Suppose we connect the ends of the thin wire from Problem 1, and curl it into a coil that is 30 turns, and has a resistance of 20 N. We then move the coil from a location 0.50 m above the Large Wire to a location 0.03 m above the large wire, in a time interval of 50 ms. 1. (How should the coil be oriented to experience the greatest magnetic flux? Explain. 2. Draw a diagram showing this orientation of the coil and the Large Wire, label the directions of currents, and all other relevant quantities and vectors. 3. Find the power dissipated by the coil at is it moved. 4. Suppose that instead of the coil moving from 0.50 m to 0.03 m above the Large Wire, it moved from 0.03 m t 0.50 m below the Large Wire. Would you answers to parts A and C change? Don't calculate any values, but draw a new diagram and explain and explain how this situation compares to the problem above.

Suppose we connect the ends of the thin wire from Problem 1, and curl it into a coil that is 30 turns, and has a resistance of 20 N. We then move the coil from a location 0.50 m above the Large Wire to a location 0.03 m above the large wire, in a time interval of 50 ms. 1. (How should the coil be oriented to experience the greatest magnetic flux? Explain. 2. Draw a diagram showing this orientation of the coil and the Large Wire, label the directions of currents, and all other relevant quantities and vectors. 3. Find the power dissipated by the coil at is it moved. 4. Suppose that instead of the coil moving from 0.50 m to 0.03 m above the Large Wire, it moved from 0.03 m t 0.50 m below the Large Wire. Would you answers to parts A and C change? Don't calculate any values, but draw a new diagram and explain and explain how this situation compares to the problem above.

University Physics Volume 2

18th Edition

ISBN:9781938168161

Author:OpenStax

Publisher:OpenStax

Chapter13: Electromagnetic Induction

Section: Chapter Questions

Problem 69AP: The conducting rod shown in the accompanying figure moves along parallel metal rails that are 25-cm...

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