Two concentric coils each of radius equal to 2 cm are placed at right angles to each other. If 3A and 4A are the currents flowing through the two coils respectively. The magnetic induction (in Wb m-2) at the centre of the coils will be
5 × 10-5
12 × 10-5
7 × 10-5
10-5
Two coils have a mutual inductance 0.005 H. The current changes in the first coil according to the equation I = im sin ωt, where im = 10 A and ω = 100 rad s-1. The maximum value of the emf induced in the second coil is
A wheel with 10 spokes each of length L m is rotated with a uniform angular velocity ω in a plane normal to the magnetic field B. The emf induced between the axle and the rim of the wheel is
NωBL2
When 100 V DC is applied across a coil, a current of 1 A flows through it. When 100 V AC of50 Hz is applied to the same coil only 0.5 A flows. The inductance of the coil is
5.5 mH
0.55 mH
55 mH
0.55 H
An aluminium ring B faces an electromagnet A. The current I through A can be altered. Then which of the following statements is correct ?
If I decreases, A will repel B
Whether I increases or decreases, B will not experience any force
If I increases, A will repel B
If I increases, A will attract B
A long solenoid has 1000 turns. when a current of 4 A flows through it, the magnetic flux linked with each turn of the solenoid is 4x10-3 Wb. The self inductance of the solenoid is,
3H
2H
1H
1H
An electron moving in a circular orbit of radius r makes n rotations per second. The magnetic field produced at the centre has magnitude.
zero
D.
As I = q/t
So, for an electron revolving in a circular orbit of radius r
q = e and t =T
A conducting square frame of side 'a' and a long straight wire carrying current I are located in the same plane as shown n the figure. The frame moves to the right with constant velocity 'v'. The emf induced in the frame will be proportional to
A coil of resistance 400 is placed in magnetic field. If the magnetic flux Φ (Wb) linked with the coil varies with time t (sec) as Φ = 50t2 +4.
The current in the coil at t= 2 s is
0.5 A
0.1 A
2 A
2 A
A thin semicircular conducting ring (PQR) of radius r is falling with its plane vertical in a horizontal magnetic field B, as shown in figure. The potential difference developed across the ring when its speed is v, is
zero