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Conductor moving perpendicular to magnetic field

Starting from the fundamental form of Faraday’s law, derive a tangible equation for the induced voltage in a conductor of length l moving in a magnetic field of flux density B with a velocity v perpendicular to the magnetic field Figure 1: Conductor moving perpendicular to magnetic field.             According to Faraday’s law in order to induce voltage in a conductor we must have: ·                      Magnetic field (B). ·                      Conductor (l). ·                      Motion (v). If the conductor is moved through a magnetic field a voltage is induced in the conductor. The induced voltage is proportional to magnetic field, conductor   and the direction of motion of the conductor.                E E=KBv. Where K is a constant and in SI units   in m, B in wb/m 2 , v in m/s then K=1.             E=Blv. MT ( Light ) Shop , Lathe Section , Milling Section, Grinding Section, Jig section , Monocrystalline solar cell us