Phase-sequence indicator uses few passive components

In a three-phase ac system, a power source with three wires delivers ac potentials of equal frequency and amplitudes with respect to a zeropotential wire, each shifted in phase by 120° from one wire to the next. Two possibilities exist for establishing a phase sequence. In the first, voltage on the second wire shifts by 120° relative to the first, and, in the second, a -120° shift occurs with respect to the first wire. Phase order determines the direction of rotation of three-phase ac motors and affects other equipment that requires the correct phase sequence: a positive 120° shift. You can use a few low-cost passive components to build a phase sequence indicator.

Figure 1 shows a conceptual circuit that can detect both phase sequences. For certain component values, the following conditions apply: The voltages across R₁ and C₂ are equal—that is, their magnitudes and phases are the same-only when V_S2 occurs exactly 120° ahead of V_S1, which indicates the correct phase sequence. In this case, the voltage between points A and B is zero. Conversely, the voltages across C₂ and R3 are equal only when V_S2 is ahead of VS3 by 120°, which corresponds to a reversed sequence.



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Referring to the phasor diagram in Figure 2, when the voltages across R₁ and C₂ are equal, V_C1=-V_R2, V_C1+V_R1=V_S1, and VC₂+V_R2=V_S2. The following equations satisfy these conditions: |V_R1| = |V_C2| =(1/2)| V_S2|=(1/2) |V_S1|, and |V_C1| = |V_R2| =cos(30°) |V_S1| =cos(30°)|V_S2|. You calculate the component values by solving the following equations: |XC1| = tan(60°)
R₁= 3
R₁ and R₂=tan (60°)
|X_C2|, where XC=–j[1/(2p
f
C)], and f represents the frequency of the V_S voltages.



Also, to ensure detection of a reversed phase sequence, C₁=C₃, and R₁=R3; that is, the components in the third branch are identical to those in the first branch. The phase-sequence-detection circuit in Figure 3 eliminates the requirement for an accessible ground wire by adding resistors R₄ and R₅ that connect in parallel with the first and third branches. Eliminating the ground-wire requirement also dictates a ratio between |XC1+R₁| and |X_C2+R₂|. For no current to flow to ground from Node G, the sum of currents in the branches must equal zero, and, if you disconnect Node G from ground, its potential with respect to ground is also zero.

As long as the proportions of X_C1 to R₁, X_C2 to R₂, and X_C3 to R3 remain as noted, the balance of voltage drops remains across R₁, C₂, and R3. Multiplying the impedance of any branch by a constant influences only the magnitude of the currents through the respective branch. The current through any branch presents the same phase angle as the voltage across a resistor in the branch. The phasor diagram in Figure 4 shows the currents in Figure 3. From this diagram, if |I₂|=tan(60°)
|I₃|, then I₁+I₂=–2
I₃. Thus, I₃ has half the magnitude of and an exactly opposite direction from (I₁+I₂).





A vector diagram of the currents shows that adding two currents, each with magnitudes equal to I₃ and the same phases as V_S1 and V_S3, produces a summed current with the same magnitude and phase as I₃; therefore, the total current at Node G is zero:

I₁+I₂+I₃+I₁'+I₃'=I₁+I₂+2
I 3=0. To make the sum of the currents equal zero, R₄=R₅=|R₁+XC1| = |R₁–j[1/ (2p
f
C₁)]|. The two LEDs in Figure 3 indicate correct or reversed-phase sequence. When LED₂ lights and LED₁ remains dark, the voltage between nodes A and B is 0V, which corresponds to a correct phase sequence. A reversed-phase sequence lights LED₁ while LED₂ remains dark. The diodes connected in parallel with the LEDs protect against exceeding the LEDs’ reverse-breakdown voltages, and resistors R₆ and R₇ limit forward currents through the LEDs. For greater sensitivity, you can replace the LEDs with highinput- impedance ac-detector circuits.

The circuit’s final version includes indicators that show whether all three phases carry voltage. In the circuit in Figure 3, a phase that carries 0V lights both LEDs. Depending on your application, you can connect voltage-detection circuits comprising LEDs and protection diodes in series with currentlimiting resistors between V_S1, V_S2, and V_S3 and Node G. You can also use low-wattage neon lamps with appropriate series-current-limiting resistors.

When selecting components, ensure that their values conform to the following proportions. For an arbitrarily chosen value for C₁, R1=R₂=R3=1/(2p
f
C₁
tan(60°)), C₁=C₃, C₂=3C1, and R₄=R₅=2
R₁. When you select a value for C₁, the currents through the detection circuitry should be significantly lower than the currents through the branches, which excludes arbitrarily low values for C₁.

When selecting components, ensure that their values conform to the following proportions. For an arbitrarily chosen value for C₁, R₁=R₂=R3=1/(2p
f
C₁
tan(60°)), C₁=C₃, C₂=3C1, and R₄=R₅=2
R₁. When you select a value for C₁, the currents through the detection circuitry should be significantly lower than the currents through the branches, which excludes arbitrarily low values for C₁.