Solving Sliding Wire Problem: Determine Magnitude & Direction of Current

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SUMMARY

The discussion focuses on solving the Sliding Wire Problem involving a conducting wire on a frictionless incline in a uniform magnetic field. The required current to keep the wire at rest is derived from the equation I = 9.8M / (LB), where M is the mass of the wire, L is its length, and B is the magnetic field strength. The direction of the current is determined using the right-hand rule, indicating that the current flows from the right to the left. Additionally, participants emphasize the importance of considering the angles involved in the forces acting on the wire.

PREREQUISITES
  • Understanding of magnetic forces, specifically the equation dF = Idl × B.
  • Knowledge of the right-hand rule for determining current direction in magnetic fields.
  • Familiarity with free-body diagrams and their application in physics problems.
  • Basic principles of mechanics, including forces acting on inclined planes.
NEXT STEPS
  • Study the application of the right-hand rule in electromagnetic contexts.
  • Learn about free-body diagram techniques for analyzing forces in physics.
  • Explore the Biot-Savart Law for calculating magnetic fields due to currents.
  • Investigate the dynamics of inclined planes and their relation to magnetic forces.
USEFUL FOR

Physics students, educators, and anyone interested in understanding the dynamics of conducting wires in magnetic fields, particularly in the context of electromagnetism and mechanics.

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Homework Statement



A straight piece of conducting wire with mass M and length L is placed on a frictionless incline tilted at an angle theta from the horizontal. There is a uniform, vertical magnetic field vecB at all points (produced by an arrangement of magnets not shown in the figure). To keep the wire from sliding down the incline, a voltage source is attached to the ends of the wire. When just the right amount of current flows through the wire, the wire remains at rest.

YF-27-67.jpg


Determine the magnitude of the current in the wire that will cause the wire to remain at rest.
Express your answer in terms of the variables M, theta, L, B, and appropriate constants.

Determine the direction of the current in the wire that will cause the wire to remain at rest.

In addition viewing the wire from its left-hand end, show in a free-body diagram all the forces that act on the wire.

Homework Equations



dF = Idl ×B
or possible the bio-stavart law.. I'm not sure

The Attempt at a Solution



the current must be directed from the right to the left i think?

other than that, unsure how to start, just chasing a hint or beginning to work from.

thanks heaps.
 
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ok so force pulling the wire down:

F=masinθ
= -9.8Msinθ

so for the rest:

F=ILBsinθ
9.8Msinθ=ILBsinθ
9.8M=ILB
I=9.8M/LB ??
 
and the current would go to the left, determined by the right hand rule?
 
EvanQ said:
and the current would go to the left, determined by the right hand rule?
Yes, but be careful with the angles. The angle between current and magnetic field is 90°, and so the resulting force points horizontally. One has to ensure that the force on the wire parallel to incline matches the weight component down the incline.

In this geometry, the angle between magnetic field and current is not the angle of the incline.
 
9.8Msin180=ILBsin90??
 
really confused sorry :(
 
Think in 3D. You know the force F_b=\vec{B}\times \vec{i}L. Here the force is perpendicular to both the current and the magnetic field. Using the left hand rule, find out the direction of the current, and the equate the appropriate components.
 

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