Inertial equilibrium system for propulsion.
It is an attempt to solve the problem of a drive with magnetic interaction between magnets and steel weights. The steel weights are approved on bearings and booms and are attracted by the permanent magnets beneath the plastic casing, which is assumed to take the action of lifting the casing upwards by the magnetic force caused by the centrifugal force due to the rotation of the systems around the axis vertical, and this housing, through a spring on the central shaft, will transfer the dynamic energy to the entire system. For proper operation, the system must be in dynamic equilibrium between the centrifugal and magnetic forces. Three generators arranged on the plan of an equilateral triangle ensure the stiffness of the drive and the balance of the system. The motors used are DC motors with a voltage of at least 12 V. It is a form of a powered drone in which the main characteristic is the lack of conventional propellers.
A continuation of equilibrium system shown on latest video with additional and required improvements of construction. It would be advantageous to add wheels, rollers of ball bearings under the weights that rotate, then they would not hold so much to the housing, especially over strong neodymium magnets. In one of my earlier videos, I was describing similar construction, however there was repulsion as the main interaction between two magnets static and in rotation. These systems will not be working, because there was no freedom between required parts of the system, and it was too stiff. In this solution I think, I solve this problem by leaving the external casing free in upper movement ability what can be realized applying a compressive spring. This casing will be pushing on this spring and this spring will be pushing on entire construction what can be seen exactly on this video. This casing is static only according to rotation and in assumption its mass (mass of neodymium magnets and mass of plastic construction) will be needed for propulsion in vertical axis. It will be pulled up by magnetic forces between those steel weights lying on casing and the neodymium magnets beneath this plastic casing. In fact, those weights will have some distance from the casing because of ball bearings mounted under and slightly in their capacity, along the external circumference of the casing. So, in the right and higher speed of rotation the weights may start to have some distance from the casing only if the spring will be compressed enough to give proper resistance for further compression by the casing.
There is another system I want to build:
This is a proposition of inertial propulsion system with only one mass. I've presented lately this system, but it was not advanced enough to a proper presentation and could not show a crucial idea of operation of this drive. One of the simplest inertia drives consists of an electric motor, a through-shaft hub and the free-position shaft itself and an outer casing. In this video you can see the shaft moving as it is forced to rotate by the motor and corrected by the outer housing. In the closing phase, rotation of the shaft already obtains sufficient energy that it no longer must be controlled by the housing. The question of friction is an open question here, in the form that is presented it is not resolved. How to lubricate this device, whether it will be work on grease or in oil mist, is an open question. Grease or oil may escape under the influence of centrifugal force and lubricate the entire device to prevent ignition. You can also use a dense roller bearing of a special design around the circumference (with needles on the inside) of the device, if the radius of curvature of the shaft tops were appropriate and it could be slightly extended to ensure contact with the needles of the bearing, the whole could work better.
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