Resultant magnetic flux in a 3-phase induction motor

In summary, according to the textbook, the value of resultant flux is constant in magnitude and 1.5 times the maximum value of flux, with the magnetic flux waveforms being 120° apart from each other and the instantaneous value of the flux waveform of the first phase being zero at time 0. There is some confusion regarding the equation Φr = 2.(√3/2)Φm.cos60/2 and whether it should be Φr = 2.(√3/2)Φm.cos120/2. The solution involves using the parallelogram rule of vector addition and rotating the second vector by 180° to get the correct angle of 60° between the two ph
  • #1
rishi kesh
35
3

Homework Statement


I have some attachements below from my textbook. According to it the value of resultant flux is constant in magnitude and 1.5 times the maximum value of flux.
But i have a doubt regarding how it is proved.
The magnetic flux waveforms are 120° apart from each other and at time 0, the instantaneous value of flux waveform of 1st phase is zero. Whereas 2nd phase has magnitude -√3/2.Φm and the third phase √3/2.Φm.The textbook says that:
Φr = 2.(√3/2)Φm.cos60/2
Here is my doubt
If the fluxes are 120° apart, shouldn't the equation be: Φr = 2.(√3/2)Φm.cos120/2 ?
Please explain me in the simple way how this works.i appreciate the help:) [/B]

Homework Equations


I know that when forces have same magnitudes then for resultant force we use the formula:
R=2.F.cosΘ/2[/B]

The Attempt at a Solution


I have been trying to think about it and draw a waveform to figure it out but couldn't understand it.
 

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  • #2
Looks like you're studying from B.L.Theraja.

You can do it yourself. Just draw two phasors of magnitudes √3/2 and -√3/2 , and 120° apart. Use the parallelogram rule of vector addition and you'll get Φ=1.5Φm.
 
  • #3
cnh1995 said:
Looks like you're studying from B.L.Theraja.

You can do it yourself. Just draw two phasors of magnitudes √3/2 and -√3/2 , and 120° apart. Use the parallelogram rule of vector addition and you'll get Φ=1.5Φm.
Hi! Can you please solve this and send a picture right here? I will appreciate that. And also explain this little bit more.
 
  • #4
  • #6
rishi kesh said:
Please explain me how to derive it to get resultant flux. I really need help.
Do you know the parallelogram law of vector addition?
cnh1995 said:
Just draw two phasors of magnitudes √3/2 and -√3/2 , and 120° apart. Use the parallelogram rule
That's how you can derive it. I can't make it any simpler.
 
  • #7
cnh1995 said:
Do you know the parallelogram law of vector addition?

That's how you can derive it. I can't make it any simpler.
This is what I am getting as answer
 

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  • #8
rishi kesh said:
This is what I am getting as answer
But the same one when i solve using cos60/2 :
 

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  • #9
The formula you used in #7 works for two 'equal' vectors. The fluxes here are √3/2 and
-√3/2, which are not equal. You can rotate the second vector by 180° and its magnitude will be √3/2. Now the angle between the two phasors is 60° and the formula works as it did in #8.
 
  • #10
cnh1995 said:
The formula you used in #7 works for two 'equal' vectors. The fluxes here are √3/2 and
-√3/2, which are not equal. You can rotate the second vector by 180° and its magnitude will be √3/2. Now the angle between the two phasors is 60° and the formula works as it did in #8.
Oh i got it! Here is one more attachment. This is how i need to think about it?
 

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  • #11
rishi kesh said:
Oh i got it! Here is one more attachment. This is how i need to think about it?
That's right.
 
  • #12
cnh1995 said:
The formula you used in #7 works for two 'equal' vectors. The fluxes here are √3/2 and
-√3/2, which are not equal. You can rotate the second vector by 180° and its magnitude will be √3/2. Now the angle between the two phasors is 60° and the formula works as it did in #8.
Thanks so much i really got this concept clear today. I realized that what i didn't know is that vectors can't have negative magnitude now if i keep this in mind my concept about resultant flux is clearly understood. :)
I am so thankful to you :)
 
  • #13
rishi kesh said:
Thanks so much i really got this concept clear today. I realized that what i didn't know is that vectors can't have negative magnitude now if i keep this in mind my concept about resultant flux is clearly understood. :)
I am so thankful to you :)
You're welcome!:smile:
 
  • #14
cnh1995 said:
You're welcome!:smile:
Hi !
Sorry, but one more question is overwhelming me right now.
Does the magnitude of resultant flux not get affected when we move -√3/2 by 180°.
Is it okay to do so ?
 
  • #15
rishi kesh said:
Hi !
Sorry, but one more question is overwhelming me right now.
Does the magnitude of resultant flux not get affected when we move -√3/2 by 180°.
Is it okay to do so ?
Yes.
Rotating a vector by 180° and changing its sign gives the same vector. It is like multplying a number by -1 twice.
 
  • #16
cnh1995 said:
Yes.
Rotating a vector by 180° and changing its sign gives the same vector. It is like multplying a number by -1 twice.
Okay. So what does negative sign mean ? Does it mean opposite direction? Like if right side is positive then left is negative?
 
  • #17
rishi kesh said:
Okay. So what does negative sign mean ? Does it mean opposite direction? Like if right side is positive then left is negative?
Kind of like that, yes.
 
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1. What is the significance of resultant magnetic flux in a 3-phase induction motor?

The resultant magnetic flux in a 3-phase induction motor is crucial in producing the rotating magnetic field that drives the motor's rotation. It is the combined effect of the three-phase currents in the stator windings and is responsible for inducing an electromagnetic force on the rotor, causing it to rotate.

2. How is the resultant magnetic flux calculated in a 3-phase induction motor?

The resultant magnetic flux in a 3-phase induction motor can be calculated using the formula:
Φ = √ (Φa² + Φb² + Φc² + 2ΦaΦbcos(2π/3) + 2ΦbΦccos(4π/3) + 2ΦcΦacos(6π/3))
Where Φa, Φb, and Φc are the individual magnetic fluxes produced by the three-phase currents.

3. How does the resultant magnetic flux affect the motor's performance?

The magnitude and direction of the resultant magnetic flux directly affect the motor's speed and torque. A higher resultant magnetic flux translates to a stronger rotating magnetic field, resulting in a higher motor speed and torque. Conversely, a lower resultant magnetic flux will lead to a slower motor speed and lower torque.

4. Can the resultant magnetic flux be controlled in a 3-phase induction motor?

Yes, the resultant magnetic flux can be controlled by varying the stator current frequency and magnitude. By adjusting the frequency and magnitude of the three-phase currents, the strength and direction of the resultant magnetic flux can be altered, allowing for speed and torque control of the motor.

5. What factors can affect the resultant magnetic flux in a 3-phase induction motor?

The resultant magnetic flux in a 3-phase induction motor can be affected by various factors such as the number of stator windings, the magnitude and frequency of the stator currents, the type and condition of the motor's rotor, and the presence of any external magnetic fields. These factors can impact the motor's performance and should be carefully considered during the design and operation of the motor.

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