09-25-2023, 07:22 AM
It seems some do not understand the operation concept.
F = qv × B (The force F is always perpendicular to the direction of the magnetic field B)
In a visual aspect, lets say each magnet was a paint brush with red paint on it. While rotating 1 revolution, we will see the speedbump get painted red from top down in a smooth orderly fashion. Equivalent to swiping 1 paintbrush vertically but we accomplished it with horizontal motion.
The entire circle of wire sees no induction or moving magnetic field because the magnets are travelling in line with the direction of the wire at equal distance away. Except when it passes the speedbump. The speedbump receives a varying intensity of magnetic field as each magnet passes the speedbump. And although the rotor is spinning horizontal, the direction of travel is vertical (only over the speedbump..)
Since the physical movement is 90 degrees from the perceived moving magnetic field, the coil projects it's magnetic force vertical while the motion that caused it is horizontal.
There is no problem with Lenz in this geometry with regards to the magnet that is inducting. The problem comes from the magnets AFTER they have done their job and are past the speedbump. If the coil is outside the rotor- the magnets that aren't inducing get attracted or repelled from the coil's pole. But it is now not linked to induction anymore, so it should be able to be corrected.
So I am designing the coil so that it's poles are in line with the blotch walls of the magnets and putting the coil's poles 90 degrees offset from the magnets. So the rotor spins inside the coil.
F = qv × B (The force F is always perpendicular to the direction of the magnetic field B)
In a visual aspect, lets say each magnet was a paint brush with red paint on it. While rotating 1 revolution, we will see the speedbump get painted red from top down in a smooth orderly fashion. Equivalent to swiping 1 paintbrush vertically but we accomplished it with horizontal motion.
The entire circle of wire sees no induction or moving magnetic field because the magnets are travelling in line with the direction of the wire at equal distance away. Except when it passes the speedbump. The speedbump receives a varying intensity of magnetic field as each magnet passes the speedbump. And although the rotor is spinning horizontal, the direction of travel is vertical (only over the speedbump..)
Since the physical movement is 90 degrees from the perceived moving magnetic field, the coil projects it's magnetic force vertical while the motion that caused it is horizontal.
There is no problem with Lenz in this geometry with regards to the magnet that is inducting. The problem comes from the magnets AFTER they have done their job and are past the speedbump. If the coil is outside the rotor- the magnets that aren't inducing get attracted or repelled from the coil's pole. But it is now not linked to induction anymore, so it should be able to be corrected.
So I am designing the coil so that it's poles are in line with the blotch walls of the magnets and putting the coil's poles 90 degrees offset from the magnets. So the rotor spins inside the coil.