Q23 of 91 Page 230

A metal wire PQ of mass 10 g lies at rest on two horizontal metal rails separated by 4.90 cm figure. A vertically downward magnetic field of magnitude 0.800 T exists in the space. The resistance of the circuit is slowly decreased and it is found that when the resistance goes below 20.0 Ω, the wire PQ starts sliding on the rails. Find the coefficient of friction.




Given-



Mass of the metal wire, M = 10 g




Distance between the two metallic strips, l = 4.90 cm



Magnetic field acting vertically-downward, B = 0.800 T



Given in the question that when the resistance of the circuit is slowly decreased below 20.0Ω the wire end PQ starts sliding on the metallic rails.


At that time, current I from ohm’s law becomes


where,


v= applied voltage and


R = resistance of the circuit




From Fleming’s left-hand rule, we can confer that the magnetic force will act towards the right.


This magnetic force will make the wire glide on the rails.


The frictional force present at the surface of the metallic rails will try to oppose this motion of the wire.


When the wire starts sliding on the rails, the frictional force acting on the wire present between the wire and the metallic rail will just balance the magnetic force acting on the wire due to current flowing through it.


Thus,



,


where



μ is the coefficient of friction



R is the normal reaction force and



F is the magnetic force


frictional force will be equal.



where


μ is the coefficient of friction for the two surfaces


W is the weight of the object


= mass × acceleration due to gravity


= mg


Also,


Magnetic force due to presence of current given by –




where,


B= magnetic field


I = current


l = length of the wire


and θ = the angle between B and l


Hence,




substituting values






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(a) Find the tension in the threads when the switch S is open.


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Two metal strips, each of length ℓ, are clamped parallel to each other on a horizontal floor with a separation b between them, A wire of mass m lies on them perpendicularly as shown in figure. A vertically upward magnetic field of strength B exists in the space. The metal strips are smooth but the coefficient of friction between the wire and the floor is μ. A current i is established when the switch S is closed at the instant t = 0. Discuss the motion of the wire after the switch is closed. How far away from the strips will the wire reach?


 24

A straight wire of length ℓ can slide on two parallel plastic rails kept in a horizontal plane with a separation d. The coefficient of friction between the wire and the rails is μ. If the wire carries a current i, what minimum magnetic field should exist in the space in order to slide the wire on the rails.

 25

Figure shows a circular wire-loop of radius a, carrying a current i, placed in a perpendicular magnetic field B.

(a) Consider a small part dl of the wire. Find the force on this part of the wire exerted by the magnetic field.


(b) Find the force of compression in the wire.