down the investigation to one of the erroneous connection states, measure it again, and confirm it.

According to the computer program for determining the wiring connection state of the electronic watt-hour meter 2 according to the present embodiment, as described above, the load of the load value input by the load value input means 22 is electronic in each connection state of the wiring. Prescribes the relationship between the combination of the theoretical values of the active powers W1 and W3 and the reactive powers var1 and var3 of the simulated load 3 measured when connected to the electric power meter 2 and the connection state of the wiring. The table to be created is created by the table creating means 24. Then, the combination of the measurement values input by the measurement value input means 21 and each combination of the theoretical values defined in the table created by the table creation means 24 are compared by the comparison means 25. From the comparison result of the comparison means 25, the determination means 26 determines a combination of theoretical values having respective values that match the combination of the measured values, and the connection state of the wiring defined in the table for the determined combination of theoretical values. Is specified.

Therefore, by causing the PC 1 to execute a program that causes the PC 1 to function as each unit shown in FIG. 2, it becomes possible to determine the connection state of the wiring connected to the electronic watt-hour meter 2. Therefore, unlike the conventional case, the wiring connected to the electronic watt-hour meter 2 can be easily performed without preparing a special device and without performing a complicated work such as wiring between the devices. It is possible to determine the presence/absence of misconnection.

Further, the measured value input means 21 in the present embodiment uses the electronic watt-hour meter 2 to measure the active powers W1 and W3 and the reactive powers var1 and var3 of the simulated load 3 measured on the one-phase side and the three-phase side of the three-phase power source. In addition to the above values, the value of the voltage phase difference θp1-p3 is also input as the second measurement value. The calculation means 23 uses the load value input means 22 as the theoretical value of the second measured value measured on the first phase side and the third phase side of the three-phase power source when the simulated load 3 is connected to the electronic watt-hour meter 2. The second theoretical value is calculated based on the load value input by. Therefore, according to this embodiment, the types of measured values measured by the electronic watt-hour meter 2 and their theoretical values increase. Therefore, in the table created by the table creating means 24, the combination of theoretical values can be defined for more connection states of the wirings connected to the electronic watt-hour meter 2. Therefore, it is possible to increase the number of wiring connection states that can be identified by the determination unit 26, and it is possible to identify the wiring connection states in more detail.

Further, in the present embodiment, the PC 1 is specified by the discriminating means 26 and the information input means 27 for inputting the instrument information of the electronic watt-hour meter 2 and the setting information set in the electronic watt-hour meter 2. It also functions as the data output means 28 which outputs the information on the connection state of the wiring as data together with the instrument information and the setting information input by the information input means 27. Therefore, when the electronic watt hour meter 2 is installed, as in the present embodiment, the load is connected to the electronic watt hour meter 2 as the simulated load 3 and the measured value of the simulated load 3 input by the measured value input means 21. By comparing each combination of the theoretical values defined in the table with each combination of the theoretical values, the electronic state together with the connection state of the wiring connected to the electronic watt-hour meter 2 is connected before the actual load is connected to the electronic watt-hour meter 2. The meter information and setting information of the electric watt hour meter 2 can be obtained as data. Therefore, before the actual load is connected to the electronic watt-hour meter 2, it is possible to accurately grasp the installation state of the electronic watt-hour meter 2 and to check the installation state of the electronic watt-hour meter 2 with the inspection report. As a result, it becomes possible to objectively and accurately transmit to a third party. Further, even after the electronic watt-hour meter 2 is installed, similarly, the load connection state of the electronic watt-hour meter 2 can be accurately grasped, and the load connection state can be objectively confirmed to a third party. Can be transmitted to.

In the above embodiment, the case where the wiring connection state determination computer program is applied to the three-phase three-wire electronic watt-hour meter 2 has been described, but the same applies to the three-phase four-wire electronic watt-hour meter. The same operation and effect can be obtained. Further, it can be similarly applied to a single-phase three-wire type or a single-phase two-wire type electronic watt hour meter. In this case, the measured value input from the electronic watt-hour meter 2 is the voltage phase difference θp1-p3 input as the second measured value in the three-phase three-wire type or three-phase four-wire type electronic watt hour meter. There is no. Further, since the number of phases is also one, the active power value and reactive power value input from the electronic watt hour meter are reduced from two phases in the second measurement value to one phase. Therefore, the measured values handled by the measured value input unit 21, the arithmetic unit 23, the comparison unit 25, and the like are only the measured values of the active power value and the reactive power value for one phase, and the 1-side active power W1 in the above-described embodiment, Compared with the second measured values of the 1-side reactive power var1, the 3-side active power W3, the 3-side reactive power var3, and the voltage phase difference θp1-p3, the values become smaller. Therefore, the number of measurement result combinations that can correspond to each wiring connection state of the electronic watt-hour meter is small, and it is difficult to identify the wiring connection state in detail. It can be easily determined as in the embodiment.

1... Personal computer (PC)
2... Electronic watt-hour meter 2a... Display part 2b... Terminal part 3... Simulated load 4... Sensor 5... Cable 11... ROM
12... RAM
13... CPU

Claims (3)

Computer,
Measurement value input means for inputting the active power value and reactive power value of the load measured by the electronic watt-hour meter as measurement values, load value input means for inputting the load value of the load, and the load is electronic power In the electronic watt-hour meter, a calculation unit that calculates the theoretical value of the measured value measured by the electronic watt-hour meter when connected to the meter based on the load value input by the load-value input unit. A table defining the relationship between the combination of the theoretical values calculated by the calculation means when the load is connected to the electronic watt-hour meter in each connection state of the wiring to be connected and each connection state of the wiring. Table creating means for creating, and a comparing means for comparing the combination of the measured values input by the measured value inputting means with each of the combinations of the theoretical values defined in the table created by the table creating means, As a discriminating unit that discriminates a combination of the theoretical values having respective values suitable for the combination of the measured values from the comparison result of the comparing unit and identifies the connection state of the wiring according to the discriminated combination of the theoretical values. A program to make it work. The measured value input means inputs, as a second measured value, an active power value and a reactive power value of the load and a voltage phase difference between the plurality of phases, which are measured for a plurality of phases of a three-phase power source by an electronic power meter.
When the load is connected to an electronic watt-hour meter, the calculation means uses the load value input means to calculate a theoretical value of the second measured value measured by the electronic watt-hour meter for a plurality of phases of a three-phase power source. Calculate as the second theoretical value based on the input load value,
The table creating means includes a combination of the second theoretical value calculated by the calculating means when the load is connected to the electronic watt-hour meter in each connection state of the wiring and each connection state of the wiring. Create a table that defines the relationship,
The comparison means compares the combination of the second measurement values input by the measurement value input means with each combination of the second theoretical values defined in the table created by the table creation means,
The discriminating means discriminates a combination of the second theoretical values having respective values corresponding to the combination of the second measured values from the comparison result of the comparing means, and the discriminative combination of the second theoretical values is stored in the table. The program according to claim 1, characterized in that the connection state of the wiring defined in paragraph 1 is specified. Computer,
Information input means for inputting meter information of the electronic watt-hour meter and setting information set in the electronic watt-hour meter, and information on the connection state of the wiring specified by the discrimination means are input by the information input means. The program according to claim 1 or 2, which is caused to function as data output means for outputting as data together with the instrument information and the setting information.

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