Solving Faraday's Law: 0.73V Induced EMF Help Needed

AI Thread Summary
The discussion focuses on calculating the induced electromotive force (EMF) using Faraday's Law, specifically addressing an induced voltage of 0.73 volts. Participants clarify that the vertical component of the Earth's magnetic field should be considered, and emphasize that if there is no change in magnetic flux (dΦ/dt), the induced EMF would be zero. They suggest treating the wingspan of the aircraft as a conducting rod and using the Blv law instead of relying on changing flux. The conversation highlights the complexities of applying Maxwell's equations to moving media, reinforcing the importance of accurate calculations in electromagnetic scenarios. Ultimately, the consensus is that the initial approach may not yield the correct results due to the lack of flux change.
Bolter
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Homework Statement
Calculate EMF induced on tips of an aircraft wing
Relevant Equations
Faraday's law
Screenshot 2020-02-19 at 17.38.38.png

I have a simple sketch of the diagram, and I know I must use the vertical component of the magnetic field of the Earth when doing this problem

IMG_3901.JPG


I got an induced emf of 0.73 volts but I do not know if I correctly substituted the right values into faraday's law equation?

Any help will be really appreciated! Thanks
 
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I agree with the answer you gave, though I think you're supposed to treat the wingspan as a conducting rod. Like @berkeman mentioned, there isn't a rate of change of flux linked in the actual wing, only the flux linked in an imaginary loop like below:

1582134921795.png


We then have ##\varepsilon = B_{v}lv## where the three terms are mutually orthogonal.
 
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The Lorentz Force will exert forces on the electrons in the wing material, so maybe there is a way to calculate the voltage generated that way. The force due to qv X B will be balanced by qE, so there will be an electric field pointing along the wing. That will generate a small voltage, but I don't think you can use dΦ/dt to do the calculation, since Φ is not changing.
 
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Do you get that same answer when you use the Hyperphysics calculator that I linked?
 
berkeman said:
Do you get that same answer when you use the Hyperphysics calculator that I linked?

Yes :)
 
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berkeman said:
... I don't think you can use dΦ/dt to do the calculation, since Φ is not changing.
I second that. In general it is dangerous to apply maxwell' s equations (which is what Farady's law is based on) to moving media.
The correct way is to use the Blv law which is what @berkeman stated.
 
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