A rotation device includes an output shaft, at least one rotatable rotary plate member arranged so that its rotation axis and the output shaft are coaxial, at least one weight member fixed to the rotary plate member, for biasing position of the center of gravity from the rotation axis of the rotary plate member, and at least one clutch mechanism arranged between the rotary plate member and the output shaft, for separating the rotary plate member and the output shaft with each other at a predetermined rotation angle. The clutch mechanism connects the rotary plate member with the output shaft when the center of gravity of the weight member descends, and separates the rotary plate member from the output shaft when the center of gravity of the weight member rises.

A gear system for achieving an infinitely variable transmission comprising an input shaft for receiving rotational input into the transmission system and output shaft for delivering rotational output from the transmission system, a flywheel component for applying resistive forces of inertia into the transmission wherein the flywheel stores and stabilizes rotational energy in the transmission system, a high gear reduction mechanism achieved by assembly of one or more epicyclic gears wherein the flywheel accelerates with increasing difference of angular velocity between the input shaft and the output shaft, wherein the high gear reduction mechanism is based on the equation. (a)Z=(n+a)R(n)X, where Z is angular velocity of flywheel, X is angular velocity of input shaft and R is angular velocity of output shaft, n & a are integer constants where a<<n or a<n. The gear ratios vary from 0 to 1, wherein another gear can be meshed with the output shaft to achieve overdrive gear ratios.

A planetary gear type throwing wheel device contains: a central shaft rotatably locked on two rotatable discs, and a transmission gear locked on the central shaft. Each rotatable disc includes three supports and three columns rotatably connect with three throwing force gears. The transmission gear drives the three throwing force gears to rotate. Each throwing force gear includes a defining portion, and multiple counterweight elements are disposed on the defining portion. A generator rotation wheel is fixed on a top rotatable disc, an actuation shaft is connected with the central shaft, and the actuation shaft has a driving wheel, such that the driving wheel drives the transmission gear to rotate the three throwing force gears simultaneously so that the six counterweight elements produce a throwing force, and a large torque is generated from the central shaft to rotate the generator rotation wheel.

The invention refers to a device for increasing the efficiency of any rotary power generating system with progressive variation, whose planetary system may have two or more pairs of pinions, or/and satellites with any multiplication/demultiplication ratio with respect to the central pinion, characterized in that it consists of an assembled inner box, A, which is assembled axially in an assembled outer box, B, to which an assembled side box is axially fixed, C; assembled inner box, A, made of a primary drive shaft, (1), having a flange, by means of which the shaft is oriented and fixed on a cover, (2), in which, axially, is assembled a bearing, (3), and radially, in some bosses, a, processed cylindrically, are fixedly assembled some bearings, (4), in which, with a shoulder, conventionally right, son satellites, (15), are assembled, each of which, on a median shoulder, has assembled a bearing, (4); axially, in the bearing, (3), is assembled an intermediate pinion, (6), which, to the left of its toothed crown, has assembled a second bearing, (18); in some bearings, (19), (FIG. 4) which are fixed in the cover, (2), are assembled some pinions, (14), which mesh both with the pinions, (15), and with the toothed crown of the intermediate pinion, (6); on the cover, (2), and oriented on the bearings, (4), (18) and (19), is centered an intermediate cover, (5), which is firmly fixed to the cover, (2), by some screws, (13); on the cover, (5), being oriented and fixed a cylindrical wall, (20); on the conventional left side of each pinion, (15), one eccentric, (16), is fixed rigidly (FIG. 1, FIG. 4, FIG. 5, FIG. 6); after each eccentric, (16), on each pinion, (15), a bearing, (4), is assembled; on each bearing, (4), it is oriented, and on the cylindrical wall, (20), is oriented and fixed another cover, (21), in the center of which is assembled a bearing, (22), through which the intermediate pinion, (6), slides; assembled box, B, consisting of a cover, (23), oriented by means of a bearing, (24), on the primary motor shaft, (1), from the assembled inner box, A, cover, (23), on which it is oriented and fixed by means of screws, (25), with the conventionally right surface, an external cylindrical wall, (26), from which, on its conventionally left surface, a cover, (27), is oriented and fixed, by means of screws, (28); cover, (27), which is oriented by