Asynchronous Motor: Short Circuiting Rotor & Magnetic Fields

In summary, the conversation discusses the use of current in the rotor of an asynchronous 3-phase motor to create electromagnets and align them with the rotating magnetic fields from the stator. This is necessary because ferromagnetic materials can only be temporarily magnetized and cannot vary their magnetic direction. The concept of "saliency" is also mentioned as a way to create torque in a motor, resulting in a type of motor called a "reluctance motor".
  • #1
hisham.i
176
2
If we have a magnetic field and a ferromagnetic material subjected to this field, the body will rotate until its magnetic axis is aligned with that of the field..
My question is: In asynchronous 3-phase motor, we have a rotating field.. so why we need to make a short circuited rotor and we don't apply the same principle of aligning the magnetic fields in such a motor? why we need a current to flow in the rotor ?
 
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  • #2
The rotor is soft iron which cannot be permanently magnetized.

The flow of current in the shorted turns turns the rotor into a number of electromagnets which will then try to follow the rotation of the magnetic fields from the stator.

You could have permanent magnets in the rotor, but they cannot vary their magnetic direction, so you would have to bring the rotor up to synchronous speed for it to work properly.
 
  • #3
But ferromagnetic materials have a property that they can be aligned to the magnetic field very quickly, when the axis of stator magnetic field is aligned with that of the rotor, then the rotor will follow the rotating magnetic field at each instant...
 
  • #4
hisham.i said:
But ferromagnetic materials have a property that they can be aligned to the magnetic field very quickly, when the axis of stator magnetic field is aligned with that of the rotor, then the rotor will follow the rotating magnetic field at each instant...

Yes but there won't be any aligning torque if the rotor has cylindrical symmetry. If you include "saliency", either by non-cylindrical shape or by use of axial laminations, then you can get torque this way. This type of motor is called a "reluctance motor".
 

1. What is an asynchronous motor?

An asynchronous motor, also known as an induction motor, is a type of electric motor that uses electromagnetic induction to generate rotational motion. It is commonly used in industrial and commercial applications due to its simplicity, reliability, and low maintenance requirements.

2. What is a short circuiting rotor in an asynchronous motor?

A short circuiting rotor is a type of rotor design in an asynchronous motor where the rotor bars are connected together by end rings. This allows the rotor to develop a magnetic field and interact with the stator's rotating magnetic field, resulting in the production of torque and rotational motion.

3. How does a short circuiting rotor differ from a squirrel cage rotor?

A squirrel cage rotor is a type of rotor design in an asynchronous motor where the rotor bars are permanently short-circuited together through end rings, resulting in a simple and robust structure. In contrast, a short circuiting rotor has a slightly more complex structure with the rotor bars being connected through end rings only during starting and then disconnected during normal operation.

4. What are the advantages of using a short circuiting rotor in an asynchronous motor?

Short circuiting rotors offer several advantages over squirrel cage rotors, including improved starting torque, higher efficiency, and better speed control. They also have lower inertia, reducing the risk of motor stalling and allowing for faster acceleration and deceleration.

5. How are magnetic fields used in an asynchronous motor?

In an asynchronous motor, the stator's rotating magnetic field interacts with the short-circuited rotor's magnetic field, resulting in the production of torque and rotational motion. The speed of the motor is determined by the frequency of the alternating current supplied to the stator and the number of poles in the stator's winding.

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