380 V, 50 Hz, 2p = 6, star connected induction motor impedance in ohms per phase values: R1 = 0.3, X1 = j0.45, R2 = 0.15, X2 = j0.45, Xm = j15 Its total mechanical losses are 500W. Core losses are negligible. For a rotor slip of 0.01 at rated voltage, calculate the following: 1-rotor speed 2-Input active power 3-Stator copper losses
380 V, 50 Hz, 2p = 6, star connected induction motor impedance in ohms per phase values: R1 = 0.3, X1 = j0.45, R2 = 0.15, X2 = j0.45, Xm = j15 Its total mechanical losses are 500W. Core losses are negligible. For a rotor slip of 0.01 at rated voltage, calculate the following: 1-rotor speed 2-Input active power 3-Stator copper losses
380 V, 50 Hz, 2p = 6, star connected induction motor impedance in ohms per phase values: R1 = 0.3, X1 = j0.45, R2 = 0.15, X2 = j0.45, Xm = j15 Its total mechanical losses are 500W. Core losses are negligible. For a rotor slip of 0.01 at rated voltage, calculate the following: 1-rotor speed 2-Input active power 3-Stator copper losses
380 V, 50 Hz, 2p = 6, star connected induction motor impedance in ohms per phase values: R1 = 0.3, X1 = j0.45, R2 = 0.15, X2 = j0.45, Xm = j15 Its total mechanical losses are 500W. Core losses are negligible. For a rotor slip of 0.01 at rated voltage, calculate the following: 1-rotor speed 2-Input active power 3-Stator copper losses 4-air gap power 5-Transferred power and Output power 6-shaft moment 7-efficiency
Branch of science that deals with the stationary and moving bodies under the influence of forces.
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