3 Phase Delta/Wye Calculator

CHOOSE POWER SOURCE

Line Voltage (V_line)

Line Current (I_line)

Power Factor (PF)

—

Phase Voltage (V_ph)

Phase Current (I_ph)

Apparent Power (S)

kVA

Real Power (P)

Reactive Power (Q)

kVAR

V_line = V_ph

I_line = √3 × I_ph

I_ph = I_line / √3

S = 3 × V_ph × I_ph

P = S × PF

PF = P / S

Q = √3 × V_line × I_line × sin φ

Apparent Power S: -- kVA

Real Power P: -- kW

Reactive Power Q: -- kVAR

Power Factor PF: --

Phase Angle φ: -- deg

What is a 3-phase Delta/Wye calculator?

Three-phase power systems can connect loads and sources in two common ways: delta (Δ) and wye (Y or star). The relationship between line and phase voltages, currents and impedances is different in each configuration.

This calculator helps you:

Convert between line and phase voltages and currents
Compare Δ and Y connected loads at the same line voltage
Determine equivalent impedances between delta and wye networks
Size motors, heaters and distribution equipment correctly

Basics of delta and wye connections

In a delta (Δ) connection, the three phase windings or loads form a closed loop. Line conductors connect to each corner of the triangle.

In a wye (Y) connection, one end of each phase is tied to a common neutral point, and the line conductors connect to the remaining ends.

Quantity	Wye (Y) connection	Delta (Δ) connection
Line voltage vs phase voltage	V_L = √3 × V_PH	V_L = V_PH
Line current vs phase current	I_L = I_PH	I_L = √3 × I_PH
Apparent power	S = √3 × V_L × I_L

Voltage and current relationships

Wye (Y) connected loads

Phase voltage: V_PH = V_L / √3
Line current: I_L = I_PH

Delta (Δ) connected loads

Phase voltage: V_PH = V_L
Line current: I_L = √3 × I_PH

The calculator applies these relations automatically to show how a given line voltage and load connection translate into per-phase quantities.

Delta–wye impedance conversion

When converting a three-branch network from wye to delta or vice versa, the branch impedances must be adjusted to preserve the same line-to-line behavior.

From wye to delta

For wye impedances Z_A, Z_B, Z_C, the equivalent delta impedances are:

Z_AB,Δ = (Z_AZ_B + Z_BZ_C + Z_CZ_A) / Z_C
Z_BC,Δ = (Z_AZ_B + Z_BZ_C + Z_CZ_A) / Z_A
Z_CA,Δ = (Z_AZ_B + Z_BZ_C + Z_CZ_A) / Z_B

From delta to wye

For delta impedances Z_AB, Z_BC, Z_CA, the equivalent wye impedances are:

Z_A,Y = (Z_AB × Z_CA) / (Z_AB + Z_BC + Z_CA)
Z_B,Y = (Z_AB × Z_BC) / (Z_AB + Z_BC + Z_CA)
Z_C,Y = (Z_BC × Z_CA) / (Z_AB + Z_BC + Z_CA)

The calculator uses these formulas behind the scenes so you can focus on entering nameplate data and seeing the equivalent values.

Worked examples

Example 1 – 400 V supply, wye-connected load

Line voltage: V_L = 400 V
Connection: wye (Y)

Phase voltage: V_PH = 400 / √3 ≈ 231 V

If each phase draws 10 A, then:

I_L = I_PH = 10 A
S = √3 × 400 × 10 ≈ 6.93 kVA

Example 2 – same load in delta

To draw the same power at 400 V in delta, the per-phase impedance must change. The calculator can show the required phase currents and new per-phase impedance so that S stays approximately equal.

Design tips for 3-phase Delta/Wye systems

Know your line voltage: A “400 V” system usually refers to line-to-line voltage. Phase voltage is lower in wye connections.
Check nameplate connection: Motors and heaters may support Y, Δ or both (e.g. 230/400 V). Connecting incorrectly can over- or under-voltage the windings.
Balance the phases: Uneven loading between phases causes neutral currents, voltage imbalance and overheating.
Consider starting methods: Star–delta motor starters temporarily use Y connection to limit starting current before switching to Δ for full power.

This calculator helps you visualize how three-phase quantities change between delta and wye connections so you can choose the right configuration, verify ratings, and design safer distribution and motor control systems.

FAQ about 3 Phase Delta/Wye Calculator

When should I use a wye connection vs a delta connection?

Wye (Y) is often used when you need a neutral point and lower phase voltage (for example 230/400 V systems feeding both single-phase and three-phase loads).

Delta (Δ) is common for motor windings and balanced three-phase loads without neutral.

The choice depends on required voltage, insulation rating, neutral availability and how the equipment is designed.

What is the difference between line and phase voltage/current?

In three-phase systems:

Line voltage is measured between two line conductors.
Phase voltage is measured across a single winding or phase of the load.
Line current flows in the line conductors; phase current flows in each winding or branch.

The relationship between these quantities depends on whether the load is connected in wye or delta

Can I directly convert a delta-rated motor to wye on the same supply voltage?

Not always. Many motors are marked with dual ratings (for example 230 Δ / 400 Y).

These are designed so that the winding voltage stays within limits in either configuration at the specified supply.

If a motor is only rated for Δ at a certain voltage, using Y on the same line voltage may under-voltage the windings and reduce torque, while using Δ on a voltage intended for Y may over-stress the insulation.

Always follow the motor nameplate and manufacturer guidelines.