A. speed of motor will increase
B. the magnetising current of the rotor will decrease
C. the windage losses will increase
A. external inductance to the rotor
C. external capacitance to the rotor
D. both resistance and inductance to rotor
A. negligible
B. slightly more than full-load torque
C. same as full-load torque
B. the motor will burn
C. the motor will not run
D. the motor will run at reduced speed
A. 4% in the rotor torque
B. 12% in the rotor torque
C. 8% in the rotor torque
B. 1.50%
C. 4%
D. 2%
A. none of the above
B. universal motor
D. D.C. series motor
A. it is run on voltage higher than the rated voltage
B. it is run on load
C. it is run in reverse direction
A. None of the above
C. Shaft
D. Bearings
A. square of supply voltage
B. rotor inductive reactance
C. frequency
B. D.C. series motors
C. compound generators
D. three phase transformers
A. all above considerations are involved
B. maintenance cost is to be kept low
C. initial cost is the main consideration
B. embedded temperature method
C. resistance rise method
D. thermometer method
A. it will run in reverse direction
B. starting torque is very high
D. it will pick-up very high speed and may go out of step
A. heavy pull out torque is required
B. load torque is heavy
D. all of the above
B. resistance is inserted in the stator
C. resistance is inserted in the rotor
D. reduced voltage is applied to the stator
A. improper design of machine
B. high loads
D. low voltage supply
A. stall after sometime
B. continue to run at lower speed without damage
D. stall immediately
A. Ns
C. (Ns-l)s
D. s.N,
B. reduce copper losses
C. improve power factor
D. improve efficiency
A. high loads
B. improper design of the machine
C. none of the above
E. low voltage supply
A. supply frequency
B. supply voltage
A. four
B. three
C. two
A. increases the starting torque
B. none of the above
C. increases the load torque
C. delta connected only
D. star connected only
B. to ensure easy fabrication
D. to increase the tensile strength of the rotor bars
A. inversely proportional to slip
C. inversely proportional to (Vslip)
D. directly proportional to (slip)2
A. in parallel with stator
B. in series
D. in series-parallel
B. k2/torque with direct switching
C. K x torque with direct switching
D. k/torque with direct switching
C. stator slots are exact multiple of rotor slots
D. stator slots are equal to rotor slots
A. increases the rotor current
C. rotor current becomes zero
D. decreases the rotor current
B. squirrel cage induction motor only but not with slip ring motor
C. slip ring motor only but not with squirrel cage induction motor
D. none of the above
A. power factor at starting in the same as that while running
B. power factor at starting is high as compared to that while running
A. 0.03
B. 0.02
C. 0.01
A. will stop and carry heavy current causing permanent damage to its winding
C. will continue running without any harm to the winding
D. will continue running burning its two phases
A. low inductance and low resistance
B. low inductance and high resistance
C. high inductance and high resistance
B. power factor on short circuit
C. leakage reactance
D. short-circuit current under rated voltage
A. any of the above
B. above synchronous speed
C. synchronous speed
C. stator resistance test
D. open-circuit test only
A. squirrel-cage induction motors only
C. both A. and (b)
A. sR2 = X2
B. R2 = s2X2
D. sR2X2 = 1
A. will continue running without any harm to the winding
B. will continue running burning its one phase
C. will continue running burning its two phase
A. it will pick up very high speed and may go out of step
D. it will run in reverse direction
B. copper
C. carbon
D. aluminium
B. windage losses will be more
C. copper loss will reduce In an induction motor
D. bearing friction will reduce
B. 960 r.p.m.
C. 1440 r.p.m.
D. 2880 r.p.m.
B. cast iron
C. stainless steel
D. high speed steel
B. inadequate motor wiring
D. poorely regulated power supply
A. variable speed motors
B. high speed motors
C. high horsepower motors
C. any of the above
D. squirrel cage type
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