GR1010284B - Power generation by conversion of the inertia force into electric energy - Google Patents

Abstract

The invention relates to power generation achieved by conversion of the power of inertia into energy. For this purpose, on a base (fig. 1) we install a shaft (fig. 2) moving into ball bearings (fig. 3.) On the shaft we weld a heavy disk (fig. A). The one end of the shaft is coupled with an electric motor (fig. 6) which rotates said shaft which, in turn, rotates the heavy disk. Then, the shaft is coupled with a reducer (fig. 7) and rotates it. This reducer finally is coupled with a power generator (fig. 8) and rotates it to generate power. So, when we set the motor into operation, all these (shaft, disk, reducer and generator) rotate and the generator generates electricity. When we stop the operation of the electric motor, the disk -due to inertia- will continue to rotate, setting the whole system into operation for power generation, without consuming energy. By means of a specific timer, we actuate the electric motor when the disk is almost immobile and we disactivate it, when the disk revs reach a maximum. So, our unit operates on its own, automatically, and autonomously. The expectation is that the offered energy, together with the capture-exploitation of inertia, will be less than the one we produce. For the best result you will need to experiment with weights and shapes of materials of our unit, depending on its size.

Description

GENERATION OF ELECTRIC CURRENT BY POWER CONVERSION

OF INERTIA INTO ELECTRICAL ENERGY

This invention refers to the way of converting inertia into energy.

When a car is moving and we stop the engine, or press the clutch, without pressing the brake, it continues to move. This force, which moves the car, without us exerting energy on it, is the force of inertia. This phenomenon is observed in any body that is pushed by a force, and it continues to be pushed even when we stop acting on it.

We try to capture this inertial force and turn it into rotary motion to drive a generator. This unit can be built anywhere, requires minimal components, and simpler construction than any other means of power generation.

Diaper) on a base (fig 1) a strong shaft (fig 2) passes through. This shaft passes through bearings with bearings (fig 3) to move freely. On this shaft we attach a heavy disc (fig 4) which has the largest possible radius. so that a greater inertial force is created during its rotation. This disk can be made of iron or other material, e.g. of cement for more economical construction, and its weight can be from several kilograms to several tons, depending on the size of the unit. The more weight the disc has, the more inertia is created. There is a cut=slot in the base for the rotation of the disc ( fig 4 ). The shaft, on the one hand, with the corresponding connection (fig. 5), fits into an electric motor (fig. 6) and rotates it. also rotating the disc. The other side of the shaft fits in the same way in a speed reducer (fig. 7), e.g. if our motor is e.g. 1400 revolutions, we get a reducer that gives the output, for example, 23 revolutions, which revolutions with the corresponding connection (fig. 5) the reducer finally transmits to the electric generator (fig. 8) to rotate it, for the production of electricity. We install the reducer. to multiply the revolutions of the disk in relation to the revolutions that end up in the generator, so that the disk spins more easily and for a longer time without energy. So we have a shaft, which rotating, with the help of an electric motor, rotates the disk, the reducer. and finally the generator, which produces electricity. The power of the motor and the weights and shapes of the materials of the unit, depends on its size, as well as after experimentation. This invention works as follows.

We start the electric motor. The shaft rotates, and the disc rotates with it. The reducer also rotates. the generator, and produces electricity. When the disc reaches the maximum revolutions, with a pre-programmed timer, we stop the operation of the electric motor. The disk due to inertia will continue to rotate, and with it the shaft, which will rotate the reducer. and he, in turn, the generator, for the production of current, without this time offering energy, for the rotation of the shaft, for the production of the current. When the revolutions of the disc reach almost a standstill, with the help of the timer, we reset in operation the electric motor, to continue the sequential continuous repetition. So our unit works by itself automatically The expected result in this invention is the energy I offer. together with the exploitation of inertia, to be less than what we produce

Claims (1)

Production of electrical energy by converting inertia into electrical energy, characterized by a heavy shaft (fig. 2) that rotates inside a ball bearing bearing (fig. 3). The bearings are attached to a base (fig. 1). One end of the shaft is offset. in a special way (fig. 5) in an electric motor (fig. 6) which rotates it. The other end is attached to a heavy disc, (fig 4 ) and then connected to a reducer (fig 7) and the output of the reducer is connected in the same way to an electric generator (fig 8) to rotate it to produce electricity. Production of electrical energy by conversion of inertia into electrical energy characterized according to claim 1 by a heavy disk (fig 4 ) which is attached to the shaft (fig 2 ) so that when the shaft rotates, the disk also rotates The radius of disc, as large as possible, for greater inertia developing in force. This invention is based on the attachment of the heavy disk, on the shaft and the addition of the reducer. Production of electricity by conversion of inertia into electricity, characterized according to claims 1 and 2 that when the electric motor operates, the shaft rotates, the disk also rotates, the reducer rotates, the generator rotates, and electric current is produced. When the electric motor stops working, the disc due to inertia continues to rotate, rotating the shaft, the shaft rotating the reducer, the reducer the generator, and electricity is produced, this time without putting out energy. We thus want to capture the power of inertia, and convert it into electrical energy. In other words, we produce current, without acting with energy. Electricity generation by conversion of inertia into electricity, characterized according to claims 1, 2, 3, by a special timer which activates the motor when the revolutions of the disk reach almost standstill, and deactivates the motor when the revolutions of the disk reach the maximum. Electric current generation by converting inertia into electrical energy characterized according to claims 1, 2, 3, 4, we create parallel identical units, the generated electric current of which results in a common electric load Production of electrical energy by converting inertia into electrical energy, characterized, according to claims 1,2, 3, 4, 5, by adding a speed controller to our electric motor, so that after experimentation, we find the ideal speed with which our motor will operate, for the most efficient performance.