The number of turns in the coil of an ac genrator is `5000` and the area of the coil is `0.25m^(2)`. The coil is rotate at the rate of `100 "cycles"//"sec"` in a magnetic field of `0.2W//m^(2)`. The peak value of the emf generated is nearly

In an ac generator, the number of turns in the coil is 2000 and the area of coil is 0.2 m^(2) . If the coil is rotated at an angular frequency of 400 S^(-1) in a magnetic field of 0.5 T , then what is the peak value of induced emf ?

A 100 turns coil shown in figure carries a current of 2 amp in a magnetic field B=0.2 Wb//m^(2) . The torque acting on the coil is

The coil of an a.c. generator has 100 turns, each of cross sectional area 2 m^(2) . It is rotating at a constant angular speed of 30 radians // s, in a uniform magnetic field of 2 xx 10^(-2) T. What is the maximum power dissipated in the circuit, if the resistance of the circuit including that of the coil is 600 Omega ?

A coil having an area of 0.4 m^(2) and 100 turns is kept perpendicular to a uniform magnetic field of induction of 0.5 Wb//m^(2) . The coil is rotated about one of is diameter so as to cut the lines of induction of the magnetic field. The average value of emf induced in the coil if it is rotated through 60^(@) in 2 seconds will be

An a.c generator consists of a coil of 1000 turns each of area 100 cm^(2) and rotating at an angular speed of 100 rpm in a uniform magnetic field fo 3.6 xx 10^(2) T. Find the peak and r.m.s value of e.m.f induced in the coil.

In an AC generator, a coil with N turns, all of the same area A and total resistance R, rotates with frequency (omega) in a magnetic field B. The maximum value of emf generated in the coils is

An a.c. generator consists of a coil of 2000 turns each of area 80 cm^(2) and rotating at an angular speed of 200 rpm in a uniform magnetic field of 4.8 xx 10^(-2) T . Calculate the peak and rms value of emf. Induced in the coil

A circular coil of wire consists of exactly 100 turns with a total resistance 0.20 Omega . The area of the coil is 100 cm^(2) . The coil is kept in a uniform magnetic field B as shown in Fig. 3.212. The magnetic field is increased at a constant rate of 2 Ts^(-1) . Find the induced current in the coil in A .