KR100495408B1 - A method to find the proper wiring of phase currents using a phase check algorithm and electrical measuring equipment using the method - Google Patents

Abstract

The present invention relates to an electrical measurement device for measuring voltage, current, power, energy, frequency, power factor, and the like, and more particularly, an phase check algorithm for determining the polarity and type of phase current from the phase difference between each phase voltage or line voltage and phase current. It relates to an electric measurement device using.

Electrical measuring device according to the present invention for achieving the above object, the first step of measuring the voltage, current connected to each phase; Applying a formula of various methods (① effective power, ② cos (θ), sin (θ), ③ zero-crossing, ④ other arbitrary methods) for calculating the phase angle θ from the measured voltage and current Step 2; Calculating a phase angle θ from the equation; A fourth step of determining the polarity and type of the phase current from a predetermined phase current determination vector region in which each phase current is located when any one of each phase voltage and the line load measured in the step 1 is a reference vector; And a fifth step of displaying the polarity and type of each phase current determined as described above.

Description

A method to find the proper wiring of phase currents using a phase check algorithm and electrical measuring equipment using the method}

The present invention relates to an electrical measurement device for measuring voltage, current, power, energy, frequency, power factor, and the like, and more particularly, an phase check algorithm for determining the polarity and type of phase current from the phase difference between each phase voltage or line voltage and phase current. It relates to an electric measurement device using.

When the worker of the electrical installation works to connect the high pressure meter, the connection of the high pressure meter is carried out after confirming whether the phase of three phase three wire or three phase four wire is normal or reversed. In case of normal, the wiring should be done according to the normal. In case of reverse phase, the wiring should be done according to the reverse phase. In this case, it is impossible to connect without the detector. Even if each phase voltage is correctly connected by the detector, the polarity and type of the current Incorrect measurements of phase currents, unconnected, natural and artificial phases of the phase current that are not connected properly have often prevented the proper measurement from being displayed on the measuring instrument. As a result, frequent field trips and telephone inquiries have caused human, time and economic costs to the instrument manufacturer. As part of an effort to improve the above problems, in the prior art, such as registration number (20-2001-0248186) and application number (20-2001-0006143) three-phase flaw detector, phases are compared by making a phase difference between three phases. Phase to display only normal order {A phase (R) -B phase (S) -C phase (T)} and reverse phase {C phase (T) -B phase (S) -A phase (R)} Although a comparative method is known, the polarity and type of the phase current of each phase are not accurately indicated by this method. Therefore, incorrect and incorrect wiring is caused by misunderstanding the polarity and type of the current, and the effective value of voltage and current irrelevant to the polarity is accurately measured, but the phase power between the voltage and current is measured incorrectly, so the power factor, power, and quantity of power affected by the phase are incorrect. The measurement resulted in the problem that a completely different measurement value was measured other than the value to be measured.

The present invention has been made to solve the above problems, the above-described electrical measuring device is a three-phase three-wire A phase (R), B phase (S), C phase (T) three phase by using the vector diagram of the phase check algorithm Phase currents for each phase voltage (three-phase four-wire) and line voltage (three-phase three-wire) as well as the phase comparison of each of the four-phase A phase (R), B phase (S), C phase (T), and neutral (N) phases The phase angle of each phase voltage (Va (R phase), Vb (S phase), Vc (T phase)) or line voltage (Vab (RS), Vbc (ST)) and phase current A phase current determination method using a phase check algorithm for determining the polarity and type (Ia, Ib, Ic, -Ia, -Ib, -Ic) of the phase current and displaying the display data through any one of the display means of LED, LCD, or monitor; It is to provide an electric measurement device using the same.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the configuration of an electrical measuring device according to the present invention.

The electric measuring device of the present invention is an electric measuring device having a true or ground, and a three-phase three-wire or three-phase four-wire type. (10), various methods (① effective power, ② cos (θ), sin (θ), ③ zero-crossing, ④ other arbitrary methods for calculating the phase angle θ from the voltage current signal generated at the input unit 10) Method), a phase angle calculator 16 that calculates a phase difference between phase voltage and phase current from the calculated value generated by the calculator, and the phase voltage and phase current generated from the phase angle calculator 16. The phase check algorithm determination unit 18 that determines the polarity and type (Ia, Ib, Ic, -Ia, -Ib, -Ic) of the phase current from the phase difference of Or display on either monitor It consists of a display unit 19 which displays through the stage.

FIG. 2 relates to a display unit 19 for displaying the measured values of FIG. 1, and is a device for displaying the polarity and type of phase current for each phase voltage by using an LED or a screen.

When the CHECK (22) mode LED is turned on after pressing the FS (24) function button, the polarity and type of phase current for each phase voltage through the LED display device 20 (Ia, Ib, Ic, -Ia, -Ib) , -Ic) is displayed.

3 is a view illustrating a display unit 19 displaying measured values. The polarity and type of phase current for each phase voltage according to the present invention are expressed by actual LEDs, and each phase (A, B, C, or AB, BC). Ia current 30, Ib current 32, Ic current 34, -Ia current 36, -Ib current 38, and -Ic current 39 which are phase currents of? This makes it possible to determine the correct phase current for each phase.

4 is a step for determining a phase current connected to each phase voltage

Step 40 measures the voltage and current connected to each phase.

The second step 42 applies the formulas of various methods (① reactive power, ② cos (θ), sin (θ), ③zero-crossing, ④ other arbitrary methods) in voltage and current. In addition to the equations described above, any one of equations for obtaining the same result may be selected according to a choice by those skilled in the art.

Step 3 (44) calculates the current vector phase angle (θ) with respect to voltage from the various calculation methods.

Fourth step 46 determines the polarity and type (Ia, Ib, Ic, -Ia, -Ib, -Ic) of the phase current according to the range of the current vector phase angle.

FIG. 5 is a formula for determining the phase difference between the line voltage and the phase voltage of the phase check algorithm calculation unit 14 of FIG. 1 as follows. Since the line voltage Vab terminal 52 flowing in the A phase and the B phase is a voltage flowing in the direct paths of the A phase and the B phase, the equation is expressed as follows when the neutral line of the vector is n.

Vab (52) = Van (54) + Vnb (-Vbn) (56)

As shown in this equation, the vector-phase line voltage Vab terminal 52 is positioned at the center of the -Vbn (-Vb) terminal 56 and Van (Va) 54. Similarly, Vbc is located at the center of -Vc and Vb and Vca is located at the center of -Va and Vc. As a result, the phase voltage of the line voltage is 30 ° compared to the phase voltage.

The following is related to the concept of the phase and the phase of the phase check algorithm for determining the polarity and type of the current for each phase of FIG. 6 to FIG. 15. It is a word that indicates. The power source can be divided into current source and voltage source. Since the voltage source is much easier to implement than the current source and most of the power sources that can be seen around are the voltage source, the voltage and ground are divided into waveforms of current based on voltage. A load that lags current against voltage is called a ground load. The load that leads the current with respect to the voltage is called the true load.

The following shows a balanced state vector diagram of phase voltage, line voltage, and phase current used in determining the polarity and type of the current for each phase of FIG. For example, in Fig. 6, Va (A phase voltage) is used as a reference vector, and vectors of remaining phase voltage, phase current, and line voltage are shown.

The phase difference of the phase current with respect to the phase voltage is called θ and θ is greater than 0 ° and does not exceed θ _th (threshold phase). θ _th 624 is the maximum phase difference of the current with respect to the voltage and can be arbitrarily set by the user. However, when θ _th 624 exceeds 60 °, it overlaps the −Vc region, and thus 0 <= θ _th <60 °.

A vector diagram for each phase check algorithm determination method will be described in detail with reference to FIGS. 6 to 15.

6 is a three-phase four-wire ground (Va) 600 reference vector diagram according to the present invention. In the three-phase four-wire ground connection mode, the A phase current is found based on the A-phase voltage.In the three-phase four-wire ground connection mode, the A-phase voltage (Va) 600 is used as the reference vector, and the forward (+ current) / reverse direction ( It shows the location area of various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector connected to -current). The conditions for determining the connected phase current are as follows. The three-phase power system has three terminals, and when looking at the Va terminal 600 as a reference, there is a phase difference of 120 ° clockwise with the Vb terminal 604 and a phase difference of 240 ° clockwise with the Vc terminal 608. . In the ground mode, since the current is in phase behind the voltage, the Vb terminal 604 is located in a clockwise direction backward 120 ° with respect to the Va terminal 600, and the -Vb terminal 606 is connected to the Va terminal 600. As a reference, it is located in the direction of 300 ° clockwise. Similarly, the Vc terminal 608 is located in a direction that is 240 ° backward in the clockwise direction with respect to the Va terminal 600, and the -Vc terminal 610 is located in a direction that is 60 ° backward in the clockwise direction with respect to the Va terminal 600. Done. If the current in the clockwise direction with respect to the Va terminal 600 falls behind the voltage by a phase of 0 ° to θ _th , it is determined as Ia current 612. Similarly, if the current in the clockwise direction falls behind the voltage by 60 ° to 60 ° + θ _th , it is determined as -Ic current 622. If the current in the clockwise direction lags the voltage by 120 ° to 120 ° + θ _th, the Ib current 616 and in the clockwise direction the current lags the voltage by 180 ° to 180 ° + θ _th . -Ia current 614, when the current in the clockwise direction falls behind the voltage by 240 ° _~ 240 ° + θ _th phase, Ic current 620, in the clockwise direction when the current is 300 ° ~ 300 ° + θ _th phase After that, it is determined as -Ib current 618.

7 is a reference vector diagram of a three phase four wire ground (Vb) 704 in accordance with the present invention. In the three-phase four-wire ground connection mode, the B phase current is found based on the B-phase voltage.In the three-phase four-wire ground connection mode, the B phase voltage (Vb) 704 is used as the reference vector, and the forward (+ current) / reverse direction ( It shows the location area of various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector connected to -current). The conditions for determining the connected phase current are as follows. The three-phase power supply has three terminals, and in the ground mode, the current is in phase behind the voltage, so when the Vb terminal 704 is viewed, there is a phase difference of 120 ° clockwise from the Vc terminal 708, and the Va terminal ( There is a phase difference of 240 ° clockwise from 700). In the ground mode, since the current is behind the voltage, the Vc terminal 708 is located in a clockwise direction 120 ° back from the Vb terminal 704, and the -Vc terminal 710 is referenced to the Vb terminal 704. In the clockwise direction. Similarly, the Va terminal 700 is located in the clockwise direction 240 ° backward with respect to the Vb terminal 704, and the -Va 702 terminal is located in the clockwise direction 60 ° backward with respect to the Vb terminal 704. do. When the current in the clockwise direction with respect to the Vb phase 704 is behind the voltage by a phase of 0 ° to θ _th , it is determined as the Ib current 716. Likewise, if the current in the clockwise direction lags the voltage by 60 ° to 60 ° + θ _th, the -Ia current 714, and in the clockwise direction when the current lags the voltage by 120 ° to 120 ° + θ _th, the Ic current. 720, if the current in the clockwise direction is 180 ° to 180 ° + θ _th behind the voltage, -Ib current 718, and in the clockwise direction, the current is 240 ° to 240 ° + θ _th behind the voltage The ground Ia current 712 is determined as -Ic current 722 when the current in the clockwise direction lags the voltage by 300 ° to 300 ° + θ _th .

8 is a reference vector diagram of a three-phase four-wire ground (Vc) 808 according to the present invention. In the three-phase four-wire ground connection mode, the C-phase current is found based on the C-phase voltage.In the three-phase four-wire ground connection mode, the C-phase voltage (Vc) 808 is the reference vector, and the forward (+ current) / reverse direction ( It shows the location area of various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector connected to -current). The conditions for determining the connected phase current are as follows. The three-phase power system has three terminals, and when viewed based on the Vc terminal 808, there is a phase difference of 120 ° clockwise with Va (800) and a phase difference of 240 ° clockwise with the terminal of Vb 804. . In the ground mode, since the current is in phase behind the voltage, the Va terminal 800 is located in a clockwise direction 120 ° back from the Vc voltage terminal 808, and the -Va terminal 802 is a Vc voltage terminal ( 808, it is located in the direction clockwise 300 ° back. Similarly, the Vb terminal 804 is located in the clockwise direction 240 ° backward with respect to the Vc voltage terminal 808 and the -Vb terminal 806 is rotated in the clockwise direction 60 ° backward with respect to the Vc voltage terminal 808. It is located at. In the ground mode, since the current is behind the voltage, it is determined as the Ic current 820 when the current is in the clockwise direction with respect to the Vc phase 808 by 0 ° to θ _th . Likewise, if the current in the clockwise direction lags the voltage by 60 ° to 60 ° + θ _th, the -Ib current 818, and the clockwise current in the clockwise direction lags the voltage by 120 ° to 120 ° + θ _th , then the Ia current. 812, if the current in the clockwise direction is 180 ° to 180 ° + θ _th behind the voltage, -Ic current 822, and in the clockwise direction, the current is 240 ° to 240 ° + θ _th behind the voltage The ground Ib current 816 is determined as -Ia current 814 if the current in the clockwise direction lags the voltage by 300 degrees to 300 degrees + θ _th .

9 is a three-phase three-wire ground (Vab) 924 reference vector diagram according to the present invention. In the three-phase three-wire ground connection mode, A-phase current is found based on the voltage between the A and B-phase lines.In three-phase three-wire ground connection mode, forward (+ current) using AB line voltage (Vab) 924 as the reference vector. Indicates the position region of the various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vectors connected in the reverse direction (-current). The conditions for determining the connected phase current are as follows. Three-phase power supply has three terminals, and when looking at the voltage terminal of the Vab phase 924, the line voltage Vab 924 has a phase difference of about 900 ° with the phase voltage Va and thus Vab 924. And the phase difference of Va 900 becomes 30 °, and the Va voltage terminal 900 has a phase difference of 120 ° in the clockwise direction with the Vb terminal 904, and a phase difference of 240 ° in the clockwise direction with the Vc terminal 908. have. In the ground mode, since the current is in phase behind the voltage, the -Va terminal 902 is located in a direction that is 210 ° back clockwise with respect to the Vab terminal 924. Similarly, the Vb terminal 904 is located in a clockwise direction 150 ° backward with respect to the Vab terminal 924, and the -Vb terminal 906 is located in a clockwise direction 330 ° backward with respect to the Vab terminal 924. Done. Similarly, the Vc terminal 908 is located in the clockwise direction 270 ° backward with respect to the Vab terminal 924, and the -Vc terminal 910 is located in the clockwise direction 90 ° backward with respect to the Vab terminal 924. do. If the current in the clockwise direction in the Va phase 900 on the line voltage Vab terminal 924 is behind the voltage by a phase of 30 ° to 30 ° + θ _th , it is determined as Ia current 912. Similarly, if the current in the clockwise direction lags the voltage by 90 ° to 90 ° + θ _th , it is determined as -Ic current 922. Ib current 916 when the current lags by 150 ° to 150 ° + θ _{th in} the clockwise direction, and -Ia current (clockwise when the current lags by 210 ° to 210 ° + θ _{th in} the clockwise direction). 914), if the current in the clockwise direction is 270 ° to 270 ° + θ _th behind the voltage, Ic current 920, and in the clockwise direction if the current is 330 ° to 330 ° + θ _th behind the voltage- It is determined as Ib current 918.

10 is a reference vector diagram of a three-phase three-wire ground (Vcb) 1028 according to the present invention. In the three-phase three-wire ground connection mode, C-phase current is found based on the voltage between C and B-phase lines.In three-phase three-wire ground connection mode, CB line voltage (Vcb) 1028 is used as the reference vector. Indicates the position region of the various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vectors connected in the reverse direction (-current). The conditions for determining the connected phase current are as follows. The three-phase power system has three terminals, and the line voltage (Vcb) 1028 has a phase difference of 30 ° from the phase voltage (-Vb) 1006 based on the line voltage between the Vcb phase (1028) and Vcb (1028). ) And -Vb (1006) has a phase difference of 30 ° and the Va voltage terminal 1000 has a phase difference of 120 ° clockwise with Vb terminal 1004 and a 240 ° clockwise with Vc terminal 1008. There is a phase difference. Va (1000) is located in a direction 90 degrees clockwise backward with respect to Vcb (1028) -Va (1002) is located in a direction 270 degrees backward clockwise relative to the Vcb (1028). The Vb terminal 1004 is located 210 ° backward in the clockwise direction based on the Vcb 1028, and the -Vb terminal 1006 is located 30 ° backward in the clockwise direction relative to the Vcb 1028. The Vc terminal 1008 is located 330 ° backward in the clockwise direction with respect to the Vcb 1028, and the -Vc terminal 1010 is located 150 ° backward in the clockwise direction with respect to the Vcb 1028. In the ground mode, since the current is in phase with the voltage, if the current is in the clockwise direction in the -Vb phase 1006 based on Vcb (1028) by 30 ° to 30 ° + θ _th, the -Ib current (1018) is used. Is determined. Similarly, when the current in the clockwise direction lags the voltage by 90 ° to 90 ° + θ _th , it is determined as Ia current 1012. If the current in the clockwise direction lags the voltage by 150 ° to 150 ° + θ _th , -Ic current 1022, and in the clockwise direction when the current lags the voltage by 210 ° to 210 ° + θ _th, the Ib current ( 1016), when the current in the clockwise direction lags the voltage by 270 ° to 270 ° + θ _th , and then -Ia current 1014, in the clockwise direction when the current lags the voltage by 330 ° to 330 ° + θ _th phases. It is determined as Ic current 1020.

11 is a vector diagram of a three-phase four-wire true phase (Va) 1100 according to the present invention. In the three-phase four-wire advanced connection mode, find the A phase current based on the A phase.In the three-phase four-wire advanced connection mode, use the A-phase voltage (Va) (1100) as the reference vector and forward (+ current) / reverse direction (- The position region of the various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector connected to the current) is shown. The conditions for determining the connected phase current are as follows. The three-phase power supply method has three terminals, and when the Va voltage terminal 1100 is viewed, there is a phase difference of 240 ° in the counterclockwise direction with the Vb terminal 1104, and 120 ° in the counterclockwise direction with the Vc terminal 1108. There is a phase difference. In the advanced mode, since the current is in phase with the voltage, the Vb terminal 1104 is positioned in the direction of 240 ° in the counterclockwise direction with respect to the Va terminal 1100, and the -Vb terminal 1106 is located in the Va terminal 1100. It is located counterclockwise 60 ° forward. Similarly, the Vc terminal 1108 is positioned 120 ° in the counterclockwise direction relative to the Va terminal 1100, and the -Vc terminal 1110 is 300 ° in the counterclockwise direction relative to the Va terminal 1100. Direction. When the current advances counterclockwise with respect to the Va phase 1100 by 0 ° to θ _th phase, it is determined as Ia current 1112. Similarly, if the current advances in the counterclockwise direction by 60 ° to 60 ° + θ _th phase, it is determined as -Ib current 1118. Ic current (1120) if the current is ahead of the voltage by 120 ° to 120 ° + θ _th phase in the counterclockwise direction, -Ia current (1114) if the current is ahead of the voltage 180 ° to 180 ° + θ _th phase in the counterclockwise direction Ib current 1116 if the current is ahead of the voltage by 240 ° to 240 ° + θ _th phase in the counterclockwise direction, and -Ic current 1122 if the current is ahead of the voltage 300 ° to 300 ° + θ _th phase in the counterclockwise direction Is determined.

Figure 12 is a three-phase four-wire true phase (Vb) 1204 reference vector diagram. This is a method of finding the current of phase B based on phase B in the three-phase four-wire phase connection mode.Various phase currents connected in the forward (+ current) and reverse (-current) with B phase voltage (Vb) 1204 as a reference vector (Ia, Ib, Ic, -Ia, -Ib, -Ic) indicates the location area of the vector. The conditions for determining the connected phase current are as follows. The three-phase power system has three terminals. The Vb terminal 1204 has a phase difference of 240 ° counterclockwise with the Vc terminal 1208 and a 120 degree counterclockwise with the Va terminal 1200. There is. In the phase advance mode, since the current is in phase with the voltage, the Vc terminal 1208 is positioned in the direction of 240 ° in the counterclockwise direction with respect to the Vb terminal 1204, and the -Vc terminal 1210 is connected to the Vb terminal 1204. It is located counterclockwise 60 ° forward. Similarly, the Va terminal 1200 is positioned 120 ° in the counterclockwise direction with respect to the Vb terminal 1204 and the -Va terminal 1202 is 300 ° in the counterclockwise direction with respect to the Vb terminal 1204. It is located at. If the current advances counterclockwise with respect to the Vb phase 1204 by 0 ° to θ _th phase, it is determined as Ib current 1216. Similarly, when the current advances in the counterclockwise direction by 60 ° to 60 ° + θ _th phase, it is determined as -Ic current 1222. Ia current 1212 if the current is ahead of the voltage by 120 ° to 120 ° + θ _th phase in the counterclockwise direction, -Ib current 1218 if the current is ahead of the voltage 180 ° to 180 ° + θ _th phase in the counterclockwise direction Ic current 1220 when current in the counterclockwise direction precedes the voltage by 240 ° to 240 ° + θ _th phase, and -Ia current 1214 when the current in the counterclockwise direction precedes the voltage by 300 ° to 300 ° + θ _th phases. Is determined.

13 is a vector diagram of a three-phase four-wire true phase (Vc) 1308 reference according to the present invention. As a method of finding the current of the C phase based on the C phase in the three-phase four-wire advanced connection mode, various phase currents connected in the forward (+ current) / reverse (-current) mode with the C phase voltage (Vc) 1308 as the reference vector. (Ia, Ib, Ic, -Ia, -Ib, -Ic) indicates the location area of the vector. The conditions for determining the connected phase current are as follows. Three-phase power supply has three terminals, and when the Vc voltage terminal 1308 is looked at, the phase difference of 240 ° counterclockwise with the Va terminal 1300 is generated, and the counterclockwise with Vb terminal 1304 is 120 °. Phase difference of. In the phase advance mode, since the current is in phase with the voltage, the Va terminal 1300 is positioned in the direction of 240 ° in the counterclockwise direction with respect to the Vc voltage terminal 1308, and the -Va terminal 1302 is the Vc voltage terminal ( 1308, it is located in a direction 60 degrees counterclockwise. Similarly, the Vb terminal 1304 is positioned 120 ° in the counterclockwise direction with respect to the Vc terminal 1308, and the -Vb terminal 1306 is 300 ° in the counterclockwise direction with respect to the Vc terminal 1308. Direction. If the current advances counterclockwise by the voltage by 0 ° to θ _th phase on the Vc 1308 phase, it is determined as the Ic current 1320. Similarly, when the current advances in the counterclockwise direction by 60 ° to 60 ° + θ _th phase, it is determined as -Ia current 1314. Ib current 1316 if the current is ahead of the voltage by 120 ° to 120 ° + θ _th phase in the counterclockwise direction, -Ic current 1322 if the current is ahead of the voltage 180 ° to 180 ° + θ _th phase in the counterclockwise direction Ia current 1312 if the current is ahead of the voltage by 240 ° to 240 ° + θ _th phase in the counterclockwise direction, -Ib current (1318) if the current is ahead of the voltage 300 ° to 300 ° + θ _th phase in the counterclockwise direction Is determined.

14 is a three-phase, three-wire Vab 1424 reference vector. In the three-phase three-wire advanced connection mode, the A-phase current is found based on the voltage between the A and B-phase lines.The voltage between the AB lines (Vab) 1424 is used as the reference vector for forward (+ current) and reverse (-current). It shows the location area of the connected various phase current (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector. The conditions for determining the connected phase current are as follows. The three-phase power supply method has three terminals, and when the Vab phase 1424 is based on the line voltage, the line voltage (Vab) 1424 has a phase difference of 30 ° from the phase voltage (Va) 1400, and thus Vab (1424). Phase difference between Va and 1400 is 30 ° and Va terminal 1400 has a phase difference of 240 ° counterclockwise with Vb 1404 and a phase difference of 120 ° counterclockwise with Vc terminal 1408. There is. In the advanced mode, since the current is in phase with the voltage, the Va terminal 1400 is positioned 330 ° in the counterclockwise direction with respect to the Vab terminal 1424, and the -Va terminal 1402 is the Vab terminal 1424. It is located 150 ° in the counterclockwise direction. Similarly, the Vb terminal 1404 is located in the counterclockwise direction 210 ° forward with respect to the Vab terminal 1424, and the -Vb terminal 1406 is 30 ° in the counterclockwise direction relative to the Vab terminal 1424. The Vc terminal 1408 is positioned 90 ° in the counterclockwise direction relative to the Vab terminal 1424, and the -Vc terminal 1410 is 270 ° counterclockwise relative to the Vab terminal 1424. It is located in the forward direction. If the current advances counterclockwise in the -Vb phase 1406 on the basis of the Vab terminal 1424, it is determined as -Ib current 1418 when the current is advanced by 30 ° to 30 ° + θ _th phase. Similarly, if the current advances 90 ° to 90 ° + θ _th phase in the counterclockwise direction, it is determined as Ic current 1420. -Ia current 1414 when current in the counterclockwise direction precedes the voltage by 150 ° to 150 ° + θ _th phase, and Ib current 1416 when the current in the counterclockwise direction precedes the voltage by 210 ° to 210 ° + θ _th phases -Ic current 1422 if the current is 270 ° to 270 ° + θ _th phase in the counterclockwise direction, and Ia current 1412 if the current is 330 ° to 330 ° + θ _th phase in the counterclockwise direction. Is determined.

15 is a vector diagram of a three-phase three-wire true phase (Vcb) 1528 reference according to the present invention. In the three-phase three-wire advanced connection mode, the C-phase current is searched based on the voltage between C and B-phase lines.The CB line voltage (Vcb = -Vbc) (1528) is used as the reference vector. The position region of the various phase currents (Ia, Ib, Ic, -Ia, -Ib, -Ic) vector connected to the current) is shown. The conditions for determining the connected phase current are as follows. Three-phase power system has three terminals, and when looking at the line voltage between the Vcb phase (1528), the line voltage (Vcb) 1528 has a sanitary difference of 30 ° with the phase voltage (-Vb) (1506). The phase difference between 1528 and -Vb 1506 becomes 30 °, and the Va terminal 1500 has a phase difference of 240 ° counterclockwise with the Vb terminal 1504 and 120 counterclockwise with the Vc terminal 1508. There is a phase difference of °. In the forward mode, since the current is in phase with the voltage, the Va terminal 1500 is located 270 ° in the counterclockwise direction with respect to the Vcb terminal 1528, and the -Va 1502 is counterclockwise with respect to the Vcb terminal 1528. Direction 90 ° forward. The Vb terminal 1504 is located in the counterclockwise direction 150 ° in the forward direction based on the Vcb terminal 1528, and the -Vb terminal 1506 is located in the counterclockwise direction 330 ° in the forward direction relative to the Vcb terminal 1528. Done. The Vc terminal 1508 is positioned in the counterclockwise direction 30 ° in the forward direction based on the Vcb terminal 1528, and the -Vc terminal 1510 is located in the counterclockwise direction 210 ° in the forward direction toward the Vcb terminal 1528. Done. If the current advances counterclockwise in the Vc phase 1508 on the basis of the Vcb terminal 1528 by 30 ° to 30 ° + θ _th phase, it is determined as the Ic current 1520. Similarly, if the current advances 90 ° to 90 ° + θ _th phase in the counterclockwise direction, it is determined as -Ia current 1514. Ib current 1516 if the current is ahead of the voltage by 150 ° to 150 ° + θ _th phase in the counterclockwise direction, -Ic current 1522 if the current is ahead of the voltage 210 ° to 210 ° + θ _th phase in the counterclockwise direction Ia current 1512 if current in the counterclockwise direction is 270 ° to 270 ° + θ _th phase, and Ib current (1518) if current in the counterclockwise direction is 330 ° to 330 ° + θ _th phase. Is determined.

The present invention is not limited to the above embodiments, and various changes can be made by any person having ordinary knowledge in the field of the present invention without departing from the gist of the present invention as claimed in the following claims. It will be said that there is a technical spirit of the present invention to the extent.

Conventional technologies such as three-phase flaw detectors compare phases by making phase difference between three phases and display only normal order (RST) and reverse order (TSR) by LED. Polarity and type could not be determined and provided correctly.

However, according to the configuration of the present invention, each phase voltage (Va (R phase), Vb (S phase), Vc (T phase)) or line voltage (Vab ), Vbc (ST)) and the polarity and type (Ia, Ib, Ic, -Ia, -Ib, -Ic) of the current with respect to the phase angle of the phase current with respect to the phase angle of the phase current are determined by the phase check algorithm. By knowing the polarity and type of the current, it is possible to prevent wrong and unconnected sources at the source, thereby preventing the incorrect measurement of power and amount of electricity.

In addition, in the case of incorrect wiring of the electric equipment worker, the manufacturer of the electric measuring device can check and correct the wrong wiring by telephone inquiries without having to go on-site, thereby reducing the human, time and economic cost of the electric measuring device manufacturer.

1 is a block diagram showing the configuration of an electrical measuring device according to the present invention

Figure 2 is a device for displaying the polarity and type of the phase current for each phase voltage, line voltage according to the present invention with LED

3 is a device expressing the polarity and type of the phase current for each phase voltage, line voltage according to the present invention in LED

Figure 4 is a flow chart showing the steps for determining the phase current connected to each phase voltage, line voltage in accordance with the present invention as a whole

5 is a condition for determining the phase difference between the line voltage and the phase voltage.

Figure 6 is a three-phase four-wire ground (Va) reference vector diagram according to the present invention

Figure 7 is a three-phase four-wire ground (Vb) reference vector diagram according to the present invention

8 is a three-phase four-wire ground (Vc) reference vector diagram according to the present invention

9 is a three-phase three-wire ground (Vab) reference vector diagram according to the present invention

10 is a three-phase three-wire ground (Vcb) reference vector diagram according to the present invention

11 is a three-phase four-wire true phase (Va) reference vector diagram according to the present invention

12 is a three-phase four-wire true phase (Vb) reference vector diagram according to the present invention

Figure 13 is a three-phase four-wire true phase (Vc) reference vector diagram according to the present invention

14 is a three-phase three-wire Vab reference vector diagram according to the present invention

15 is a three-phase three-wire true phase (Vcb) reference vector diagram according to the present invention

Claims (3)

In the phase current determination method using the phase difference between each phase voltage and line voltage and phase current in ground mode, phase advance mode, three-phase four-wire or three-phase three-wire connection mode used in electrical equipment construction, A first step of measuring a voltage and a current connected to each phase; A second step of calculating a phase angle from the measured voltage and current by applying any one of equations for calculating effective reactive power and zero crossing; A third step of determining the polarity and type of the phase current from the predetermined phase current determination vector region by using the calculated phase voltage and phase angle of the phase current when any one of the phase voltages measured in step 1 is a reference vector; And And a fourth step of displaying the polarity and type of each phase current determined as described above. The method of claim 1, The fourth step is a polarity and type determination method of the phase current using the phase check algorithm, characterized in that the display by any one of the display means of the LED, LCD or monitor. In the electrical measuring equipment for measuring voltage, current, power, energy, frequency, power factor, etc., An electric measuring device power supply unit for supplying internal power; An input unit receiving a voltage signal and a current signal; A phase angle calculator configured to calculate phase angles of phase voltage and phase current by applying any one of a formula for calculating reactive power or zero crossing from the voltage and current signals generated by the input unit;  A phase determination unit for determining the polarity and type of the phase current from a predetermined phase current determination vector region using the phase angles of the phase voltage and the phase current generated from the phase angle calculator; And  And a display unit for displaying the determination value generated from the phase determination unit through any one of the display means of the LED, the LCD, or the monitor.