The concept behind it is simple, but if you’re a high school student and don’t have experience in the world of engineering, the task can be a bit of a challenge. When electricity flows directly between two objects such as electrons, two things happen, a negative current will flow and a positive current will flow in the opposite direction. However, in order for one of these currents to flow, it has to be a flow, not a current, as current is defined as the flow of something between two things. Now if someone is to demonstrate this concept with a flywheel the result could be a very surprising result.

The idea of having a rotating flywheel seems very interesting but is the reality of it hard to demonstrate? Yes, this is exactly what I’m going to demonstrate. It’s possible to explain away how this concept works and also describe why this concept works. If you don’t understand this concept at all when I explain it to you, you are probably better off not reading this article.

It’s easier to understand that if you imagine the flywheel as rotating on a motor. An AC current flows across the flywheel and the flywheel rotates according to the rotational angle of the current and the direction of the current. For the sake of simplicity let’s say our flywheel is a single flywheel, the motor shaft is stationary, and we are rotating the flywheel with respect to the motor shaft.

Let’s look at the flywheel rotation of one flywheel rotating at 60 deg. It turns at 120 rotations per minute, or 60 revolutions per second.

However, this flywheel will rotate more slowly at a lower rate than if it were spinning at a constant speed and the speed of rotation inversely proportional to the rotational speed. For instance, the speed of rotation is a constant 30 rotations per minute, however, the rotational speed is only 17 rotations per minute or approximately 1/4 the rotational speed of 1/60. Therefore the flywheel will rotate more slowly at a lower rate (0.4 seconds versus 17), however, it will operate much faster.

The rate of rotational speed depends on the mass, density and velocity of the material between the two materials, so it’s the rotational speed of the material and the rotational speed of the flywheel that determines the rate of rotation.

When applying this concept to the case of electricity flowing from an AC power line, the rotational speed varies with the speed at

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