A 480-V, 60-Hz, four-pole Y-connected induction motor runs at 1735 rpm when operating at full load. Assume the friction and windage losses are 1.6 kW and core losses are 1.3 kW. The motor parameters are: R₁ = 0.05 ohm, R2 = 0.04 Ohm, X₁ = 0.18 Ohm, X2 = 0.16 Ohm, X = 0.16 Ohm. a) Find the slip of the motor in both rpm and rad/sec. b) Find the input power of the motor. c) Find the stator losses. d) Find the air-gap power. e) Find the power converted to mechanical power. f) Find the load torque. g) Find the motor efficiency. For the motor of Problem 1, find the followings: a) Find the maximum torque and the slip in which it happens. b) Find the start-up torque. c) Repeat Part (a) and Part (b) assuming R2 is adjusted to 0.08 Ohm. Also, find the torque at 1735 rpm (full-load of Problem 1) using the approximate torque-slip equation. d) Compare the results of Part (c) with what you found for original value of R2. What can be concluded from these numbers? e) Find the rotor resistance which would result in maximum torque occurring at the start-up. The motor of Problem 1 (with R2 = 0.04 Ohm) is delivering 250 hp at the slip of 4%. a) Find the air-gap power of the motor. b) Find the rotor copper losses. c) Find the magnitude of the current of the rotor referred to the stator side (|12|).
A 480-V, 60-Hz, four-pole Y-connected induction motor runs at 1735 rpm when operating at full load. Assume the friction and windage losses are 1.6 kW and core losses are 1.3 kW. The motor parameters are: R₁ = 0.05 ohm, R2 = 0.04 Ohm, X₁ = 0.18 Ohm, X2 = 0.16 Ohm, X = 0.16 Ohm. a) Find the slip of the motor in both rpm and rad/sec. b) Find the input power of the motor. c) Find the stator losses. d) Find the air-gap power. e) Find the power converted to mechanical power. f) Find the load torque. g) Find the motor efficiency. For the motor of Problem 1, find the followings: a) Find the maximum torque and the slip in which it happens. b) Find the start-up torque. c) Repeat Part (a) and Part (b) assuming R2 is adjusted to 0.08 Ohm. Also, find the torque at 1735 rpm (full-load of Problem 1) using the approximate torque-slip equation. d) Compare the results of Part (c) with what you found for original value of R2. What can be concluded from these numbers? e) Find the rotor resistance which would result in maximum torque occurring at the start-up. The motor of Problem 1 (with R2 = 0.04 Ohm) is delivering 250 hp at the slip of 4%. a) Find the air-gap power of the motor. b) Find the rotor copper losses. c) Find the magnitude of the current of the rotor referred to the stator side (|12|).
Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN:9780133923605
Author:Robert L. Boylestad
Publisher:Robert L. Boylestad
Chapter1: Introduction
Section: Chapter Questions
Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...
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