No Load Test

In this test, the motor is made to run without any load i.e. no load condition. The speed of the motor is very close to the synchronous speed but less than the synchronous speed. The rated voltage is applied to the stator. The input line current and total in put power is measured. The two wattmeter method is used to measure the total input power. The circuit diagram for the test is shown in the Fig. 1.

Fig. 1 No load test

As the motor is on no load, the power factor is very low which is less than 0.5 and one of the two wattmeters reads negative. It is necessary to reverse the current coil or pressure coil connections of such a wattmeter to get the positive reading. This reading must be taken negative for the further calculations.

The total power input W_o is the algebraic sum of the two wattmeter readings. The observation table is,

The calculations are,

W_o = √3V_oI_o cosΦ_o

This is no load power factor.

Thus we are now in a position to obtain magnitude and phase angle of no load current I_o, which is required for the circle diagram.

From the knowledge of I_o and Φ_o, the parameters of the equivalent circuit can be obtained as,

I_c = I_o cosΦ_o = Active component of no load current

I_m = I_o sinΦ_o = Magnetising component of no load current

R_o = V_o (per phase) / I_c (per phase) = No load branch resistance

X_o = V_o (per phase)/ I_m (per phase) = No load branch resistance

The power input W_o consists of following losses,

1. Stator copper loss i.e. 3 I_o² R₁²where I_o is no load per phase current and R₁ is stator resistance per phase.

2. Stator core loss i.e. iron loss.

3. Friction and windage loss.

The no load rotor current is very small and hence rotor copper loss is negligibly small. The rotor frequency is s times supply frequency and on no load it is very small. Rotor iron losses are proportional to this frequency and hence are negligibly small.

Key Point : Under no load condition, I_o is also very small and in many practical cases it is also neglected.

Thus W_o consists of stator iron loss and friction and windage loss which are consists for all load condictions. Hence W_o is said to give fixed losses of the motor.

.^.. W_o = No load power input

1.1 Separation No Load Losses

The no load losses are the constant losses which include core loss and friction and windage loss. The separation between the two can be carried out by the no load test conducted from variable voltage, rated frequency supply.

When the voltage is decreased below the rated value, The core loss reduces as nearly square of voltage. The slip does not increase significantly the friction and windage loss almost remains constant.

The voltage is continuously decreased till the machine slip suddenly begins to increase and the motor tends to stall. At no load, this takes place at a sufficiently reduced voltage. The graph showing no load losses P_N.L. versus as shown in the Fig. is extrapolated to V = 0 which gives friction and windage loss as iron or core loss is zero at zero voltage.