An inertial and magnetic machine based on neodymium permanent magnets, whose main functional assumptions involve synchronizing the rotation of a central mass or two masses that move outward and inward with a reciprocating motion and flywheels. While the central mass oscillates between static plates with four neodymium permanent magnets on each side, arranged 45 degrees apart, this mass, also having four magnets arranged 45 degrees apart in a circle, completes one rotation, each time striking pairs of magnets with pairs of outer magnets of the same polarity. Therefore, the closer they are on each side, the stronger the repulsion. The central mass is mounted on a central shaft that runs almost the entire length of the device. On one side, it is connected to a bearing-mounted hinge, which allows the shaft to be pushed and rotated simultaneously. An extension of this shaft, behind the hinge, is a shaft section connected to the flywheel via an off-center arrangement, enabling reciprocating motion and rotation of the flywheel, which is mounted on the outer shaft segments. On the other side of the device, there is a system of gears powered by torque derived from the angular transmission from the flywheel to the outer shaft. These gears interact with the shaft on which the main inertial mass of the system oscillates. The central shaft, housing the inertial mass and magnets, has grooves for this purpose, enabling the entire system to be connected into a single, synchronously operating system. This description refers to a single-mass system. However, the system can also consist of two masses, in which case it will operate with a slightly different configuration of structural elements, maintaining twice the power of a single-mass device. In a dual-mass system, a centrally located rotary coupler allows for the conversion of motion from the two outer masses. These masses each have four magnets, for a total of eight permanent magnets. Both the single-mass and dual-mass machines operate completely automatically, using only the magnetic and mechanical energy generated by the repulsion of the permanent magnets. The device can be used for various applications, such as generating electricity or providing mechanical energy for heating homes in winter. The design allows for efficient energy conversion and can be adapted for different power requirements by adjusting the size and number of magnets, as well as the mass of the central component. This innovative approach to energy generation harnesses the principles of magnetism and inertia to create a sustainable and efficient source of power.
