According to Wikipedia, A flywheel is a spinning mechanized machine utilized to stock and release rotational power.
Flywheels are seen to possess an inertia, termed the "moment of inertia" which therefore resists alterations in rotational to their speeds, much like the mass (inertia) of an automotive system prevents its acceleration.
The level of power trapped in a flywheel is proportional to the square of its rotational movement.
Energy is delivered to a flywheel by the utilization of a torsional power to it, consequently raising its rotational velocity, and as a result its accumulated power. On the other hand, a flywheel produces collected energy by making use of torsional power to a physical load, consequently lowering the flywheel's rotational rate.
Typical applications of a flywheel incorporate:
Offering nonstop energy where the source of energy is discontinuous. As an illustration, flywheels are utilized in reciprocating motors since the power source, torque from these motors, are irregular.
Dispensing energy at rates beyond the capability of a persisting source of energy.
This is often accomplished by gathering energy in the flywheel progressively then simply discharging the energy swiftly, at rates that surpass the capabilities of the source of energy.
Managing the alignment of a mechanised equipment. In this kind of usages, the angular speed of a flywheel is specifically routed as a torsional power to the connecting mechanized system while energy is moved to or from the flywheel, consequently provoking the connecting equipment to move into certain expected position.
Flywheels are ideally made from steel and move over special high grade bearings; these are typically confined to a revolution value of several thousand RPM.
A number of contemporary flywheels are constructed of carbon fiber components and implement magnetic bearings, making it possible for these to rotate at rates up to 60,000 RPM.
The above discussion clearly states that flywheels have the potentials to generate an output power that may much higher than the input once it has been rotated to some specified high speed.
From the above discussion we can conclude that using a flywheel an overunity electricity generator can be achieved without much complications and skepticism.
Considering Flywheel as an Effective Free Electricity Generator
In this article we'll see how a flywheel can be used for executing an overunity result, and derive over 300% more output than the applied input.
In the diagram below we can see a simple flywheel with a motor set up:
This can be seen as a manual electricity generator using a flywheel wherein the flywheel needs to be pushed occasionally for sustaining a consistent rotation over the attached motor.
The motor wires can be appropriately terminated with a battery for acquiring the proposed free electricity from the set up.
The advantage of this set up is that once the flywheel is rotated with the specified maximum torque, the rotational can be sustained by pushing the flywheel with significantly less amount of energy.
Although efficient, the above set up may not look too impressive due to the requirement of an individual all the time near the system.