DC motors and Induction motor: What does "no load conditions" mean?

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Discussion Overview

The discussion revolves around the concept of "no load conditions" in DC motors and induction motors, specifically focusing on the implications of no load speed and the conditions under which torque is considered to be zero. Participants explore the definitions and conditions associated with no load scenarios for both types of motors.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants propose that no load condition implies that the output torque (Tout) is zero for both DC and induction motors.
  • Others clarify that for a DC motor, no load speed occurs when back EMF equals the applied voltage, while for an induction motor, it occurs when slip is zero.
  • A participant suggests that there may be multiple conditions for no load, indicating that armature current (Ia) can be non-zero while still having zero output torque due to power losses.
  • Another participant explains that disconnecting the output shaft results in no torque or external mechanical load, and that Ia must supply the torque needed to overcome internal friction and windage losses.
  • Some participants discuss the distinction between ideal motors, where Ia is zero at no load speed, and real motors, where internal losses are present and Ia is not zero.
  • There is mention of confusion regarding textbook definitions of no load speed, particularly in relation to the presence of internal losses and the conditions under which they are considered.

Areas of Agreement / Disagreement

Participants express differing views on the conditions that define no load speed, particularly regarding the role of armature current and internal losses. No consensus is reached on a singular definition of no load conditions for both types of motors.

Contextual Notes

Participants note that the discussion involves nuances related to the definitions of no load conditions, the impact of internal losses, and the behavior of armature current under different scenarios. These aspects remain unresolved and are subject to interpretation based on specific motor characteristics.

Pipsqueakalchemist
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Thread moved from the technical forums to the schoolwork forums
TL;DR Summary: So I'm just confused when the question asks me to solve for the no load speed of DC motors and induction motors. Does no load condition mean that the output torque (Tout) is zero? This is what I was assuming so far for both DC and induction motor. Is no load condition the same for both of these motors? I have the imagine of both motors below

Shunted DC motor
1670015556894.png

Induction motor
1670015626022.png
 
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Pipsqueakalchemist said:
Does no load condition mean that the output torque (Tout) is zero?
Yes.
Consider the RPM of a DC motor, when the back EMF is equal to the applied voltage.
Consider the RPM of an induction motor when the slip is zero.
 
Baluncore said:
Yes.
Consider the RPM of a DC motor, when the back EMF is equal to the applied voltage.
Consider the RPM of an induction motor when the slip is zero
Oh so these are the conditions under no load in DC and induction motor correct?
 
Pipsqueakalchemist said:
Oh so these are the conditions under no load in DC and induction motor correct?
We cannot study for you. When you have examined DC and induction motors sufficiently, you will understand, and will be able to answer to your own question.
 
Baluncore said:
We cannot study for you. When you have examined DC and induction motors sufficiently, you will understand, and will be able to answer to your own question.
Ok after looking over my notes, I believe that there's more than one condition for no load (Tout = 0), one condition is if Emf = Vapplied and hence armature current (Ia) will be zero. But I'm pretty sure that there is a no load condition where Ia isn't zero and there is power delivered to the load, it's just all the power is loss through rotational loss so Tout is still 0. I just want to confirm if my understanding of DC motors are correct
 
Pipsqueakalchemist said:
But I'm pretty sure that there is a no load condition where Ia isn't zero and there is power delivered to the load, it's just all the power is loss through rotational loss so Tout is still 0.
Disconnect the output shaft, so there can be no torque or external mechanical load. The torque then needed to overcome the internal friction and windage losses of the spinning motor must be supplied by Ia. The "no load speed" of a real motor must therefore be slightly less than expected from the equality of back EMF and supply voltage. Ia will not be zero when there is no shaft load on a spinning motor.

If you were to drive the operating motor shaft mechanically, as a generator, then when Ia does become zero, the shaft torque would be providing for the motor internal friction and windage losses. The speed would then be higher than the "no load speed" measured earlier.
 
Baluncore said:
Disconnect the output shaft, so there can be no torque or external mechanical load. The torque then needed to overcome the internal friction and windage losses of the spinning motor must be supplied by Ia. The "no load speed" of a real motor must therefore be slightly less than expected from the equality of back EMF and supply voltage. Ia will not be zero when there is no shaft load on a spinning motor.

If you were to drive the operating motor shaft mechanically, as a generator, then when Ia does become zero, the shaft torque would be providing for the motor internal friction and windage losses. The speed would then be higher than the "no load speed" measured earlier.
Is it correct to say that when EMF = Vsupplied and hence not armature current that this is the max rotor speed, and that when there is no shaft and armature is non zero then this is the no load speed which is slightly less then max moto speed.
 
Pipsqueakalchemist said:
Is it correct to say that when EMF = Vsupplied and hence not armature current that this is the max rotor speed, and that when there is no shaft and armature is non zero then this is the no load speed which is slightly less then max moto speed.
My textbook is very confusing because it refers to the case where EMF = V as no load speed but it also refers to no shaft as no load speed
 
V supply is an EMF. To make it clear, refer to the voltage "generated" internally as "back EMF".

There are no internal friction and windage losses in an ideal motor. In an ideal motor, Ia will be zero when Vsupply = back EMF, at the ideal "no load speed".

The "no load speed" is defined as the speed a real DC motor runs, given a particular supply voltage, and there is no external mechanical load being driven by the shaft. The internal losses are not being ignored. Ia is not zero.

The component of Ia that is needed to overcome the internal friction and windage losses, varies as the square of the RPM.
 
  • #10
Baluncore said:
V supply is an EMF. To make it clear, refer to the voltage "generated" internally as "back EMF".

There are no internal friction and windage losses in an ideal motor. In an ideal motor, Ia will be zero when Vsupply = back EMF, at the ideal "no load speed".

The "no load speed" is defined as the speed a real DC motor runs, given a particular supply voltage, and there is no external mechanical load being driven by the shaft. The internal losses are not being ignored. Ia is not zero.

The component of Ia that is needed to overcome the internal friction and windage losses, varies as the square of the RPM.
I think i understand, so when back EMF = V, this speed is the ideal where losses are ignored and the no shaft speed is when when losses aren't ignored anymore
 
  • #11
Pipsqueakalchemist said:
I think i understand, so when back EMF = V, this speed is the ideal where losses are ignored and the no shaft speed is when when losses aren't ignored anymore
Also when you mean internal losses, you mean specifically rotational losses. Armature and field loss are still present in the ideal motor case where back emf = Vsupplied
 

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