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Denken
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I know that a magnet passing through a coil will create a current in the wire. So what is stopping us from using magnets to power things?
Denken said:I know that a magnet passing through a coil will create a current in the wire. So what is stopping us from using magnets to power things?
Denken said:I know that a magnet passing through a coil will create a current in the wire. So what is stopping us from using magnets to power things?
Denken said:I know that a magnet passing through a coil will create a current in the wire. So what is stopping us from using magnets to power things?
There is a force, similar to friction, when you move a magnet past a coil through which a current can flow. So when you move a magnet past a coil to drive current, you have to have something continuously pushing on the magnet. Simplest example is a generator. You crank up the arm, and you get current flowing, but if you've ever tried that with a real generator, you know that it takes quite a bit of effort to do.Denken said:but it doesn't have to be dropped
it can be pushed sideways
Denken said:im just wondering for just a magnet moving through an uncharged coil, the charge created is creating a force back on the magnet
right?
Denken said:I've been studying a few things related to this so I am not just asking a bunch of question's and yes it does related to a ppm, my idea would be effectively a ppm however at a point the container would weaken to the point of breaking and stop it, so it is not a true ppm.
there are two ideas i have that i believe would virtually be perpetual:
1. having an open top rectangular container where the walls and floor are lined with magnets all but one of the smaller walls having either have + or - facing inward, and that one other wall being the opposite of the others. Then with a three sided "cart" lined with magnets facing outward and opposing, creating a levitating effect. Then having a magnet inside the cart facing in such a way as to repel from both of the smaller walls of the container. All within a vacuum.
2. is the same basic idea except with a circular track instead of a rectangular one, and instead of one "cart", having two that start next to each other and when released would bounce back and forth along the track.
Magnets generate power through the movement of electrons. The electrons within the magnet spin in the same direction, creating a magnetic field. When another object with electrons, such as a wire, moves through this magnetic field, it creates an electrical current which can be used to power devices.
Not all devices can be powered by magnets. The device must have a component that can convert the electrical current generated by the magnet into usable power. For example, devices like generators and electric motors can be powered by magnets, but devices like phones and computers require a battery to convert the electrical current into usable power.
The strength of a magnet needed to power a device depends on the size and type of device. Generally, stronger magnets are needed for larger devices or devices that require more power. However, even a small magnet can generate enough power for some devices.
No, magnets cannot power devices indefinitely. The energy created by the movement of electrons within the magnet will eventually dissipate, and the magnet will lose its magnetic field. However, with proper maintenance and care, magnets can continue to generate power for a long time.
There are several advantages to using magnets to power devices. They are a renewable source of energy, as magnets do not need to be replaced after they lose their magnetic field. They also do not produce any emissions, making them a clean source of energy. Additionally, magnets can be used in a variety of devices, from small electronics to large generators, making them a versatile option for powering devices.