Conical weights inertial propulsion

 This inertial propulsion method was shown already on my blog. I am presenting it again because of my conviction of high potential of this propulsion method as a inertial drive system. Once the system is powered by electric motor and deck fuel-less source of electric energy it has potential to deep space exploration depending only from mechanical durability of parts from which the system is made. I didn't make any calculations about this method but the geometry of the device is indicating that the single weight is more massive than in eight-roller propulsion type, additionally having conical shape suitable for generate more thrust from one weight. The weak side of the device is application of ball bearings as power transmission elements on which is paid quite big pressure coming from the centrifugal force multiplied by weight of each mass, so they can be used down very quickly. The solution is application of strong permanent magnets both in external rim and on the tops of each conical mass. The friction will be canceled in such a situation, but the power of the device would be limited to the point where centrifugal force will be greater than magnetic repulsion force. Nevertheless, nowadays neodymium magnets are very strong magnets, so we can admit that the system will be producing sufficient force for lift loads and the crew. You can notice that this system has denser located masses on the bottom than on the top. If the system had the same density in every direction than no difference in centrifugal force distribution will be generated. Thanks the location side by side on the bottom the system can produce low centrifugal force in the vector complying with gravity vector, because the centers of the masses are passing closer from the main center of rotation almost attaching to central shaft from one smaller end aimed to the center. Main shaft is placed on bigger ball bearings and it is placed not centrally with relation to vertical diameter length of the device, slightly closer to the lowest point of the device. The weights/masses are made from two symmetric pieces in which there are made machining works like drilled holes for linear bearings and secondary shafts which are parts of the central rotor. Also drilled wholes for two screws and nuts conjoining in one piece both halves The system of caring the masses is made from eight smooth steel caring rollers.  The system in this shape can be not balanced enough due to it can have an ability to turning around caring steel rollers because they are round, however two applied ball bearings can stabilize each of the masses during the work. Of course there is a possibility to apply two caring rollers in each masses, so system would be stiffer.