Effect of Changing Magnetic Field on Flux through a Coil

Click For Summary
SUMMARY

The discussion centers on the effects of changing the magnetic field on the magnetic flux through a coil. When the magnetic field B increases while remaining perpendicular to the coil, the magnetic flux increases due to the direct proportionality between magnetic field strength and flux. Conversely, if the coil is rotated to be parallel to the magnetic field, the flux decreases to zero as the angle between the field and the coil's axis changes to 90 degrees. The key equations referenced include the magnetic flux formula, Φ = BAcosθ, which governs these relationships.

PREREQUISITES
  • Understanding of magnetic flux and its calculation using Φ = BAcosθ
  • Knowledge of the relationship between magnetic field strength and flux
  • Familiarity with the concepts of angles in relation to magnetic fields
  • Basic principles of electromagnetism
NEXT STEPS
  • Study the implications of Faraday's Law of Electromagnetic Induction
  • Explore the effects of coil orientation on magnetic flux in different configurations
  • Learn about applications of magnetic flux in electrical engineering
  • Investigate the role of magnetic field strength in electromagnetic devices
USEFUL FOR

Students of physics, electrical engineers, and anyone studying electromagnetic theory will benefit from this discussion, particularly those focusing on magnetic fields and their effects on coils.

cse63146
Messages
435
Reaction score
0

Homework Statement


You hold a wire coil perpendicular to a magnetic field B. If the magnitude of B increases while its direction remains unchanged, how will the magnetic flux through the coil change?

Check all that apply:

The flux is unchanged because the position of the coil with respect to B is unchanged.
The flux increases because the magnitude of B increases.
The flux decreases because the magnitude of B increases.
The flux is unchanged because the surface area of the coil is unchanged.

Homework Equations



A_{eff} = Acos\vartheta

The Attempt at a Solution



According to the formula - A_{eff} = Acos\vartheta, the magnetic flux is determined by the area. I believe the answer is "flux is unchanged because the surface area of the coil is unchanged" since in the problem, only B is changing.

Am I right?
 
Physics news on Phys.org
Magnetic flux linkage is given by:

\Phi =BAcos\theta
 
Ah, since magnetic filed is directly proportional to the magnetic flux, it would make the solution - The flux increases because the magnitude of B increases, correct?
 
cse63146 said:
Ah, since magnetic filed is directly proportional to the magnetic flux, it would make the solution - The flux increases because the magnitude of B increases, correct?

Correct.
 
Thanks, but another question "unlocked" itself after I finished the first one:

If B is kept constant but the coil is rotated so that it is parallel to B, how will the magnetic flux through the coil vary?

The flux is unchanged because the magnitude of B is constant.
The flux increases because the angle between B and the coil's axis changes.
The flux decreases because the angle between B and the coil's axis changes.
The flux is unchanged because the area of the coil is unchanged.

So \Phi = ABcos\vartheta and since the coil is parallel to B, it means \vartheta0 and cos\vartheta = 1 so in this case \Phi = AB and since B is constant and so is A, there are two answers:

i) The flux is unchanged because the magnitude of B is constant.
ii) The flux is unchanged because the area of the coil is unchanged.

Correct?
 
Last edited:
can someone just double check me reasoning/answer, as this is the last question on my assigment.

Thank You.
 
When the coil is perpendicular:
\theta=0

When the coil is parallel, the tilt is 90 degrees, and the magnetic flux is 0. You can imagine flux as the number of field lines passing through the area. If the coil is parallel to the magnetic field, none of the field lines get passed the area bounded by the coil.
 
Since it's being rotated so it would be parallel, \vartheta is decreasing so the answer is:

The flux decreases because the angle between B and the coil's axis changes. Correct?
 
Yes.
 
  • #10
Thank you both for all your help.
 

Similar threads

EMF induced by a magnet falling through a coil
  • · Replies 4 ·
Replies
4
Views
3K
Flux linking (and de-linking?)
  • · Replies 6 ·
Replies
6
Views
1K
Is the magnetic flux density B constant?
  • · Replies 6 ·
Replies
6
Views
2K
Will EMF be induced in a coil that is accelerating in a uniform magnetic field?
  • · Replies 4 ·
Replies
4
Views
1K
Trace on the screen of a C.R.O. when a deflection coil is rotated
  • · Replies 9 ·
Replies
9
Views
1K
Current induced on a coil by a changing magnetic flux in another coil
  • · Replies 5 ·
Replies
5
Views
3K
AC generator -- Understanding coil voltages as function of position
  • · Replies 1 ·
Replies
1
Views
2K
Eddy currents in Faraday's Law Experiment
  • · Replies 3 ·
Replies
3
Views
2K
Motional EMF in the presence of a time-varying magnetic field
  • · Replies 11 ·
Replies
11
Views
3K
The magnetic flux and the induce emf in the dynamo.
  • · Replies 8 ·
Replies
8
Views
3K