Two straight conducting rails form a right angle where their ends are joined. A conducting bar in contact with the rails starts at the vertex at time t = 0 and moves with constant velocity v along them as shown in Fig. A magnetic field `vec(B)` is directed into the page. the induced emf in the circuit at any time t is proportional to

Two straight conducting rails form a right angle where their ands are joined. A conducting bar contanct with the rails starts at vertex at the time t=0 & moves symmetrically with a constant velocity of 5.2 m//s to the right as shown in figure. A 0.35 T magnetic field point out of the page. Calculate: (i) The flux through the tringle by the rails & ber at t=3.0 s . (ii) The emf around the tringle at that time. In what manner does the emf around the tringle vary with time.

Two straight conducting rails from a right angle where their end are joined. A conducting bar polaced over the rails starts at vertex at the time t=0 and moves with a constant velocity v to the right as shown in the figure. Calculate (a) the flux through the triangle (isosceles) by the rails and bar at t=t_(0) the emf around the triangle at that time (c) in what manner does the emf around the triangle vary with time

A conducting rod, with a resistor of resistance R. is pulled with constant speed v on a smooth conducting rail as shown in figure. A constant magnetic field vecB is directed into the page. If the speed of the bar is doubled, by what factor does the rate of heat dissipation across the resistance R change?

The two conducting rails are placed perpendicular to each other, such that their ends are joined as shown in figure. A conducting bar is now placed over the rails and start moving with constant velocity v starting from the vertex at time t = 0. (i) The flux through the triangle (isosceles) by the rails and bar at t=t_(0) . (ii) The emf around the triangle at that time. (iii) In what manner does the emf around the triangle vary with time.

A conducting bar is slid at a constant velocity v along two conducting rods. The rods ar seprated by a distance l and connected across a resistor R. The entire apparatus is placed in an external magnetic field B directed into the page The induced current in the above circuit is:

Two parallel long smooth conducting rails separated by a distance l are connected by a movable conducting connector of mass m . Terminals of the rails are connected by the resistor R and the capacitor C as shown in figure. A uniform magnetic field B perpendicular to the plane of the rail is switched on. The connector is dragged by a constant force F . Find the speed of the connector as a function of time if the force F is applied at t = 0 . Also find the terminal velocity of the connector.

A rod of length 10 cm made up of conducting and non-conducting material (shaded part is non-conducting). The rod is rotated with constant angular velocity 10 rad//s about point O , in constant magnetic field of 2 T as shown in the figure. The induced emf between the point A and B of rod will be:

in fig. The four rods have lambda resistance per unit length. The arrengement is kept in a magnetic field of constant magnitude B and directed perpendicular to the plane of the figure and directing in ward. Initially, the sides as shown form a square. Now each wire starts moving with constant velocity v toward the opposite wire. Find as a function of time: (a) induced emf in the circuit. (b) induced current in the circuit with direction. ( c ) force required on each wire to keep its velocity consatnt. (d) total power required to maintain constant velocity. (e) thermal power developed in the circuit.