LT5400B - A gravitation engine - Google Patents

Abstract

The invention relates to gravitation apparatus and can be used for a drive of mobile and stationary machines as assembly of power transforming rotation energy to electrical energy. The gravitation engine comprises a rotary truncated cone, which is not controlled in respect of vertically and a load to maintain rotary moving is directed by a load mechanism to a satellite carriage, which distributes a load to an oblique circular disc and to a rotary truncated cone, which is fixed tightly in an axis. A circular disc is tightly fixed in a rotation axis of a truncated cone in respect of rotation of truncated cone and a rotation axis of it. An engine is controlled by a load mechanism.

Description

The invention relates to gravitational devices and can be used as a power unit in the drives of stationary and mobile machines - gravitomobiles and in the conversion of rotational energy into electrical energy.

The closest known technical solution is the patent no. 5188 - Gravity Engine. The vertical load of the uncontrolled rotation of the rotating disk - individual bodies secured by belts in the axis of rotation of the satellite wheels mounted directly or by rigid free-joints on the disk or its axis of rotation and additional load does not use constant and maximum gravitational or simulation forces.

SUMMARY OF THE INVENTION The object of the present invention is to provide an engine which constantly and maximally utilizes the action of charge gravitational forces or simulated forces.

The essence of the invention is that, in a known engine based on the action of gravitational or simulated forces, operating in long-term unbalance mode and having a rotating disc output in it, a transmission gear, a common axis of rotation of the disc and a transmission gear mounted in a support, a loading mechanism to support the rotational motion of the disk, this load is fixed in the satellite trolley, and the rotary disk is a rotary cone cut parallel to its horizontal underside, the base.

The pivoting cone having its external lateral surface forming angles of 45 ° respectively with the plane of the horizontal base of the punctured cone is rigidly mounted on its vertical hollow cylindrical pivot, mounted on a support such that the pivot axis of the pivoting cone rotates freely in the pivot. along its axis. The pivoting cone's pivot axis, below the support, is rigidly mounted with the required transmission gear (pulleys, sprockets, friction wheels, etc.) so that it does not touch the support. The hollow axis of rotation of the rotary cut cone has a rigid outer outer cylinder rigidly mounted at its upper end such that its center, in relation to its length and its outer and inner diameters, extends upwards, in its center and its ends in the respective vertical planes. .

The horizontal outer cylinder is provided with a horizontal inner cylinder of the same length having an outer diameter equal to the inner diameter of the outer cylinder so that it rotates freely in the outer cylinder and cannot move along it.

The inner cylinder, on its inner lateral surface and in the middle of its length, has a rigidly horizontal end rigidly parallel to the vertical planes perpendicular to the inner cylinder side surface and having a length equal to the inner diameter of the inner cylinder.

The center axis of the horizontal axis is provided with a rigid lever so that it rotates freely on that axis, cannot move along it, forms a right angle with it, cannot rotate and bend that angle, and is rigidly fixed at its ends by a sloping ring disc. on an inner circular surface the diameter of which is equal to the length of the lever. The radius of the outer circumferential surface of the inclined ring is equal to the distance from the center of the horizontal axis, in length and thickness, coinciding with the center of rotation of the rotating truncated cone in its extension upwards and at the intersection of the constituent outer surface of the truncated cone of the outer circumferential surface.

The underside of the oblique annular disk is in a portion of its plane in contact with the frictional drive cone outer sidewall forming member which is in one vertical plane with the lever along its entire length, i.e. the plane of the inclined annular disc forms an angle of 45 ° with the horizontal plane of the rotating base of the tapered cone (the vertical distance from the center of said horizontal axis in length and thickness to the center of the radius of the incised conical base) half-plane, is frictionally coupled to the outer lateral surface of the cut cone, its corresponding forming so that the inner circumferential surface of the inclined ring disc does not touch the axis of rotation of the cut cone intersecting upward in its center and at the intersection of the intersecting points, the horizontal axis at its center, the lever at its center, the outer and inner horizontal cylinders at the common center of its lengths and diameters, the plane containing the underside of the bevelled annular disk, and, at the (point of) the axis of rotation of the annular disk which is rigidly connected to the axis of rotation of the cone, with respect to their rotation, through a horizontal axis which changes its position with respect to horizontal, internal and external cylinders of and the lengths are such that the lever does not touch those cylinders.

The axis of rotation of the rotary cut cone, below the base of the cone, is fitted with a rigid, free-flange joint at one end so that it rotates freely on that axis, cannot move along it and does not touch its support. In the horizontal part of the joint there is a hole drilled in the shape of an arc of a diameter of a hole but of an indefinite length whose radius of intersection is the axis of rotation of the cut cone, through which the hole made in the joint is made. size bolt-lock, the joint is rigidly secured to the base of the cut cone, ie in the required radius of that base, depending on the shape of the joint. At the other end of the rigid free-flowing connector at the other end of the lower left-hand quadrant of the rotating cone base is a rigid rectangular tube in its cross section, with its sidewalls in the respective vertical planes parallel to the vertical plane, having the axis of rotation of the rotary cut cone and the upper radius of the base of the cone, the lower guide wall forming an angle of 45 ° with the horizontal plane and the plane of rotation of the conical base of the cone and its continuation respectively the lower half, the plane and its extension at an angle of 90 °. The upper upright corners of the side walls of the rectangular tube are intentionally cut without touching the lower guide wall.

The rectangular tube contains a rectangular bar, a satellite cart having a length equal to the length of the rectangular tube and a width and height corresponding to the internal distance between the sides of the rectangle and its upper and lower guide walls so that it slides freely within the rectangle. The rectangular bar placed in a sloping rectangular tube, near its lower end and upper tube wall, has a drilled lower, perpendicular to the side walls of the rectangular tube, a horizontal hole, and a correspondingly shaped outlet having a spaciously mounted satellite wheel support in the lower horizontal hole of the rectangular bar - trolley of the same diameter so that the support wheel rotates freely on its axis of rotation, cannot move along it and does not touch the rectangular bar on its sides nor the rectangular tube on its circumferential surface; a drilled top, perpendicular to the side walls of the rectangular tube, a horizontal hole whose center, in relation to its diameter, is a vertical straight line passing through the upper corner of the rectangular bar and the point of intersection of the line passing through the lower horizontal hole of the rectangular bar - satellite trolley with respect to its diameter and parallel to the lower guide wall of the rectangular tube and its sidewalls.

The satellite support wheel of the satellite trolley is resting on a rigid, lightweight, L-shaped plate rotated 90 ° to the right, rigidly inclined in a circular disk, its lower part on its upper side such that the respective planes containing this plate and the inclined annular disk being parallel to each other and the longitudinal portion of the plate running horizontally and perpendicular to the vertical plane containing the formation of the outer lateral surface of the cut cone which is touched by the frictionally driven inclined annular disk in its lower half plane. The seat of the satellite wheelchair support wheel, rotated to the right in the "L" shaped plate, is the lower part of the shorter plate above the bottom left-hand quadrant of the sloping annular disk, and the direction of the support is perpendicular to each other annular disk and plate and parallel to the lower guide wall of the rectangular tube and its side walls.

The hollow axis of rotation of the rotary cut cone is provided with a cylindrical core having a diameter equal to the inside diameter of the axis of rotation of the hollow cylindrical cut cone, so that its lower part terminating in the upper and lower horizontal discs rigidly secured therethrough an axis of rotation in which the core is free to slide along and rotate therein. The axis of rotation of the cut cone, in its part below the cone, has a vertical oblong, uniform width over its length, an outlet containing a rigid, free-target load connection which is rigidly fixed at one end to the core and at the other end to the horizontal axis. , is fixed in the upper horizontal hole of the rectangular bar - satellite trolley of the diameter of that axis so that the rigid loading joint does not touch the sloping annular disk, the truncated cone, its axis of rotation and the horizontal axis of this joint .

The support located below the core discs and to the left of the axis of rotation of the cut cone has a rigid, vertical transverse section, a stand (integral part of the loading mechanism) such that its two opposite sides are parallel to a vertical plane containing the upper radius of the cut cone base. , and the center of the square of the cross-section of the rack at any height of that rack is in a corresponding horizontal line passing through the center of rotation of the truncated cone and perpendicular to the vertical plane containing the top radius of the truncated cone base.

The square pillar is provided with a hollow square, its inner and outer shape in cross-section, its internal cross-sectional parameters being equal to the square pillar's cross-section, the inner side of which is parallel to its respective outer sides and its corresponding lateral sides. can freely slide up and down the square rack but cannot rotate about it. On the outside of the coupling, closer to the axis of rotation of the cut cone, a rigid horizontal axis is fixed at one end so that it rotates freely in the coupling, cannot slip across it and is in a vertical plane passing through the center of the square the other end of the axis terminating in a horizontal, symmetrical extension of that axis with respect to the axis of rotation of the cone, a semicircle having a point of intersection in the extension of that axis and a mandrel shaped at its center coinciding with the center of the axis of rotation the corresponding horizontal axes are mounted such that they are in extension to one another, outside the fork and in a vertical plane containing the upper radius of the tapered base of the cone. The corresponding forks of the same cross-section of diamond-shaped cross-sections are mounted on the fork shafts so that they rotate freely on their respective individual shafts, cannot slip along an equal distance from the non-contacting core and do not touch the core when rolling. upper floppy, its lower half.

On the side of the coupling, behind the stand and on the upper radius of the cone base, there is a rigidly mounted vertical pinion which is connected to a pinion rigidly mounted on its horizontal axis of rotation so that this axis cannot move in the support and is perpendicular to the vertical plane containing the upper radius of the tapered base of the cone with the teeth of the same module.

On the left-hand side of the pivoting axis of the pivoting wheel and further away from the core, the short-ended f-handle is rigidly mounted to start, adjust and stop the engine so that it is all horizontal and its longer portion is perpendicular to that pinion. an axis of rotation parallel to a vertical plane having a radius of the cone base and fixed in a corresponding position relative to its horizontal position by a latch on the annular support and freely slidable on the longer portion of the handle thanks to a handle loop behind the pinion axis of rotation and the load fixed therein (in the longer part of the handle) such that the center of gravity of that load is in the axis of rotation of the pinion, even when the plane of rotation of the cut cone is vertical, etc.

The equilibrium of the rotating cut cone (offset by the centrifugal, symmetrical axial rotational forces of the engine components) is offset by the balancer.

The invention will now be further described with reference to one embodiment of the drawings.

Figure 3 is a diagram showing a cross-section of the motor in a vertical plane parallel to the axis of rotation of the cut cone.

Figure 3 is a diagram showing a cross-section of the engine in a horizontal plane perpendicular to the axis of rotation of the cut cone.

Figure 1 is a diagram showing a counter-clockwise rotation of 90 °; in plan view, the transverse section of the engine in a vertical plane parallel to the axis of rotation of the cut cone.

Fig. 2 is a diagram showing a counter-clockwise rotation of 90 °; in plan view, the transverse section of the engine in a horizontal plane perpendicular to the axis of rotation of the cut cone.

Figures 5 to 10 are diagrams showing transverse sections of engine modifications in vertical planes parallel to the axis of rotation of the cone.

The gravitational motor (the configuration of its components is described on the basis of Fig. 3) consists of a rotary cut cone (1) whose outer side surface members (2) form 45 ° angles respectively with the plane of the horizontal base (3) of the cut cone (1). on its vertical hollow cylindrical pivot axis (4) mounted in the support (5) such that the axis of rotation (4) of the cut cone (1) rotates freely in the support (5) and cannot move along its axis.

On the pivoting cone (1) of the rotating cut cone (1), below the support (5), the required power transmission gear (6) (pulleys, sprockets, friction wheels, etc.) is rigidly mounted so that it does not touch the support (5). .

On the hollow axis of rotation (1) of the rotary cut cone (1), a horizontal outer cylinder (7) is rigidly mounted at its upper end such that its center (8) is in relation to its length and its outer and inner diameters. in the extension of the axis of rotation (4) upwards, in its center, the ends being in the respective vertical planes. The horizontal outer cylinder (7) is provided with a horizontal inner cylinder (9) of the same length having an outer diameter equal to the inner diameter of the outer cylinder (7) such that it rotates freely in the outer cylinder (7) and cannot move along it. The inner cylinder (9,) on its inner lateral surface and in the middle of its length has a rigid end-mounted rigid horizontal axis (10) which is parallel to vertical planes perpendicular to the lateral surface (11) of the inner cylinder (9). for the inner diameter of the inner cylinder (9).

On the center (12) of the horizontal axis (10), a rigid lever (14) is mounted with its middle part (13) so that it rotates freely on that axis (10), cannot slip along it, forms a right angle to it, and curved, and at its ends it is rigidly secured to the inner circumferential surface (16) of the inclined annular disk (15) having a diameter equal to the length of the lever (14). The radius of the oblique annular disc (15), the outer circumferential surface (17) is equal to the distance from the center (12) of the horizontal axis (10), its length and thickness coinciding with the center (18) of the rotation axis (4) ) in its extension upwards and at the point of intersection (19) of the outer lateral surface of the cut cone (1) to the outer circumferential surface (20) of the base (3) of the cut cone (1).

The underside (21) of the inclined annular disk (15) extends in a part of its plane into the forming side (2) of the outer lateral surface of the friction-driven cone (1), which is in one vertical plane with the lever (14). the plane of the inclined annular disk (15) forms an angle of 45 ° with the horizontal plane of the base (3) of the rotating cut cone (1) (vertical distance from the center (12) of said horizontal axis (10) in length and thickness to the cut cone 1) the center of the base (3) is equal to the length of the radius of the base (3) of the cut cone (1) and this annular disk (15) is frictionally connected to the outside of the cut cone (1) lateral surface, its respective forming (2) such that the inner circumferential surface (16) of the inclined annular disk (15) does not touch the axis of rotation (4) of the cut cone (1), which is intersected upward in its center (18). and at the intersection (19) of the outer lateral surface of the cut cone (1), the horizontal axis (10) with its center (12), the lever (14) with its center (13), the outer (7) and the inner ( 9) Horizontal cylinders in their long with a common center (8) of diameters and diameters, the plane comprising the underside (21) of the bevelled annular disk (15), which is parallel to its upper half (22), and (at point (19)) the inclined annular disk (15). a pivot axis (23) which is rigidly connected to the pivot axis (4) of the cone (1) with respect to their rotation (1), (4) via a horizontal axis (10) which changes its position when the engine is running with respect to the inner (9) and outer (7) cylinders having diameters and lengths such that the lever (14) does not touch those cylinders (7), (9).

The pivoting cone (1) of rotation is rotatable on the axis of rotation (4), below the base (3) of the cone (1) and has a rigid, free-flanged joint (24) at one end so that it rotates freely on that axis (4). move along it and not touch its support (5). In the horizontal part (25) of the connector (24), a hole (26) is drilled, at which, at the base (3) of the cut cone (1), an arc of diameter (25) but of indefinite length is formed the pivot axis (4) of the cone (1) being removably shaped (27) through which said hole (26) made in the joint (24) is bolted (28) to the diameter of said hole (26), the joint (24) being rigidly fixed in the base (3) of the cut cone (1) at the required location, ie in the required radius of the base (3), depending on the shape of the connector (24). At the other end of the rigid, free-flanged connector (24) above the left lower quarter (29) of the rotating truncated cone (1) base (3) to the left and down is a rigid rectangular tube (30) in its cross-section. ) such that its sidewalls (31) are in respective vertical planes parallel to the vertical plane having the axis of rotation (4) of the rotating cut cone (1) and the upper radius (32) of the cone (1) and the lower guide the wall (33) has an angle of 45 ° with the horizontal plane and the plane of the base (3) of the rotating cut cone (1) and its extension, respectively, and the sloping annular disk (15) with its upper side (22) parallel to its lower half (21), the plane and its extension 90 °. The uppermost upper angles (34) of the side walls (31) of the rectangular tube (30) are purposefully cut out without touching the lower guide wall (33).

The rectangular tube (30) contains a rectangular satellite satellite carriage (35) having a length equal to the length of the rectangular tube (30) and a width and height corresponding respectively to the inner distance between the side walls (31) of the rectangular tube (30) and its top. (36) and the lower guide (33) walls so that it slides freely in the rectangular tube (30) and cannot rotate therein. The rectangular bar (35), which is inclined in a rectangular tube (30), has a lower, perpendicular to the lateral walls (31) of the rectangular tube (30) drilled near its lower end (37) and the upper wall (36) of the tube (30). 38) and an exit (39) of appropriate shape and size having a substantially accommodated support wheel (40) of a satellite cart (35) having a pivot axis (41) rigidly mounted in a lower horizontal hole of a rectangular bar (35) of the same diameter. (38) so that the support wheel (40) rotates freely on its axis of rotation (41), cannot move along it and does not touch the rectangular bar (35) with its sides on its circumferential surface, nor on the rectangular tube (30), and the rectangular bar (35) has a notched upper, perpendicular to the side walls of the rectangular tube (30) near its upper end (42) (31), a horizontal hole (43) having a center (44) having a vertical line passing through the upper corner (45) of a rectangular bar (35) and a line passing through a rectangular bar (35) the lower horizontal hole (38) with respect to its diameter, the center (46), and parallel to the lower guide of the rectangular tube (30)! the intersection of the wall (33) and its side walls (31).

The satellite support wheel (40) of the satellite trolley (35) is resting on a rigid, lightweight, L-shaped plate (47), rotated 90 ° to the right, rigidly mounted on the lower annular disk (15) on its upper part (48). the sides (22) such that the respective planes containing this plate (47) and the inclined annular disk (15) are parallel to each other and the longitudinal portion (49) of the plate (47) is horizontal and perpendicular to the vertical plane when the engine is running is the forming part (2) of the outer side surface of the cut cone (1), which is in contact with the plane of its lower side (21), which is in contact with the frictionally driven inclined annular disk (15). The seat of the support wheel (40) of the satellite trolley (35), rotated to the right in the "L" shaped plate (47), is located on the shorter portion (50) of this plate (47) above the lower left quarter quarter (51). to the left and down, the lower part (52), and the direction of the support is perpendicular to the mutually parallel planes, their extensions having respectively a sloping annular disk (15) and a plate (47) and parallel to the lower guide wall of the rectangular tube (30) 33) and its sidewalls (31).

In the hollow pivot axis (4) of the rotating cut cone (1) is provided a roller core (53) having a diameter equal to the inner diameter of the pivot axis (4) of the hollow cylindrical cut cone (1) so that its lower part (54) The core (53) protrudes from the axis of rotation (4) of the hollow cone (1), in which the core (53) can slide freely along and rotate therein.

The axis of rotation (4) of the cut cone (1), in its part below the cone (1), has a vertical elongate of uniform width over its length, a recess (57), which contains a rigid, free-target loading coupling (58) one end being rigidly secured to the core (53) and the other end terminating in a horizontal horizontal hole (43) of a rectangular bar - satellite carrier (35) having a diameter of that axis (59) such that the rigid loading connection (58) does not touch the sloping annular disk (15), the tapered cone (1), its axis of rotation (4), and the horizontal axis (59) of this connector (58) cannot move across the satellite rod carriage (35) of the rectangle and the rectangular tube ( 30).

The support (59a) located below the core (53) on the flaps (55), (56) and on the left side of the pivot axis (4) of the cut cone (1) has a rigidly mounted vertical, square cross section, stand (60) (Part 60)) such that its two opposite sides are parallel to a vertical plane having the upper radius (32) of the cut cone (1) base (3) and the center of the cross-section square of the stand (60) at any height of that stand. (61) is in a respective horizontal line passing through the axis of rotation (4) of the cut cone (1), its center (18) and perpendicular to the vertical plane containing the upper radius (32) of the base (3) of the cut cone (1).

The hollow square (60) has a hollow square, its inner and outer shape in cross-section, the inner cross-section of which is the same as the square cross-member (60), the inner side of which is parallel to its respective outer sides. and the respective sides of the rack (60) such that it can slide freely up and down along the square rack (60). On the outer side (63) of the sleeve (62) closer to the axis of rotation (4) of the cut cone (1), a rigid horizontal axis (64) is mounted at one end so that it rotates freely in the sleeve (62). in a vertical plane passing through the center of the square (61) of the cross section of the rack (60) and the axis of rotation (4) of the cut cone (1), its center (18) and the other end of the axis (64) extending toward the cone (1) with respect to the axis of rotation (4), a semicircle having a point of intersection with the extension of that axis (64) and a center (65) of the core (53) with respect to its diameter coinciding with the axis of rotation 4) a center (18) in the form of a fork (66) having its respective horizontal axes (67) rigidly fixed at its ends so as to extend into each other, outside the fork (66) and in a vertical plane having the base of the cut cone (1) (3) upper beam (32). Corresponding diamond wheels (68) of equal diameter are mounted on the forks (67) of the fork (66) so that they rotate freely on their respective individual axes (67), cannot move along them, and are equally spaced from the core (53). which do not touch the fork (66) and, while rolling with the upper side (69) of the lower disk (56) of the core (53), do not touch the upper disk (55) of the core (53) and its lower side (70).

On the side of the sleeve (62), behind the rack (60) and the upper radius (32) of the base (3) of the cone (1), there is a rigidly mounted vertical pinion (71) whose rivets (72) are connected to the pinion (72). 73), rigidly mounted on its horizontal pivot axis (74), rotating freely in the support (75) such that said axis (74) cannot move in the support (75) and is perpendicular to the vertical plane containing the base (3) of the cut cone (1). ) upper radius (32), with the gear (76) of the same module.

On the end of the pivot wheel (73) on the pivot axis (74) on the left side of the rack (60) and further away from the pivot (53), there is a rigid "f" -shaped handle - engine starting, adjusting and stopping device (77). that the whole (handle) is in a horizontal plane, its longitudinal portion (78) being perpendicular to the axis of rotation (74) of that pinion (73) parallel to the vertical plane containing the upper radius (32) of the base (3) of the cone (1). and is locked in its respective position with respect to its horizontal position by the latch (79) in the annular support (80) and on the elongate portion (78) of the handle (77), thanks to the loop (81) of the handle (77) the load (83) of the load (83) is located in the axis of rotation (74) of the pinion (73), even at the cut cone (1) s vertical plane of rotation.

The equilibrium of the rotating cut cone (1) (centered forces of the components of the motor, symmetrical with respect to the axis of rotation (4) of the cone (1)) is balanced by the balance (84).

Design of gravity motor for operation (at least once):

With the inclined ring disc (15) in its initial position, i.e. when its lever (14) is in one vertical plane with the forming side (2) of the outer side surface of the rotating cut cone (1), which is in contact with the slanting ring disc (15) with its friction drive part of its lower side (21); is temporarily locked in its non-rotatable axis of rotation (4), the inclined annular disk (15), at any point in its lower left quadrant (51), is pressed by a hand muscle or other force perpendicular to the plane of the inclined annular disk (15) , until the slanting ring disc (15) is flush with the outer lateral surface of the cut cone (1) to the right, clockwise with respect to the base (3) of the cut cone (1), the position of the plane of the slanting ring (15) (3) With respect to the upper radius (32), the surfaces of the friction drive do not slip relative to one another. In particular, with the inclined annular disk (15) in this position, the lower part (48) of its upper half (22) is rigidly fixed to the right by a "L" shaped plate (47) so that its longer part (22) 49) (as a unit, not its plane) is a horizontal connector (24) having a rectangular tube (30) at its end with a support wheel (40) of the satellite trolley (35) already supported in the desired portion (50) of the plate (47). ), is fixed in place by a screw-retainer (28) on the base (3) of the rotating cut cone (1) in its respective radius. The horizontal axis (59) of the load connection (58) is respectively fixed in the satellite trolley (35) with its upper horizontal hole (43) and the other end of that connection (58) rigidly in the core 53 if the cut cone (1) is removed (57). the axis of rotation (4) does not have sufficient width or the seat of the satellite wheel (35) wheel (40) on the plate (47) or the inclined ring disc (15) does not satisfy, the latter two structural steps may be performed before the joint (24) is locked by the latch (28) in the base (3) of the cone (1). The temporary fixation of the rotating cut cone (1), which prevents the cone from rotating about its axis of rotation (4), is removed, and its equilibrium is compensated by the balancer (84).

The gravitational motor operates on the following principle:

Moving the load (83) away from the longitudinal portion (78) of the handle (77) away from the pivot axis (74) of the pinion wheel (73) and the loop (81) of the handle (77) and locking the load (83) into the longitudinal portion ), the load (83) is driven by gravitational forces, rotates the pinion wheel (73) as seen from its core (53) anticlockwise and pushes the coupling through its pinions (76) and pinions of the pinion (71) (62) and, through its horizontal axis (64), fork (66) axes (67), rotating diamond wheels (68), lower disk (56) of the core (53), core (53), load coupling ( 58), its horizontal axis (59) fixed in the upper horizontal hole (43) of the satellite rod - satellite trolley (35), vertically downwards, resulting in the satellite trolley (35) through its lower horizontal hole (38). ) a horizontal axis of rotation of the support wheel (40) presses the rotated L-shaped plate (47) to the right (41) and through the support wheel (40), and through it the inclined annular disk (15), inclined at an angle of 45 ° to the right and down about 0.7 charge (83) (incl. bogie (35), load connection (58), core (53), coupling (62) and the like. gravity gravitational force and rotates the axis of rotation (4) of the rotating cut cone (1) through the slanting ring disc (15), the lever (14), its axis (10), the inner (9) and outer (7) cylinders, ( with the actual length of the rotating shoulder equal to the radius of the base (3) of the cut cone (1), with the support wheel (40) in the plate (47) spaced from the center (18) of the cut cone (1) clockwise), and through the friction drive of the inclined ring disc (15) (thanks to the corresponding friction surfaces of the shorter portion (50) of the plate (47), increased friction is increased by the increased pressing of the inclined ring disc (15) 1) outer side surface) with the outer side surface of the cut cone (1) and its respective forming (2) rotates the axis of rotation (4) of the cut cone (1) through the cut cone (1) with the same force at the same rotation pe anticlockwise longitudinally, but the satellite trolley (35) presses the lower guide wall (33) of the rectangular tube (30) at a 45 ° angle with respect to the vertical and in the direction of the horizontal axis (59) of the load connector (58). left and down also about 0.7 charge (83) (including satellite trolley (35), load connection (58), core (53), coupling (62) and so on). gravity and rotates the axis of rotation (4) of the cut cone (1) through the rectangular tube (30), its connection (24), its bolt-lock (28) and through the cut cone (1) (calculated from its base ( 3) ie at the same horizontal rotating shoulder length equal to the radius length of the cut cone (1) base (3) in the above conditions, about 1.0 load (83) gravitational weight force, counterclockwise. The engine stops in reverse.

Engine modifications are possible where the load (83) is rigidly mounted directly on the shaft (59) of the load connection (58), eliminating the load connection (58) itself, the core (53), the coupling (62) and so on. or when the load (83) is attached to the shaft (59) by a belt (85). The gravitational force of the load (83) then changes its rotational acceleration to the centrifugal force of its rotation, and as the ratio of the gravitational force of the load (83) to its centrifugal force decreases, the rotational acceleration of the cone (1) decreases. and the increase is repeated periodically. The centrifugal force of the load (83) can in this case be counteracted by attaching it to the pivot axis (4) of the cone (1) by means of a flexible or rigid connection (86) of appropriate length such that the belt (85) is vertical.

However, the centrifugal force of the load (83) can be used to rotate the cut cone (1) about its axis of rotation, with a rigid joint (24) having a rigid free-form joint (87) at one end and a horizontal axis terminating at the other end. (88) on which the pulley (89) rotates freely so that the pulley (89) cannot move along the axis (88), the horizontal axis (88) being perpendicular to the vertical plane having the corresponding radius of the base (3) of the cut cone (1), the axis (59), the center of gravity of the load (83), a circular vertical belt (85) in its cross-section and a pulley (89) touching it, the belt (85) being between the pivot axis (4) of the pulley (89) and and the load (83) is below the pulley (89).

In addition, the friction drive surfaces of the engine components may include increased friction or special micro-cogging and may be further pressed against one another by a normal press wheel (90) rotating freely on the outer side surface of the parallel cut cone (1) for contacting the friction. actuating a portion of the plane of the underside (21) of the inclined annular disc (15), the axes (91) being in one vertical plane with said cone (1) forming (2), its axis of rotation (4) and rigidly mounted on one end 92), the other end of which is rigidly fixed in a joint (24) in which a rectangular tube (30) is mounted, and the load (83) can be simulated by a tensioned vertical spring (93) which can be mounted at one end in said shaft (59) or handle. (77), in its longer portion (78), and the other, respectively, may be secured in the joint (24), where It has a tube (30) mounted on it or in a row support and whose tension, compression, including replacements for that spring (93), can be adjusted automatically, even at a distance.

The equilibrium of the rotating cut cone (1) (offset by the centrifugal, symmetrical forces of the components of the cone (1) with respect to the axis of rotation (4)) may be modified in the engine modifications not only by the balance (84), but weight) in the axis of rotation (4) of the cone (1) cut by the device described, rotated 180 ° about the axis of rotation (4) of the cone (1) counterclockwise or clockwise with respect to the device described: instead of one inclined ring disc (15) (14) connecting it to the horizontal axis (10) of the inner cylinder (9) can be provided with two portions (94), (95) of an inclined annular ring (15) which is symmetrical with respect to its axis of rotation (12) respectively connected to the shaft (10) of the inner cylinder (9) by a replacement of the lever (14), the hinge (98) of the two respective lever parts (96), (97) such that the planes containing those ring disc parts (94), (95) ), are alone a perpendicular to one another when the same cone (1) and common handle (77) are used, or parallel when a mirror-cut cone (99) is used and other similar components of the mirror motor (100) when the plane of the mirror (101) is horizontal; it comprises a pivot point (14), a horizontal axis (10) of the hinge (98), a pivot axis (23) of the inclined ring disc (15) and a common point of intersection of the respective outer side surfaces (2) of the cut cones (1). 19). The sloping ring disc (15) and the tapered cone (1) can be further loaded with another load (102) attached to one end of the belt (103) fixed to the hook (104) at the other end to a rigidly fixed disc (15) in the lower (21). ) or on an analogous side (50) of the plate (47) (after engine preparation for operation, which involves a different distance between the friction surfaces of the inclined annular disc (15) and the rotary axis of the cut cone (1) (4) , with respect to their "anchorage" locations on that axis (4) and purposeful use of different circular lengths) such that a pulley (105) having a horizontal pivot axis (106) is rigidly coupled (107) to a joint (24) a rectangular tube (30), the plane being parallel to the side walls (31) of that tube (30), the belt (103) connecting the pulley (105) from its right side to its eighth upward (bow (108) possible rigidly mounted), the upper leg (109) is parallel to the lower wall (33) of the tube (30) and its side walls (31), and a pulley (110) may be used to utilize the centrifugal force of this charge (102) to rotate the cone (1). ) respectively fixed in a rigid joint (24) analogous to the pulley (89) but, under new conditions, the second hook (104) may also be mounted on the upper portion (22) of the sloping annular ring (15), ) and similarly, the other pulleys (105) and (110) are further fastened to the respective engine components so that the second belt (103) with one end attached to the second hook (104) and the other end is attached to the second load (). 102), connects the second pulley (110) with a semicircle (111) at its top, and the second pulley (105) at its left side, one-eighth down (can only be used with the anchors hinges (108), (111)) such that the lower branch (112) of the second belt (103) is parallel to the upper branch (109) of the first belt (103). However, it is possible to modify the engine by properly assembling some parts of the engine, dropping some parts or reusing some of them, leaving the number of engine components undetermined. Therefore, in the design of the motor, after cutting off the "L" letter plate (47) and the outer cylinder (7), the cone (1) is cut upward in the vertical hollow axis of rotation (4), i.e. the upper vertical hollow axis of rotation (4) mounted in the upper support (5) such that the upper axis of rotation (4) rotates freely in the upper support (5) and cannot shift in the vertical direction, the lower part of this upper axis of rotation (4) a cylinder (9) such that its lateral surface components (11) are parallel to a horizontal plane, its rigid axis (10) whose ends rotate freely in the inner cylinder (9) and whose center coincides with the center (8) of the cylinder and the cone (1) ) in the extension of the upper axis of rotation (4) down the center (18), is horizontal and cannot move horizontally. The lever (14) of the inclined ring disc (15) rotates freely in its middle part on the rigid axis (10) of the inner cylinder (9), perpendicular thereto and the outer cylinder (7) having an outer diameter is not equal to the outer diameter of the inclined annular disk (15) having an angle of 45 ° with its horizontal plane and having an indeterminate length equal to the radius of the corresponding outer circumferential surface (17) of the disk (15) (15) of the outer diameter) and the sum of the diagonal lengths of the right triangle whose static (indeterminate lengths) are equal to this radius, are rigidly fixed at one end to the disc (15), its lower half (21) such that 15) the axis of rotation (23) and the axis of rotation of the outer cylinder (7) coincide with the outer circumferential surface of the other end, at the junction of the circumferential surface and the end, the outer cylinder (7) is frictionally coupled to a cut cone (1) which is rigidly anchored in its lower pivot axis (4) downstream of the upper pivot axis (4) and which is rigidly secured in its lower in the abutment (5) of that axis, the outer circumferential (or top of the cone) surface at which the diameter of the cone (I) is equal to the diameter of the annular disk (15) and outer cylinder (7), ie the outer cylinder (7) ) once their respective outer circular surfaces do not slip relative to one another, the outer cylinder (7), the sloping annular disk (15) rotate about their common axis of rotation (23) once by rotating the upper axis of rotation (4) through the lever (14) (10) and inner cylinder (9) twice. On the upper pivot axis (4) of the cone (1) above the inner cylinder (9) and the disc (15) and a free-form rigid joint (24) which is fixed at one end to the upper pivot axis (4) so that it rotates freely about that the shaft (4), not touching the disk (15), and having at its other end a rectangular tube (30) with a satellite rod wheel (35), respectively, which is undetectable in shape, including its cross-sectional shape , the corresponding lower guide and upper walls (33) of the rectangular tube (30), corresponding to one-eighth of the corresponding circumference, may be arcs (108) corresponding to such a circular tube as an analogue of such a circular rod-carriage (35) the bow (108)), the lower pulley (110) is fixed so that it rotates freely about the upper axis of rotation of the cone (1), cannot move vertically and which an arcuate outlet (27) at a vertical hole (26) in the joint (24) for securing the joint (24) with a bolt-latch (28) in this pulley. In the upper pivot axis (4) of the cone (1), above the lower pulley (110), there is a rigidly fixed upper pulley (110) having a diameter equal to that of a rectangular triangle with an oblique equal to the sloping annular disc (15) and outer cylinder (7). ), the corresponding part of which is distal to the upper pivot axis (4) (at the lower side of the outer cylinder (7) on different sides of the pivot axis (4) of the cone (1)), on the circumferential surface, on the side of the outer diameter, and above the upper pulley (110) in the upper axis of rotation of the cone (1) is a rigidly engaged transmission gear pulley (pulley) (6). On the right-hand side of the cut cone (1) with its upper pivot axis (4), the pulley (105) is mounted in its lateral support (5) so that the axis (106) rotates freely in the lateral support (5). ) and cannot move in a vertical direction, the pulley (105) is rigidly mounted on an axle (106) such that it is in a horizontal plane with the upper pulley (110) to which is connected (joined) a "0" form belt (103). and the pivot (89) is rigidly mounted on the pivot axis (106) of the pulley (105), below the pulley (105), so that it is flush with, connected to and connected to the lower pulley (110). the number "0" in the form of a belt (85), and below the pulley (89), on its axis of rotation (106), is a rigidly engaged transmission pinion (pulley) (6). The lower hollow spindle (53) of the cone (1) has an analogously mounted core (53) so that it rotates freely in the lower spindle (4) and can move freely in the vertical direction and its top is rigid at one end above the cut cone (1). fixed, non-contacting slanting ring disc (15) and cone (1), a rigid free-loading coupling (58) which is secured at the other end, terminating on the horizontal axis (59), to the satellite rod-carriage (35) in its upper horizontal hole (35). 43), but when using a satellite tube (30) in the form of an arc (108) (load (83) is about 0.7 times less at the same engine power), the load connector (58) terminates in a vertical downward direction on the shaft (59) resting (may be appropriately secured through the hinge (98)) to a horizontally cut bow (108) in the form of a bow (35) in a satellite tube (30) in the shape of an arc (108), which is not in contact with this axis (59) and is rigidly fixed in the joint (24) such that the tangents of the respective arcs of the tube (30) and the rod (35) are vertical at their upper ends (the tangents of the respective arcs 45 ° angles), the upper end, the arcuate tube (30) is in a vertical plane perpendicular to the plane of the inclined disk (15) and the support wheel (40) of the arcuate bar (35) having a cross-sectional shape (diamond) , its sides) are undetermined, resting against the inclined ring disc (15), its upper side (22) such that a line passing through the point of contact of that wheel (40) with the inclined ring disc (15) and through the axis of rotation of that wheel (15). 41) is perpendicular to the plane of the inclined disk (15) and the axis of rotation (41) of the support wheel (40) is parallel to the left horizontal radius of the inclined disk (15) which is tangent to the support wheel (40) and, in such a position of the satellite tube (30), regardless of its shape, the connector (24) is fixed by a screw-lock (28) in the lower pulley (110). The end of the outer cylinder (7) farthest from the upper axis of rotation (4) of the cone (1), the joint between it and the circumferential surface of the outer cylinder (7) is pressed against the normal pressing of the lateral surface of the cut cone (1) a roller (90) rolling on an inner or outer circumferential surface of the outer cylinder (7) and rotating freely on a common axis of rotation (23) of the annular disk (15) and outer cylinder (7) in a single vertical plane with a cone (1) a pivot axis (4), a conical (1) outer surface forming member (2) which is frictionally actuated by an outer cylinder (7) and rigidly mounted on one end of a rigid free-joint joint (92) that does not touch engine components, and the end being rigidly secured to the lower pulley (110) or joint (24). The diameter of the lower pulley (110) is twice the diameter of the upper pulley (110) and the pulley (105) and (89) of the same diameter, but the diameters of the pulley (110), (105), (89) depending on the particular outer cylinder (7), the outer diameter of the outer cylinder (7) is specifically calculated (in the particular case where the outer cylinder (7) has a length and an outer diameter such that the outer cylinder (7) rolls over its outer circumferential surface and farther from the upper axis of rotation 4) the end joint with the outer diameter of the corresponding diameter of the cut cone (1), the outer cylinder (7) rotates about the lower axis of rotation (4) of the cone (1) once and about the common axis of rotation (23) ) twice, the diameter of the lower pulley (110) is three times that of the upper pulley (110) and the pulleys (105) and (89)) the leverage is counterbalanced by the balance (84). When the satellite rod-carriage (35) is loaded with a load (83), the load, gravitationally applied, rotates the outer cylinder (7), the slanting ring disc (15) through the support wheel (40) of the carriage (35), the cone (1). clockwise and rotates clockwise through its lever (14), axis (10) and inner cylinder (9), and through the satellite tube (30), regardless of its shape (4) acting on a joint (24) of a thrust of about 0.4 loads (83) gravitationally) at its outer, longest arc ends, and at the respective radii of that arc at those ends, the bolt (24) - the locking pin (28), the lower pulley (110), the belt (85), the pulley (89), its pivot axis (106), the pulley (105), the belt (103) and the upper pulley (110) rotate the upper part of the cone (1) rotation axis (4) counterclockwise with greater force. In addition, a modification is possible in which, in order to reduce the weight of the outer cylinder (7), the respective middle part of the outer cylinder (7) is removed in two transverse sections, the remainder of the cylindrical portions having different diameters the other two slanting discs (15) of the same or corresponding diameter rigidly fixed (or, by analogy, two levers (14) of corresponding length), the respective levers (14) of which are rigidly connected by a straight rigid joint (107), that this joint coincides with the common axis of rotation (23) of the slanting ring discs (15) and the remaining corresponding parts of the outer cylinder (7), so that a modification is possible when the power transmission pinion (pulley) (6) is mounted in the lower cone (1) in the axis of rotation (4) so that it rotates freely on that axis, cannot move in a vertical direction and is rigid It is connected to one end of the free-form elongated portion (49) of the abandoned "L" -shaped plate (47) and at the other end of which rotates freely with a straight rigid joint (107). (4) instead of the cut cone (1), only the outer lateral surface of that cone (1) consisting of its lateral forming members (2) is rigidly supported by the shorter part (50) of the "L" shaped plate (47). basis (3), viz a corresponding radius of said cross section of eight arcs (108) forming a complete horizontal ring which is frictionally connected to the upper lateral surface (junction) of the end of the outer cylinder (7) farther from the axis of rotation (4). The upper pulley (110) is frictionally coupled to the pulley (105) and, in the first described embodiment of the outer cylinder (7), having a length to diameter ratio, the pulley (105) is 1.414 times larger than the lower pulley (110), the diameters of the pulleys (110) and pulleys (89) (the number of decimals is not specified in the calculations and, depending on their number, the value of the abovementioned number may be adjusted). the upper rotation axis (4) of the cut cone (1) rotating once on the annular disk (15) to which the outer cylinder (7) is rigidly attached, ie zero when this cylinder is not present, rotating about its upper axis of rotation (4) approximately 3.44 times (in the calculations the number of significant figures after the decimal point is not determined and depending on their number the value of the said number can be specified which is very important) the plane forming an angle of 45 ° so that the diameter of the pulley (89) is 3.44 times the number of the lower pulley (110), the upper pulley (110), and the pulley (105), which are equal to a the oblique is equal to half of the outer diameter of the sloping annular disk (15) and the outer cylinder (7), which are similarly connected by the straps (103) and (85) respectively and twice the radius of the outer cylinder (7) the lower side ends of the cylinder (7) are on one side of the lower and upper axes of rotation (4), viz when the distal end of the outer cylinder (7) from the sloping annular disk (15) is frictionally connected to the corresponding lateral circumferential surface of the cone (1), the diameter of the pulley (89) is 6.88 times (possible analogically adjusted number) times the diameters of the pulleys (110) and (105) having the same diameter. The balance of the rotating parts of the motor is compensated by the balancer (84). After loading the satellite cart (35) with a load (83), in the first case, the upper axis of rotation (4) of the cone (1), due to the winning force, rotates clockwise, in the second case anticlockwise and specific excess force required for system operation. the loading charge (83) is applied via a power transmission pulley (6) specifically to rotate the power generator required for such a force, and the like. or the excess power may be automated or otherwise purposefully utilized by computer, respectively. Engine component parameters, wheel (40) bearing location on disc (15), engine component frictional surfaces, undetectable, in place of pulleys (110), (105) (89) with diameters depending on specific outer cylinder (7) length, the outer diameter being specifically calculated, wheels, friction wheels, toothed wheels with respective belts, the position of the support wheel (40) of the satellite trolley (35) in the inclined ring disc (15) can be used, at least where the outer cylinder (7) is less than half of the outer diameter of the inclined annular disk (15), may be offset from a vertical plane perpendicular to the side walls (31) of the rectangular tube (30) (parallel to the vertical plane containing the upper axis of rotation (4) of the cone a component (2) of its outer circumferential surface which is in contact with the outer cylinder (7) with its friction gear at its end, its respective part, or a sloping annular disk (15) with its lower half (21), its respective portion when the outer cylinder (7) is zero) and having an upper pivot axis (4) of the cone (1) such that the satellite cart ( 35) the center (44) of the upper horizontal hole (43) is in that plane. In addition, modification is possible when the inner cylinder (9) is similarly rigidly mounted on the upper hollow axis of rotation (4) of the cone (1) in a freely rotating and incapable vertical movement on the vertical axis (88) below and below the cone (1), in the lower axis of rotation (4) of the cone (1), there is a free-rotating joint (87) rotating freely on one end and terminating on the other end in at least two arcs (108) in a vertical plane (centered on the inclined annular disk (15) the center of the axis (23) being in the plane of said disk (15) having a center of their total length in a horizontal line passing through this center and having a radius equal to the distance from said center of rotation axis (23) of the inclined annular disk the plane of the disc (15) in which the other rhomboidal press wheel (90) rotates freely on its individual, parallel recline a plane of a rotary axis (91) rigidly mounted on the outer circumferential surface of the disc (15) and coinciding with a corresponding radius of rotation of said disc (15) perpendicular to said rotation plane of the wheel (90) located on the inclined annular disc (15). in the plane, on its underside (21)), with the upper part of the length to which said wheel (90) is supported by the slanting ring disc (15) rotating clockwise, ie the vertical plane containing said upper portion of the two arcs (108) of said joint (87) being parallel to the vertical plane containing the axis of rotation (91) of the press wheel (90) and spaced from one another through the radius of said wheel (90). whose length is not adjustable. The upper pulley (110) is mounted below the cone (1) on the lower axis of rotation (4) of the cone (1) so that it cannot rotate freely about it, has a recess (27) and is respectively analogous to a bolt-lock (28). connected to the connector (87) through a hole (26) therein. The pulleys (105) are rigidly mounted on its pivot axis (106), extending downwardly so that the latter pulleys (110) and (105) are in one horizontal plane and connected by a belt (103), but instead of the inner cylinder (9) in the vertical axis ( 88) whether a hollow inner ball of rigidly interconnected arcs (108) or portions thereof freely rotating in hollow outer hemispheres analogous to arcs (108) or its can be fixed in the upper axis of rotation (4) of the cone (1) the parts so that the centers of the spheres coincide, cannot move with respect to each other, are downwardly of the axes (88), (4), coincide with the center of the axle (10) and terminate (hemispherically) in the middle of the lever (14) such that the spherical top of the upper hemisphere, with the lever (14) horizontal, is cut horizontally so that the annular disk (15) is inclined the upper hemisphere does not touch the vertical axis (88) or the upper axis of rotation (4) of the cut cone (1). In addition, a modification is possible in which the inner cylinder (9) is similarly rigidly secured to the lower core (53), its upper, freely rotating hollow lower axis of rotation (4) of the cone (1) such that the lower core (53) cannot move vertically and the upper side (22) of the sloping annular disk (15) has a rigidly mounted outer cylinder (7) which terminates analogously with a straight rigid joint (107) having at its other end a razor-shaped cone (1) rigidly and similarly inclined. 107) coincides with the common axis of rotation (23) of the outer cylinder (7), the inclined disc (15) and the cone (1) passing through the intersection of the lever (14) and the horizontal axis (10), which is in one horizontal plane the lower lateral forming part (2) of the cut cone (1) and the other cut at the lower axis of rotation of the cone (4) the upper horizontal surface of the cone (1) being frictionally connected to the lateral circumferential surface of the inclined cone (1) and its lower lateral forming part (2). In the lower axis of rotation (4) of the cone (1), above the lower support (5), where this axle (4) is rigidly mounted, and below the rigid cone (1), which has an aperture (27) in its upper part the ring disc (15) touching the lower cone (1), the upper pulley (110) and the coupling (24) (with the satellite tube (30) and the carriage (35)) are fixed so that they rotate freely about the lower cone (1). the axis of rotation (4) cannot move in a vertical direction and are interconnected by a bolt-lock (28). The upper pulley (110) is connected to the pulley (105) by a belt (103) (may be coupled to a toothed belt (103) as a toothed wheel, etc.), and the pulley (89) is frictionally coupled to the lower pulley (110) ( as friction or pinion wheels of a corresponding diameter), similarly rigidly mounted in the lower core (53), which has a rigidly mounted power transmission pinion (pulley) (6). A load coupling (58) is provided in the hollow pivot axis (4) of the lower cone (1) so that it rotates freely in that axis and freely moves in the vertical direction and under the gravitational force of the load (83) rotating the upper pulley (110) about the pivot axis. (4) once counterclockwise, the inclined incised cone (1) rotates the lower core (53) only 0.414 (the number can be adjusted analogously) once clockwise so the diameter of the lower pulley, pinion, friction wheel (110) is 2,414 (the number can be adjusted analogously for the number of significant digits used in the calculations, which is not decimated, which is very important) times the diameter of the top pulley, the pinion (110) and the pinion pulley (106) and (89). diameters (diameter of the last cog wheels (106) and (89) i can be any size but equal), so due to the winning force, the lower core (53) rotates clockwise. In addition, engine modifications are possible without departing from the following frames: radius of cut cone (1), base (3), angle size formed by cone (1) side surface forming elements (2) with base (3), angle size, consisting of a lower wall (33) of the tube (30) with a plane containing the base (3) of the cut cone (1), the seat of the support wheel (40) of the satellite trolley (35) on the plate (47) and the inclined annular disk (15) position of the joint (24) and the respective mounting points of the power transmission gear (6) on the axis of rotation of the cut cone (1), the "exposition" of the horizontal plane of the mirror (101) on the vertical axis of rotation of the cut cone (1) 4) to build the mirror motor (99), the length of the handle (77), the size and type of the force acting on the longer part (78) (force of gravity of the load, human muscle force, mechanical force), engine components (angular s disc (15) with an "L" letter plate (47)) whose individual equilibrium can be offset by balancers (84), the size of the inner (9) and outer (7) cylinders of the sloping annular disk (15), L-shaped plate (47) lengths (49), (50) lengths, belts (85), (103) lengths, cross-sectional shape and engine component parameters, sizes, numbers (satellite rod truck (35) may have a second analogue secured therein by a support wheel (40) and resting on the lower guide wall (33) of the rectangular tube (30) such that the lines connecting the respective horizontal pivot axes (41) of both support wheels (40) to the horizontal axis (59) of the load connector (58). ) or connecting the centers (46) of the respective horizontal holes (38) drilled on said axes (41) with respect to their diameter to the horizontal holes (43) drilled on the axis (59) with respect to their center, forming a right angle and the position with respect to other engine components is not determined in the engine modifications, nor is the design of the engine controlled and the size of the load, the method of loading which may be accomplished by compressed spring, compressed or compressed air, gas and magnetic, electromagnetic forces, etc., and in addition, or in the cut cone (1), which may be replaced by the disc, in its axis of rotation (4) by the removal of the described other engine components mentioned magnetic, electrical, electromagnetic or any other antigravity forces of corresponding power, or waves of appropriate power, intensity, length, defeating or eliminating, counteracting the gravitational forces acting on the charge (part of the cut cone (1) with respect to its axis of rotation (4)) may be directed directly to the respective mechanism (60) as the source of those waves left-handed cone (1); or d the front perpendicular to its axis of rotation (4), half or part thereof, perpendicular to the horizontal plane containing the axis of rotation (4) of the cut cone (1) and bottom up or in any direction such that the cone (1) is cut, even directly, by neutralizing the action of the respective gravitational forces on its said part by anti-gravity material shielding or otherwise.

Claims (12)

DEFINITION OF INVENTION 1. A gravitational motor based on the action of gravitational and simulated forces, operating in long-term imbalance, having a rotatable disc (1), a recess (27) therein, a transmission gear (pulleys, sprockets, friction wheels) (6), a disc (1). ) and a common pivot axis (4) of the transmission pinion (6) mounted on the support (5), the balance levers (84) of the disc (1), the loading mechanism (60), the load (83) to maintain the rotational motion of the disc (1), characterized in that this charge (83) is mounted in the satellite trolley (35), the rotating disk being a rotating cone (1), which is cut parallel to its horizontal lower part, the base (3), and whose outer side surface is formed (2). forming at an angle of 45 ° respectively with the plane of the horizontal base (3) of the cut cone (1), rigidly mounted on its vertical hollow cylindrical pivot axis (4) fixed at in the frame (5) such that the axis of rotation (4) of the rotating cut cone (1) rotates freely in the support (5) and cannot rotate therein along its axis, and on the axis of rotation (4) of the rotating cut cone (1). ), the required power transmission pinion (6) (pulleys, sprockets, friction wheels, etc.) is rigidly fixed so that it does not touch the support (5); furthermore, on the hollow axis of rotation (1) of the rotary cut cone (1), a horizontal outer cylinder (7) is rigidly mounted at its upper end such that its center (8) is in relation to its length and its outer and inner diameters. (1) in the extension of the axis of rotation (4) upwards, in its center, the ends being in the respective vertical planes. 2. A gravitational motor according to claim 1, characterized in that a horizontal inner cylinder (9) of the same length is mounted in the horizontal outer cylinder (7) with an outer diameter equal to the inner diameter of the outer cylinder (7) so that it rotates freely in the outer cylinder. (7) and cannot move along it, and the inner cylinder (9), on its inner side surface and in the middle of its length, has a rigid end-mounted rigid horizontal axis (10) parallel to vertical planes perpendicular to the inner cylinder (9). surface members (11) having a length equal to the inner diameter of the inner cylinder (9); furthermore, a rigid arm (14) is mounted on the center (12) of the horizontal axis (10) with its middle part (13) so that it rotates freely on that axis (10), cannot move at right angles thereto, it is not adjustable and inclined and, at its ends, is rigidly mounted on an inner circumferential surface (16) of a sloping annular disk (15) having a diameter equal to the length of the lever (14) and an outer circumferential surface of the sloping annular disk (15) 17) the radius is equal to the distance from the center (12) of the horizontal axis (10) in length and thickness, coinciding with the center (18) of the axis of rotation (18) of the rotating cut cone (1) 1) at the point of intersection (19) of the outer side surface members (2) to the outer circumferential surface (20) of the cut cone (1) base (3); furthermore, the underside (21) of the inclined annular disk (15) extends in a part of its plane to the outer side surface member (2) of the frictionally actuated cone (1) which is in one vertical plane with the lever (14). length, ie the plane of the inclined annular disk (15) forms an angle of 45 ° with the horizontal plane of the base (3) of the rotating cut cone (1) (vertical distance from the center (12) of said horizontal axis (10) in length and thickness to the cut cone 1) the center of the base (3) is equal to the length of the radius of the base (3) of the cut cone (1) and this annular disk (15) is frictionally connected to the outside of the cut cone (1) lateral surface, its respective forming (2) such that the inner circumferential surface (16) of the inclined annular disk (15) does not touch the axis of rotation (4) of the cut cone (1), which is intersected upward in its center (18). and at the intersection (19) of the outer lateral surface of the cut cone (1), the horizontal axis (10) with its center (12), the lever (14) with its center (13), the outer (7) and the inner ( 9) Horizontal cylinders in their long with a common center (8) of diameters and diameters, the plane comprising the underside (21) of the bevelled annular disk (15), which is parallel to its upper half (22), and (at point (19)) the inclined annular disk (15). a pivot axis (23) rigidly connected to the pivot axis (4) of the cut cone (1) with respect to the pivoting point of the cut cone (1) and its axis (4), through a horizontal axis (10) which positioning with respect to the horizontal, the inner (9) and outer (7) cylinders having diameters and lengths such that the lever (14) does not touch those cylinders (7), (9). 3. A gravitational motor according to claims 1-2, characterized in that on the axis of rotation (4) of the rotating cut cone (1), below the base (3) of the cone (1), there is a rigid, free-flanged joint (24) so that it rotates freely on that axis (4), cannot move along it and does not touch its support (5), and a horizontal hole (26) is drilled in the horizontal part (25) of the joint (24) at the base of the cut cone (1). (3) is formed by an arc (26) of diameter (25) wide but of unspecified length whose radius of intersection is the axis of rotation (4) of the cut cone (1), through which said joint (24) a hole (26), the bolt (28) having the diameter of that hole (26), the connector (24) being rigidly secured to the base (3) of the cut cone (1), in the required radius of the base (3), depending on the shape of the connector (24); furthermore, at the other end of the rigid, free-flowing target joint (24) above the left lower quarter (29) of the rotating truncated cone (1) base (3) to the left and down, there is a rigid rectangular cross-section, a tube (30) such that its side walls (31) are in respective vertical planes parallel to the vertical plane containing the axis of rotation (4) of the pivoting cone (1) and the upper radius (32) of the base (3) of the cone (1), the lower guide wall (33) having an angle of 45 ° with the horizontal plane and with the plane of the base (3) of the rotary cut cone (1) and its extension respectively with the bevelled annular disk (15), its upper side (22) parallel to its upper right angles (34) to the lower half (21), plane and its extension, 90 ° above the side walls (31) of the rectangular tube (30) without touching the lower guide These walls (33) are purposefully cut. 4. A gravitational engine according to claims 1-3, wherein the rectangular tube (30) has a rectangular bar (35) having a length equal to the length of the rectangular tube (30) and a width and height corresponding to the internal distance between them. a wall of the side walls (31) of the rectangular tube (30) and between its upper (36) and lower guide (33) walls so that it slides freely within the rectangular tube (30) and cannot rotate therein; in addition, the rectangular bar (35) disposed in an oblique rectangular tube (30) closer to its lower end (37) and the upper wall (36) of the tube (30) has a recessed lower perpendicular to the side walls (31) of the rectangular tube (30), a horizontal hole (38) and an exit (39) of appropriate shape and size, having a substantially accommodated satellite wheel (35) support wheel (40) having a pivot axis (41) rigidly secured to a lower horizontal rectangular bar (35) to in a hole of the same diameter (38) such that the support wheel (40) rotates freely on its axis of rotation (41), cannot slip along its axis and does not touch the rectangular bar (35) or its rectangular tube (30) a rectangular bar (35) near its upper end (42) has a drilled upper, perpendicular to the lateral sides of the rectangular tube (30) the rods (31), a horizontal hole (43) having a center (44) with a vertical line passing through the upper corner (45) of the rectangular bar (35) and lines passing through a rectangular bar (35) a point of intersection of the lower horizontal hole (38) with respect to its diameter, and a center (46) parallel to the lower guide wall (33) of the rectangular tube (30) and its side walls (31). 5. Gravity engine according to claims 1-4, characterized in that the satellite support wheel (40) of the satellite trolley (35) is resting on a rigid, lightweight L-shaped plate (47) rotated at 90 ° to the right and rigidly mounted on the inclined annular disk. (15), in its lower part (48) on its upper side (22) such that the respective planes containing this plate (47) and the inclined annular disk (15) are parallel to each other and, when the engine is running, the plates (47). the longitudinal part (49) being horizontal and perpendicular to the vertical plane having the forming (2) of the outer lateral surface of the cut cone (1), which is in contact with the plane of its lower side (21) with the frictionally driven inclined annular disk (15); furthermore, the seat of the satellite wheelchair (35) support wheel (40), rotated to the right in the "L" shaped plate (47), is located on the shorter portion (50) of this plate (47) above the left lower quarter (15). 51) the lower part (52) of the extension left and down, and the direction of support is perpendicular to the planes parallel to each other, their extensions having respectively a sloping annular disk (15) and a plate (47) and parallel to the lower guide wall of the rectangle tube (30); (33) and its sidewalls (31). 6. A gravitational motor according to claims 1-5, characterized in that the hollow pivot axis (4) of the rotating cut cone (1) is provided with a cylindrical core (53) having a diameter equal to the axis of rotation (4) of the hollow cylindrical cut cone (1). ) with an inner diameter such that, with its lower part (54) terminating on the upper (55) and lower (56) horizontal discs rigidly fixed thereto, the core (53) protrudes from the axis of rotation (4) of the hollow cone (1), the core (53) is free to slide along and rotate therein, and the axis of rotation (4) of the cut cone (1), in its part below the cone (1), has a vertical elongated passage of equal width, a rigid, free-purpose load-carrying connection (58) is provided which is rigidly secured at one end to the core (53) and at the other end terminating in a horizontal axis (59) having a diameter of s (59) in the upper horizontal hole (43) of the rectangular bar - satellite trolley (35) such that the rigid loading connection (58) does not touch the sloping annular disk (15), the cut cone (1), its axis of rotation (4), the axis (59) cannot move transversely of the rectangular bar (35) and does not touch the rectangular tube (30); furthermore, the support (59a) located below the core (53) on the flaps (55), (56) and on the left side of the pivot axis (4) of the cut cone (1) has a rigidly fixed vertical, square cross section, stand (60) ( an integral part of the loading mechanism (60), such that its two opposite sides are parallel to a vertical plane having the upper radius (32) of the cut cone (1) base (3) and a square of cross section of the stand (60) at a height, the center (61) is in a respective horizontal line passing through the axis of rotation (4) of the cut cone (1), its center (18) and perpendicular to the vertical plane containing the upper radius (32) of the base (3) of the cut cone (1). . 7. A gravitational motor according to claims 1-6, characterized in that a square hollow (60) is provided with a hollow, square in its inner and outer cross-section, the inner cross-section of which is equal to the cross-section of the square stand (60). (62) having inner sides parallel to its respective outer sides and corresponding sides of the rack (60) such that it can slide freely upwardly downwardly of the square rack (60) and the sleeve (62) in the outer on the side (63) closer to the axis of rotation (4) of the cut cone (1), a rigid horizontal axis (64) is mounted at one end so that it rotates freely in the sleeve (62) and cannot move transversely therethrough; the center of the square (61) of the cross-section of the stand (60) and the axis of rotation (4) of the cut cone (1), its center (18), the other end of the axis (64) ending in a horizontal symmetrical axis; the hinge (64) extending towards the cone (1) relative to the axis of rotation (4), a hemisphere having a point of intersection at the extension of that axis (64) and a center (65) of the core (53) coincident with the cone (1). ) at the center (18) of the pivot axis (4), in the form of a fork (66) with its respective horizontal axes (67) rigidly fixed at each end so that they are in extension to one another, outside the fork (66) and in a vertical plane containing the cut cone (1) an upper radius (32) of the base (3); furthermore, respective forks (67) are provided with corresponding diamond-shaped cross-sections of the same diameter in the cross-section of the fork (66) such that they freely rotate on their respective individual shafts (67), cannot slip along them and are equally spaced from the core. (53) not touched by a fork (66), and by touching the upper side (69) of the lower disk (56) of the core (53) does not touch the upper disk (55) of the core (53) and its lower side (70). 8. Gravity motor according to claims 1-7, characterized in that a vertical pinion (71) is rigidly mounted on the side of the sleeve (62) behind the stand (60) and the upper beam (32) of the cone (1) base. ), the teeth (72) of which are connected to a toothed wheel (73) rigidly mounted on its horizontal pivot axis (74), which rotates freely in the support (75) such that said axis (74) cannot move in the support (75) and is perpendicular a vertical plane having the upper radius (32) of the cut cone (1) base (3), by the gear (76) of the same module and on the end of the pinion (74) on the left side of the stand (60); further away from the core (53), there is a rigidly fitting short-end f-handle - the engine start, adjust and stop device (77) such that it is all (handle) in a horizontal plane, its longer portion (78) perpendicular to that pinion. rotation of the wheel (73) an axial axis (74) parallel to a vertical plane having the upper radius (32) of the base (3) of the cone (1) and fixed in its respective position with respect to its horizontal position by the latch (79) in the annular support (80); moreover, the elongate portion (78) of the handle (77) is freely slidably secured thereto by a loop (81) on the handle (77) located outside the pivot axis (74) of the toothed wheel (73) and secured therein by a latch (82). in the handle portion) the load (83) such that the center of gravity of that load (83) is in the axis of rotation (74) of the toothed wheel (73), even with the axis of rotation of the cut cone (1) and the like 1) Equilibrium (aligned forces, centrifugal, symmetrical with respect to the rotational axis (4) of the cone (1) of the engine components) is aligned with the balance (84). A gravitational motor according to claims 1-8, characterized in that the engine, at least once, for operation of the engine: with the inclined ring ring (15) in its initial position, i.e. when its lever (14) is in one vertical plane with the forming side (2) of the outer side surface of the rotating cut cone (1), which is in contact with the slanting ring disc (15) with its friction drive part of its lower side (21); is temporarily locked in its non-rotatable axis of rotation (4), the inclined annular disk (15), at any point in its lower left quadrant (51), is pressed by a hand muscle or other force perpendicular to the plane of the inclined annular disk (15) , until the slanting ring disc (15) is flush with the outer lateral surface of the cut cone (1) to the right, clockwise with respect to the base (3) of the cut cone (1), the position of the plane of the slanting ring (15) (3) with respect to upper radius (32), no longer rotating, friction drive surfaces not slipping relative to each other and the sliding annular disk (15) in this position is rigidly mounted on the lower part (48) of its upper side (22) in this position and rotated to the right in the form of an "L" shaped plate (47) so that its longer part (49) () the unit (not its plane) is a horizontal connector (24) having at its end a rectangular tube (30) with the support wheel (40) of the satellite carriage (35) already supported at a desired location on the shorter part (50) of the plate (47), is secured by a bolt-locking device (28) to the base (3) of the rotating cut cone (1) in its respective radius, and the horizontal axis (59) of the load connection (58) is respectively fixed in the satellite carriage (35) with its upper horizontal hole (43). , the other end of that joint (58) being rigidly in the core 53 if the width of the cut-out cone (1) in the axis of rotation (4) is not sufficient or the seat of the satellite wheel (35) wheel (40) in the plate (47). or the inclined ring disc (15) does not satisfy desires, i.e. the latter two constructive steps may be performed earlier; moreover, it removes the temporary fixation of the rotating cut cone (1), which prevents this cone from rotating about its axis of rotation (4) and balances its balance with the balance (84). 10. A gravitational motor according to claims 1-9, characterized in that modifications of the motor are possible, whereby the load (83) is rigidly mounted directly on the axis (59) of the load connection (58), releasing the core (53) of the load connection (58) itself. couplings (62) and the like. or when the load (83) is attached to the shaft (59) by a belt (85) because the gravitational force of the load (83) changes the rotational speed of the rotating cut cone (1) as it moves through the centrifugal force and for the ratio of force to its rotational centrifugal force, the decrease and increase of rotational acceleration of the cut cone (1) is repeated periodically; furthermore, the centrifugal force of the load (83) can in this case be counteracted by attaching it to the pivot axis (4) of the cone (1) with a flexible or rigid coupling (86) of appropriate length such that the belt (85) is vertical and ) the centrifugal force can be used to rotate the cut cone (1) about its axis of rotation (4), wherein the rigid joint (24) has a rigid free-formed joint (87) at one end and a horizontal axis (88) terminating freely at the other end rotating pulley (89) such that pulley (89) cannot move along axis (88), horizontal axis (88) is perpendicular to vertical plane containing corresponding radius of cut-off cone (1) base (3), axis (59), load (83) center of gravity, round in its cross section vertical belt (85) and tangent pulley (89), belt (85) is between pivot axis (4) of pulleys (89) and cut cone (1), load (85) is below pulley (89). 11. Gravity engine according to claims 1-10, characterized in that, in modifications, the friction drive surfaces of the engine components can be increased frictional or have special microbumps and additionally pressed against each other by a normal press wheel (90) freely rotating on a parallel cut cone (1). ) the outer side surface forming member (2) touching a part of the plane of the lower side (21) of the inclined ring disc (15) in a friction drive, the axes (91) being in one vertical plane with said conical (1) forming axis (2); 4) and the load (83) of a rigid joint (92) rigidly mounted on one end, the other end of which is rigidly mounted on a joint (24) containing a rectangular tube (30), may be simulated by a tensioned vertical spring (93) can be secured to said shaft (59) or handle (77), its longer part (78) , the other, respectively, may be secured in a joint (24) in which a rectangular tube (30) is mounted or in a row support and whose tension, compression, including replacements for that spring (93), can be automatically adjusted, even remotely by a rotating cut cone (1) the equilibrium (aligned with the centrifugal, symmetrical axis of rotation (4) of the components of the cone (1), forces) in the engine modifications may be offset not only by the balance (84) but / or by a second, appropriately anchored (equal weight), a rotary axis (4) of the cone (1) cut by the device described, rotated 180 ° about the axis of rotation (4) of the cone (1) counterclockwise or clockwise with respect to the device described: instead of one inclined ring disc (15) and lever (14) for connecting it to the horizontal axis (10) of the inner cylinder (9), two slanting ring discs (15), external, symmetrical to it, may be used. with respect to the pivot axis (12), the parts (94), (95) which are respectively connected to the horizontal axis (10) of the inner cylinder (9) by replacing the lever (14) with the hinge (2) 98) such that the planes containing those portions of the annular disk (94), (95) are perpendicular to one another when the same cut cone (1) and common handle (77) are used or parallel when the mirror cut cone is used ( 99) and other similar components of the mirror motor (100), the mirror (101) having a horizontal plane and having a lever (14), a horizontal axis (10) of a hinge (98) or an inner cylinder (9), 15) axis of rotation (23) and common point (19) of intersection of cut-off cones (1), (99) of respective outer side surfaces (2), sloping annular disc (15) and cut-off cone (1), through its base (3) ), may be overloaded with another load (102), attached you at one end of the strap (103) fixed at the other end to the hook (104) rigidly fixed on the underside (21) of the bevelled annular disc (15) or on the short side (50) of the "L" shaped plate (47) for the operation of the structural preparation of the engine, which is based on the distance between the friction surfaces of the inclined ring disc (15) and the cut cone (1) relative to the axis of rotation (4) of the cut cone (1) purposeful use of circles) such that the plane of the pulley (105) having a horizontal pivot axis (106) fixed by a rigid joint (107) in a joint (24) containing a rectangular tube (30) is parallel to the lateral sides of the tube (30). for the walls (31), the belt (103) connecting the pulley (105) on its right side (viewed horizontally, parallel to the plane of the sloping annular disk (15) when it is inclined the nose is inclined from the right) its eighth to the top (the bow (108) can be rigidly secured), the upper branch (109) is parallel to the lower guide wall (33) of the tube (30) and its sidewalls (31); (102) for rotating the centrifugal force of the cut cone (1), a pulley (110) fixed in a rigid joint (24) containing a tube (30) may be used analogously to the pulley (89) but in a new condition and a second hook (104). ), may also be mounted on the upper portion (22) of the inclined ring disc (15), in its right quarters (the number of hooks (104) is unlimited), and by analogy additionally in the respective engine components other pulleys (105) and (110) a belt (103) having one end secured to a second hook (104) and the other end secured to a second load (102) connecting the second pulley (110) the pin (111) over its top, and the second pulley (105) on its left side, one-eighth down (only their bows (108), (111) can be used so that the lower leg (112) of the second belt (103) being parallel to the upper branch (109) of the first belt (103); in addition, engine modification is possible by properly assembling, disassociating, or reusing some of the engine components, leaving the number of engine components indeterminate, so that the engine design, "In the extension of the letter-shaped plate (47) and the outer cylinder (7) with the vertical hollow axis of rotation (4) of the tapered cone (1) upwards, ie the upper vertical hollow axis of rotation (4) mounted in the upper support (5) such that the upper axis of rotation (4) rotates freely in the upper support (5) and cannot shift in the vertical direction, the lower part of this upper axis of rotation (4) a cylinder (9) such that its lateral surface components (11) are parallel to a horizontal plane, its rigid axis (10) whose ends rotate freely in the inner cylinder (9) and whose center coincides with the center (8) of the cylinder and the cone (1) ) in the extension of the upper pivot axis (4) down the center (18), is horizontal and cannot move horizontally, the lever (14) of the sloping ring disc (15) rotates freely with its middle part in the rigid axis (10) of the inner cylinder (9) , is perpendicular to it and cannot move across it, and the outer cylinder (7) having an outside diameter that is not adjustable is equal to ulniojo circular disk (15), in a plane forming with the horizontal plane of 45 °, the outer diameter and length, which also has been fixed, is equal to the inclined annular plate (15) the outer circumferential surface (17) the length of the radius (i.e. the outer diameter of that disk (15)) and the sum of the diagonal lengths of the right triangle whose static (indeterminate lengths) are equal to this radius, are rigidly fixed at one end to the oblique annular disk (15) such that the axis of rotation (23) of the sloping annular disk (15) and the axis of rotation of the outer cylinder (7) coincide with the outer circumferential surface of the other end, at the junction of the circumferential surface and the end, the outer cylinder (7) is frictionally coupled to a cut cone (1) analogously rigidly mounted in a lower pivot axis (4) extending downward from the upper pivot axis (4) and rigidly secured in the lower in the axial support (5), the outer circumferential (or conical top) surface at which the diameter of the cone (1) is equal to the diameter of the annular disk (15) and the outer cylinder (7), ie the outer cylinder (7) once, without their respective outer circular surfaces slipping relative to one another, the outer cylinder (7), the slanting ring disc (15) rotates about their common axis of rotation (23) once by rotating the upper axis of rotation (4) through the lever (14), the shaft (10) and the inner cylinder (9) twice; on the upper pivot axis (4) of the cone (1) above the inner cylinder (9) and the sloping annular disk (15) and the free-form rigid joint (24) which is fixed at one end to the upper pivot axis (4) so that it rotates freely about said axis (4), not touching the inclined disk (15) and having at its other end a rectangular tube (30) with a satellite rod-carriage (35) respectively, whose shape, including its cross-sectional shape, is undetectable (108) having a shape equal to one-eighth of the corresponding circumference, that is, the respective lower guide and upper walls (33), (36) of the rectangular tube (30) may be arcs (108) corresponding to an arc tube like an analogue bar -the bow (108) corresponding to the bogie (35), the lower pulley (110) is fixed so that it rotates freely about the upper axis of rotation of the cone (1), cannot rotate rotating in a vertical direction and having an arcuate exit (27) at a vertical hole (26) in the joint (24) for securing the joint (24) with a bolt-latch (28) in this pulley; in the upper pivot axis (4) of the cone (1), above the lower pulley (110), there is a rigidly fixed upper pulley (110) having a diameter equal to a static rectangle having an oblique plane equal to the sloping annular disc (15) and the outer cylinder (7) ), the corresponding part of which is distal to the upper pivot axis (4) (at the lower side of the outer cylinder (7) on different sides of the pivot axis (4) of the cone (1)), on the circumferential surface, half of the outer diameter, and on the upper pulley (110) in the upper axis of rotation of the cone (1), a force transmission pulley (pulley) (6) is fixed; on its right side relative to the cut cone (1), its upper pivot axis (4), the pivot (105) is mounted in its lateral support (5) so that the pivot (106) rotates freely in the lateral support (5). ) and cannot move in a vertical direction, the pulley (105) is rigidly mounted on an axle (106) such that it is in a horizontal plane with the upper pulley (110) to which is connected (joined) a "0" form belt (103). and the pivot (89) is rigidly mounted on the pivot axis (106) of the pulley (105), below the pulley (105), so that it is in a horizontal plane with the lower pulley (110), not touched and connected thereto (coupled). the number "0" in the form of a belt (85), and below the pulley (89), in its axis of rotation (106), is a rigidly engaged power transmission pulley (pulley) (6); the lower hollow axis of rotation of the cone (1) having an analogously secured core (53) so that it rotates freely in the lower axis (4) and can freely move in a vertical direction, the top of which is rigid at one end above the cut cone (1) fixed, non-contacting slanting ring disc (15) and cone (1), a rigid free-loading coupling (58) which is secured at the other end, terminating on the horizontal axis (59), to the satellite rod-carriage (35) in its upper horizontal hole (35). 43), but when using a satellite tube (30) in the form of an arc (108) (load (83) is about 0.7 times less at the same engine power), the load connector (58) terminates in a vertical downward direction on the shaft (59) resting (may be appropriately secured through the hinge (98)) to a horizontally cut bow (108) in the shape of a bow (35) contained in a satellite tube (30) in the shape of an arc (108), which is not in contact with this axis (59) and is rigidly fixed in the joint (24) such that the tangents of the respective arcs of the tube (30) and the rod (35) are vertical at their upper ends (the tangents of the respective arcs 45 °), the upper end of which is formed by an arcuate tube (30) in a vertical plane perpendicular to the plane of the inclined disk (15) and a support wheel (40) of cross-sectional shape (40) the diamond, its side) being undetermined, is resting on the inclined ring disc (15), its upper side (22) such that the line passing through the point of contact of that wheel (40) with the inclined ring disc (15) and through the axis of rotation of that wheel (41) is perpendicular to it, perpendicular to the plane of the inclined disk (15), and the axis of rotation (41) of the support wheel (40) is parallel to the left horizontal radius of the inclined disk (15) the radius of the beam (40) and, in such a position of the satellite tube (30), regardless of its shape, the connector (24) is fixed by a screw-retainer (28) in the lower pulley (110); the end of the outer cylinder (7) farthest from the upper axis of rotation (4) of the cone (1), the joint between it and the circumferential surface of the outer cylinder (7) is pressed against the normal pressing of the lateral surface of the cut cone (1) a roller (90) rolling on the inner or outer circumferential surface of the outer cylinder (7) and rotating freely on a common axis of rotation (23) of the annular disk (15) and outer cylinder (7) in a single vertical plane with a cone (1) a pivot axis (4) formed by the outer surface of the cone (1) a (2) which is in contact with the outer cylinder (7) in a friction gear and rigidly mounted on one end of a rigid free joint (92) the other end being rigidly mounted on the lower pulley (110) or the joint (24), the lower pulley (110) having a diameter twice as large for the diameters of the upper pulleys (110) and pulleys (105) and (89) of the same diameter, but the diameters of the pulleys (110), (105), (89) are specifically calculated, depending on the length of the particular outer cylinder (7). (in a particular case, when the outer cylinder (7) has a length and an outer diameter such that the outer cylinder (7) rolls at its junction between its outer circumferential surface and the end of the upper pivot axis (4) of the cone (1). the outer cylinder (7) rotates about the lower axis of rotation (4) of the cone (1) once and about the common axis of rotation (23) of itself and the bevel ring (15) twice, the diameter of the lower pulley (110) being three times the diameter of the upper pulley (110) and the pulleys (105) and (89)), and the balance of the rotating engine parts is balanced by the balancer (84); when the satellite rod-carriage (35) is loaded with a load (83), the load, gravitationally applied, rotates the outer cylinder (7), the slanting ring disc (15) through the support wheel (40) of the carriage (35), the cone (1) clockwise and rotates clockwise through its lever (14), axis (10) and inner cylinder (9), and through the satellite tube (30), regardless of its shape (4) acting on a joint (24) of a thrust of about 0.4 loads (83) gravitationally) at its outer, longest arc ends, and at the respective radii of that arc at those ends, the bolt (24) - the locking pin (28), the lower pulley (110), the belt (85), the pulley (89), its pivot axis (106), the pulley (105), the belt (103) and the upper pulley (110) rotate the upper part of the cone (1) rotating axis (4) counterclockwise with greater force; furthermore, a modification is possible in which, in order to reduce the weight of the outer cylinder (7), the respective middle portion of the outer cylinder (7) is removed in two transverse sections, the remainder of the cylindrical portions having different diameters the other two slanting discs (15) of the same or corresponding diameter (or, by analogy, two levers (14) of corresponding length), the respective levers (14) of which are rigidly connected by a straight rigid joint (107) this joint coincides with the common axis of rotation (23) of the slanting ring discs (15) and the remaining corresponding parts of the outer cylinder (7), so that a modification is possible when the transmission pinion (pulley) (6) is mounted in the lower pivot (1) on the axis (4) so that it rotates freely on that axis, cannot move vertically and is rigid connected to one end of the free-form elongated portion (49) of the discarded "L" -shaped plate (47) and at the other end of which rotates freely in a straight rigid joint (107); furthermore, a modification is possible whereby the lower axis of rotation (4) of the cone (1), instead of the cut cone (1), is rigidly secured by the shorter part (50) of the "L" shaped plate (47) to that cone (1). ) an outer lateral surface consisting of its lateral formations (2) at its base (3), a corresponding horizontal radius of the octave arcs (108) of said cross-section forming a complete horizontal ring which is frictionally connected to the upper lateral surface (junction) of the outer cylinder (7) at its distal end (4), the upper pulley (110) being a friction drive coupled to the pulley (105), and in the first embodiment of the length-to-diameter ratio of the outer cylinder (7) described above, the diameter of the pulley (105) is 1.414 times larger than the lower pulley (110), upper pulley (110), and pulley (89). ) diameters (the calculations do not specify the number of significant figures after the decimal point and the value of the said number may be adjusted depending on their number). 12. Gravity motor according to claims 1-11, characterized in that a modification is possible by eliminating the fact that the number of engine components is indeterminate and that the upper axis of rotation (4) of the cut cone (1) turns once on the sloping annular disk (15). ) with a rigidly fixed outer cylinder (7) of length zero, ie when this cylinder is not present, rotating about its upper axis of rotation (4) approximately 3.44 times (in the calculations the number of significant figures after the decimal point is not determined and depending on their number the value of the said number can be specified which is very important) the plane forming an angle of 45 ° so that the diameter of the pulleys (89) is 3.44 times the number of possible lower pulleys (110), the upper pulleys (110) and the pulleys (105), equal to the static rectangle, having an oblique equal to half of the outer diameter of the slanting ring disc (15) and the outer cylinder (7), which are similarly connected by straps (103) and (85) respectively and twice the radius of the outer cylinder (7) the lower side ends of the outer cylinder (7) are on one side of the lower and upper pivot axes (4), ie when the distal end of the outer cylinder (7) from the sloping annular disk (15) is frictionally connected to the corresponding lateral circumferential surface of the cone (1), the diameter of the pulley (89) is 6.88 times (possible analogically adjusted number) times the diameters of the pulleys (110) and (105) having the same diameter, and the balance of the rotating parts of the motor being offset by the balancing means (84); after loading the satellite cart (35) with a load (83), in the first case, the upper axis of rotation of the cone (1), due to the winning force, rotates clockwise, in the second case anticlockwise and a specific excess force not required for system operation. the loading charge (83) is applied via a power transmission pulley (6) specifically to rotate the power generator required for such a force, and the like. or the excess power may be automated or otherwise purposefully utilized by computer, respectively; engine component parameters, cantilever (40) abutment support plate (15), friction surfaces of engine components, undetectable, instead of pulleys (110), (105) (89), with diameters depending on the particular outer cylinder (7) ), outer diameter, are specifically calculated, castors, friction casters, pinions with respective belts can be used, and the form of attachment of these belts (number "8", number "0") is not determined, the support wheel (35) of the satellite trolley (35) 40) the location in the oblique annular disk (15), at least when the outer cylinder (7) is less than half the outer diameter of the oblique annular disk (15), may be offset from a vertical plane perpendicular to the sidewalls of the rectangular tube (30); ) (parallel to the vertical plane containing the upper axis of rotation (4) of the cone (1) and its outer circumferential surfaces the ear member (2) being in contact with the friction drive by the outer cylinder (7) at its end, its respective portion, or the bevelled annular disk (15) with its lower half (21), its corresponding portion when the outer cylinder (7) is zero) and having an upper pivot axis (4) of the cone (1) such that the center (44) of the top horizontal hole (43) of the satellite carrier (35) is in that plane; furthermore, a modification is possible in which the inner cylinder (9) is similarly rigidly mounted on the upper hollow axis of rotation (4) of the cone (1) in a freely rotating and non-vertical movement on the vertical axis (88) below and below the cone (1). a conical (1) lower pivot axis (4) having a free-rotating joint (87) rotating freely about one end thereof and terminating at the other end with at least two arcs (108) in a vertical plane (centered by a bevelled annular disk (15)). the center of the axis of rotation (23) being in the plane of said disk (15) having a center of their total length in a horizontal line passing through this center and having a radius equal to the distance from said center of rotation axis (23) of the inclined annular disk perpendicular to the plane of the disk (15) in which the other rhomboidal press wheel (90) rotates freely on its individual, parallel recline a plane of a rotary axis (91) rigidly mounted on the outer circumferential surface of the disc (15) and coinciding with a corresponding radius of rotation of said disc (15) perpendicular to said rotation plane of the wheel (90) located on the inclined annular disc (15). in the plane on its underside (21)) with the upper part of the length to which that wheel (90) is supported by the inclined) rotating disk (15) clockwise, ie the vertical plane containing said upper portion of the two arcs (108) of said joint (87) being parallel to the vertical plane containing the axis of rotation (91) of the press wheel (90) and spaced from one another through the radius of said wheel (90). having a non-adjustable length, the upper pulley (110) being mounted below the cone (1) on the lower axis of rotation (4) of the cone (1) so that it rotates freely about it, cannot move vertically, has a recess (27) and similarly bolted (28) to the joint (87) through a hole (26) therein, the pulley (105) being rigidly secured to its axis of rotation (106), its extension downwards so that the latter pulses (110) and (105) are in one horizontal plane and connected by a belt (103), but instead of an inner cylinder (9), a hollow inner ball may be rigidly mounted in the vertical axis (88) or in the upper axis of rotation of the cone (1) the axes (88) of rigidly interconnected arcs (108) or portions thereof rotating freely in hollow outer hemispheres formed analogously of arcs (108) or portions thereof such that the centers of the spheres coincide and cannot rotate with respect to each other, (4) extending downward, coinciding with the center of the axle (10) and terminating (hemispherically) with the center of the lever (14) of the annular disk (15) such that the spherical top of the upper hemisphere is horizontally cut with the lever (14) that the upper hemisphere does not touch the vertical axis (88) or the upper axis of rotation (4) of the cut cone (1) when the annular disk (15) is inclined at the required angle; furthermore, a modification is possible in which the inner cylinder (9) is similarly rigidly mounted on the lower core (53), on its top, in the freely rotating hollow lower axis of rotation (4) of the cone (1) so that the lower core (53) and the upper side (22) of the sloping annular disk (15) has a rigidly mounted outer cylinder (7) which terminates analogously with a straight rigid joint (107) having at its other end a razor-shaped cone (1) rigidly and similarly inclined. 107) coincides with the common axis of rotation (23) of the outer cylinder (7), the inclined disc (15) and the cone (1) passing through the intersection of the lever (14) and the horizontal axis (10), which is in one horizontal plane the lower lateral forming part (2) of the cut cone (1) and the other cut at the lower axis of rotation of the cone (4) an upper horizontal surface of the cone (1) which is frictionally connected to the lateral circumferential surface of the inclined cone (1) and its lower lateral forming part (2); in the lower pivot axis (4) of the cone (1), above the lower support (5) containing this axle (4) and below the rigid cone (1), which has an aperture (27) in its upper part which prevents the inclined annular the disc (15) being in contact with that lower cone (1), the upper pulley (110) and the joint (24) (with the satellite tube (30) and the trolley (35)) are fixed so that they rotate freely about the lower rotation of the cone (1) the pivot (4) cannot move vertically, is interconnected by a bolt-locking device (28), the upper pulley (110) is a belt (103) (can be connected by a toothed belt (103) as a pinion, etc.) similarly connected to a pulley. (105), and the pulley (89) is frictionally coupled to the lower pulley (110) (as friction or pinion wheels of corresponding diameter), which is similarly rigidly fixed to the lower core (53), which is rigidly tensioned a tensioned transmission gear, (pulley) (6), a load coupling (58) is mounted in the hollow pivot axis (4) of the lower cone (1) so that it rotates freely in that axis and freely rotates in the vertical direction under load (83). the gravitational force rotating the upper pulley (110) about the axis of rotation (4) once anticlockwise, the slanting cone (1) rotates the lower core (53) only 0.414 (the number can be adjusted analogously) once clockwise, the diameter of the pulley, pinion, friction wheel (110) is 2.414 times (the number may be adjusted by the number of significant digits used in the calculations, which is not significant, which is very important) times the diameter of the upper pulley of the same pulley (110) and pulley, pinion (106) and (89) diameters (p the toothed wheels (106) and (89) may have diameters of any size but the same), so that, due to the winning force, the lower core (53) rotates clockwise; furthermore, modifications to the engine are possible without leaving the following frames: radius of cut cone (1), base (3), angle size of the cone (1) side surface forming elements (2) with its base (3), angle size, consisting of a lower wall (33) of the tube (30) with a plane containing the base (3) of the cut cone (1), the seat of the support wheel (40) of the satellite trolley (35) on the plate (47) and the inclined annular disk (15) position of the joint (24) and the respective mounting points of the power transmission gear (6) on the axis of rotation of the cut cone (1), the "exposition" of the horizontal plane of the mirror (101) on the vertical axis of rotation of the cut cone (1) 4) to build the mirror motor (99), the length of the handle (77), the size and type of the force acting on the longer part (78) (force of gravity of the load, human muscle force, mechanical force), engine components (angular s disc (15) with an "L" letter plate (47)) whose individual equilibrium can be offset by balancers (84), the size of the inner (9) and outer (7) cylinders of the sloping annular disk (15), L-shaped plate (47) lengths (49), (50) lengths, belts (85), (103) lengths, cross-sectional shape and engine component parameters, sizes, numbers (satellite rod truck (35) may have a second analogue secured therein by a support wheel (40) and resting on the lower guide wall (33) of the rectangular tube (30) such that the lines connecting the respective horizontal pivot axes (41) of both support wheels (40) to the horizontal axis (59) of the load connector (58). ) or connecting the centers (46) of the respective horizontal holes (38) drilled on said axes (41) with respect to their diameter to the horizontal holes (43) drilled on the axis (59) with respect to their center, forming a right angle and the position with respect to other engine components is not determined in the engine modifications, nor is the design of the engine controlled and the size of the load, the method of loading which may be accomplished by compressed spring, compressed or compressed air, gas and magnetic, electromagnetic forces, etc., and in addition, or in the cut cone (1), which may be replaced by the disc, in its axis of rotation (4) by the removal of the described other engine components mentioned magnetic, electrical, electromagnetic or any other antigravity forces of corresponding power, or waves of appropriate power, intensity, length, defeating or eliminating, counteracting the gravitational forces acting on the charge (part of the cut cone (1) with respect to its axis of rotation (4)) may be directed directly to the respective mechanism (60) as the source of those waves left-handed cone (1); or d the front perpendicular to its axis of rotation (4), half or part thereof, perpendicular to the horizontal plane containing the axis of rotation (4) of the cut cone (1) and bottom up or in any direction such that the cone (1) is cut, rotates, even directly, by neutralizing the action of the respective gravitational forces on said part by anti-gravity material shielding or otherwise, and in the case of possible modifications, the inclined disc (15), upper pulley or caster (110), lower pulley or caster (110) whether the respective diameters of the wheels (105) and (89) are such that any tube (30) rotates counterclockwise or anticlockwise about the axis of rotation of the cut cone (1), the support wheel (40) of the satellite trolley (35). ), resting on the disc (15) or on the base of the sloping cone (1), not in contact with the tube (30), retains initial structural preparation, however, in the case of said modification, wherein the inclined annular disk (15), with or without the flexible (98), lower part (21) of its lower part below the horizontal plane of the outer cylinder (7) or mirror (101) is a friction drive connected to a plane (2) formed by the outer lateral surface of the cut cone (1) and a plane (22) of its upper part above the horizontal plane of the outer cylinder (7) or mirror (101), which is in a plane with the plane of the underside (21) of said lower portion of the inclined ring disc (15), the middle (12) of the rigid axle (10) of the inner cylinder (9), and the center (13) of the inclined ring disc (15); with the point of intersection (19) of the intersection (2) of the cut cone (1) and the mirror cut cone (99) respectively pa (12), (13) and intersected by the axis of rotation (23) of the inclined ring disc (15) (ignoring the thickness of the inclined ring disc (15), i.e. moving only the mirror-cut cone (99) away from the mirror (101) at an appropriate distance reduces engine power), is frictionally coupled to the mirror-cut cone (99), (rigidly secured to the upper vertical hollow mirror cone (99) and to the cut cone (1) ) in the common axis of rotation (4), which may include a mirror removable (57) for the load connection (58) and a rigidly mounted top of the outer cylinder (7), corresponding to the outer surface formed by a (2) such that completed with the rigid axis (10) of the inner cylinder (9) in a horizontal position (then on either end of that horizontal axis (10) depending on which side the rotational axis (4) of the cut cone (1) is to rotate closer to the inner cylinder ( 9), it may also be directly anchored (83) or supported against it from above or below through its load connection (58). ) a horizontal axis (59), which may also have an arc of a corresponding length having a radius equal to (greater) the cross-sectional radius of the roll-shaped axis (10) and integrate the axis (10) such that the axis (10) rotates freely in the arc (59) and the non-functional parts of both cones (1) (99) can be removed for the purpose of reducing the weights of those cones as well as the sloping annular disk (15) whose levers (14), even rotating in the shaft (10) , which may also rotate in the cylinder (9) and other variants of their attachment (14), (10), including rigid ones to one another, the ends may be frictionally driven or rigidly connected to the respective cones (1), (99) the outer side surface members (2)) (not adjustable) or the lever (14) of the inclined ring disc (15) in a horizontal position, which may also be applicable in the example of the engine described; in addition, at least two engines of the same modification in which the horizontal cut cone (1), the sloping cut cone (1), the upper and lower pulleys (110), the pulleys (105) and (89) and the vertical pivot axis of the latter pulleys are used ( 106) (other parts) mounted in the lateral support (5) can be assembled with each other with the transmission gears (6) either directly or through an appropriate belt such that the lever (14) of one of them is horizontal and the lever (14) of the other. , which can also rotate in an axis (10) rotating in an inner cylinder (9) secured to the lower core (53), with a horizontal plane parallel to the base (3) of the horizontal cut cone (1) and the upper incision planes, 45 ° ( not adjustable) but one motor can be used, especially when its lever (14) is horizontal, such that the vertical rotation axis (106) of the pulleys (105), (89) is parallel to the horizontal the axis of rotation (4) of the beer-cut cone (1), after removing its lateral support (5), is fixed in the horizontal cut-off cone (1), in its lower part so that it rotates freely and cannot move vertically; ), which, disengaging its lower pivot axis (4), is rigidly secured to a lower core (53) having an upper pulley (110) similarly secured thereto (freely rotating about it) and which is secured to a lower support (5) below the lower pulley (110) such that the lower core (53) rotates freely in the lower support (5) and cannot move vertically with its horizontal upper plane, its part being rigidly (frictionally actuated) connected to the lateral cut-off cone (1) formed by the lower surface (2) of the surface such that its extension extends through the center of the axis (10) of the inner cylinder (9) in the extension of the lower core (53) and the letter "L" by means of a s-shaped plate (47) with an upper hollow axis of rotation (4) of the horizontal cut cone (1), which is mounted on the upper support (5) so that it (4) rotates freely and cannot move vertically and has an outlet (57) for loading coupling (58) to lock its axis (59) in a satellite trolley (35) and in which the upper core (53) extends freely rotatably and can move vertically, which is in the extension of the lower core (53); a joint of a support wheel (40) of a carriage (35) operated by the gravitational or simulated forces of the load (83) without controlling horizontally the rotational plane of the horizontal cone (1), positioning left or right of the base (3) of the sloping cone (1) (107) or relative to its axis of rotation (23), on the side, the entire structure of the engine, balanced by balancing arms (84), rotates about a horizontal cut. and the axis of rotation of the cone (1), the upper and lower cores (53) counterclockwise or clockwise.