The diagram shows a circuit having a coil of resistance R = 2.5 (Omega) and inductance L connected to a conducting rod PQ which can slide on perfectly conducting circular ring of radius 10 cm with its centre at 'P'. Assume that friction and gravity are absent and a constant uniform magnetic field of 5 T exist as shown in Fig. At t = 0, the circuit is switched on and simultaneously a time varying external torque is applied on the rod so that it rotates about P with a constant angular velocity 40 rad//s. Find magnitude of this torque (in milli Nm) when current reaches half of its maximum value. Neglect the self-inductance of the loop formed by the circuit.

The diagram shows a circuit having a coil of resistance R = 2.5 (Omega

1.	The diagram shows a circuit having a coil of resistance R = 2.5 (Omega) and inductance L connected to a conducting rod PQ which can slide on perfectly conducting circular ring of radius 10 cm with its centre at 'P'. Assume that friction and gravity are absent and a constant uniform magnetic field of 5 T exist as shown in Fig. At t = 0, the circuit is switched on and simultaneously a time varying external torque is applied on the rod so that it rotates about P with a constant angular velocity 40 rad//s. Find magnitude of this torque (in milli Nm) when current reaches half of its maximum value. Neglect the self-inductance of the loop formed by the circuit.
Answer» Solution :Induced emf = `1/2 B omega l^(2)` Maximum current : `i_(0) =(Bomegal^(2))/(2R)` TORQUE about the hinge P is `tau=int_()^(1) i(dx)Bxd implies tau = 1/2 iBl^(2)` put `i=i_(0)//2`, we GET , `tau = (B^(2)omegal^(4))/(8R)=5 MMM`.

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