A metallic ring of radius r with a uniform metallic spoke of negligible mass and length r is rotated about its axis with angular velocity omega in a perpendicular uniform magnetic field B as shown in Fig. 3.163. The central end of the spoke is connected to the rim of the wheel through a resistor R as shown. The resistor does not rotate, its one end is always at the center of the ring and the other end is always in as shown is needed to maintain constant angular velocity of the wheel. F is equal to (the ring and the spoke has zero resistance)

A metallic ring of radius r with a uniform metallic spoke of negligibl

1.	A metallic ring of radius r with a uniform metallic spoke of negligible mass and length r is rotated about its axis with angular velocity omega in a perpendicular uniform magnetic field B as shown in Fig. 3.163. The central end of the spoke is connected to the rim of the wheel through a resistor R as shown. The resistor does not rotate, its one end is always at the center of the ring and the other end is always in as shown is needed to maintain constant angular velocity of the wheel. F is equal to (the ring and the spoke has zero resistance)
Answer» (a) `(B^(2)omegar^(2))/(8R)` (b) `(B^(2)omegar^(2))/(2R)` ( c) `(B^(2)omegar^(3))/(2R)` (d) `(B^(2)omegar^(3))/(4R)` Solution :(d) Induced emf in the SPOKE is SHOWN in figure below. `e = (1)/(2)Bomegar^(2), I = (e)/(R ) = (Bomegar^(2))/(2R)` There will be no induced emf SEPARATELY in parts `ADC`or `AEC`. `F_(b) = IrB = (B^(2)omegar^(3))/(4R)` balancing torque about `E`: `FR = F_(b)r//2` RARR `F = (F_(b))/(2) = (B^(2)omegar^(3))/(4R)`

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