These questions have been bothering me for ages:
1. At a certain place on the earth's surface, the horizontal component of the earth's magnetic field is 4.5 x 10^-5 T. A wire oriented at right angles to this horizontal component is moving vertically so it cuts the field at right angles with a speed of 25m/s. If the wire is 12m long, what is the magnetic flux cut per second?
2. A square loop of wire, WXYZ, of side 0.10m is held at right angles to a magnetic field of intensity 4.0 x 10^-4 T. The field is directed down into the page and exists only to the left of the line AB.
(a)
(i) Explain why no current will flow in the loop until the side XY crosses the line AB.
(ii) Calculate the emf induced in the coil as the side XY crosses the line AB.
(iii) This emf produces an induced current that flows clockwise in the loop. Lenz's law state that an induced current flows in such a direction as to oppose the change that caused it. How does the clockwise-flowing current "oppose the change that caused it"?
(b) The loop is now moved back to its original position. The magnetic field is then steadily decreased to 1.0 x 10^-4 T over an inerval of 2.0 x 10^-3 s. Calculate the emf generated in the loop.
3. Graph the voltage vs time graph for a DC dynamo, an alternator and a battery.
4. Compare a split ring communtator with a slip rings, and give the application of each.
THANKS
1. At a certain place on the earth's surface, the horizontal component of the earth's magnetic field is 4.5 x 10^-5 T. A wire oriented at right angles to this horizontal component is moving vertically so it cuts the field at right angles with a speed of 25m/s. If the wire is 12m long, what is the magnetic flux cut per second?
2. A square loop of wire, WXYZ, of side 0.10m is held at right angles to a magnetic field of intensity 4.0 x 10^-4 T. The field is directed down into the page and exists only to the left of the line AB.
(a)
(i) Explain why no current will flow in the loop until the side XY crosses the line AB.
(ii) Calculate the emf induced in the coil as the side XY crosses the line AB.
(iii) This emf produces an induced current that flows clockwise in the loop. Lenz's law state that an induced current flows in such a direction as to oppose the change that caused it. How does the clockwise-flowing current "oppose the change that caused it"?
(b) The loop is now moved back to its original position. The magnetic field is then steadily decreased to 1.0 x 10^-4 T over an inerval of 2.0 x 10^-3 s. Calculate the emf generated in the loop.
3. Graph the voltage vs time graph for a DC dynamo, an alternator and a battery.
4. Compare a split ring communtator with a slip rings, and give the application of each.
THANKS