FR2883049A1 - MANEGE FOR GRAVITATIONAL CENTRIFUGAL CONVERTER - Google Patents

Abstract

Device for producing an acceleration which is converted into energy by a converter.It consists of a maneuver whose base (2) of the pillar (3) is a truncated cone which houses the motor (4) which drives in a rotational movement the marquee (5) to which pendulums are suspended, the base of the pillar is assembled with the circular plate (6) of the apparatus, the capital (5) is carried by a rolling device (8) which is arranged at the top (9) of the pillar, each pendulum consists of a sphere (12) full of high density material suspended from a rope (13) which is itself suspended from the capital, the circular plate, the pillar and the capital are made of strong plate The device according to the invention is intended to produce an acceleration which is converted into energy by a converter.

Description

2883049 -1-

  The present invention relates to a modification of the manege employed in the gravitational centrifugal converter.

  The gravitational centrifugal converter is a device that uses centrifugal force, gravity and clocks to produce energy 24 hours a day, 365 days a year without using a natural energy source (fuel) whether it is renewable or non-renewable.

  In the description of the gravitational centrifugal converter, the characteristics of the manege were poorly defined, it concerns the pillar which carries the capital, the method used to drive its rotation, the length of the cord which determines the frequency of the comings and goings of the pendulums, and the sphere full of a high density material, which is suspended at the end of the rope.

  The object of the invention is to redefine the characteristics of the manege use in the gravitational centrifugal converter, to establish the length of the rope which determines the frequency of the back and forth pendulums and the dimension of the components of the apparatus, and that its angular velocity and that of the manges ,.

  According to the invention the force which is converted into energy by the apparatus is produced by differential actions, which are produced by the comings and goings of the pendulums, which must reproduce with a certain frequency, according to the analysis it is the angular parameter which determines the frequency of the comings and goings of the pendulums.

  The angular parameter relates to the comings and goings of the pendulums when they are placed in a centrifuge, if a pendulum is placed in a centrifuge with high angular velocity, the centrifugal force cancels the comings and goings of the pendulum, whereas if it is placed in a centrifuge with a small angular velocity, the centrifugal force does not cancel the comings and goings of the pendulum, between these two extremes there exists an angular velocity (angular parameter) if one increases this angular velocity the pendulum does not have to go back and forth if it is lowered, the pendulum has a coming and going. According to research there are no instruments that can measure the optimal frequency, ie the angular parameter, but according to the analysis the optimal frequency is in a range that spreads between 15 rotations per minute and 30 rotations per minute, or 22.5 rotations per minute.

  2883049 -2- Because in order to obtain the differential actions that produce the acceleration that is converted into energy, the pendulums have to go back and forth for the duration of the rotation of the apparatus in which they are arranged. the optimal angular velocity of the apparatus is 22.5 rotations per minute and with a pendulum whose length of the string is two meters we obtain approximately 21.5 cycles per minute, ie 21 , 5 cycles per minute a cycle equals one goes and one comes, it is the aforementioned length which is used to calculate the dimension of the apparatus and its components.

  Among the accompanying drawings illustrating the description of the invention. Figure 1 is a vertical section of the manege.

  Figure 2 a vertical section of the circular plate and maneges that form the device (gravitational centrifugal converter).

  Figure 3 a top view of the circular plate and manéges it carries.

  Figure 4 bottom view of the device that launches the device and the device that keeps the circular plate on its axis.

  FIGS. 5 and 6 are two drawings showing the movement of the spheres forming the pendulums, about the axis of a manege and the central axis of the apparatus.

  Referring to Figure 1 we distinguish the manege (1) whose base (2) of the pillar (3) is a truncated cone, which houses the motor (4) which drives in a rotational movement the capital (5) to which pendulums are suspended, the base (2) of the pillar is assembled with the circular plate (6) of the apparatus (7), the capital (5) is carried by a rolling device (8) which is arranged at the top ( 9) of the pillar, and its axis is maintained in the axis (10) of the manege (1) by the bearing (11), each pendulum consists of a sphere (12) full of a high density material suspended from a rope (13), which is itself suspended from the capital (5), the circular plate (6), the whole of the pillar (3) and the capital (5) are made of strong sheet whose thickness is suitable in the manufacture of the three aforementioned components.

  2883049 -3- It is the length of the rope (13) which determines the frequency of the comings and goings of the pendulums, the aforementioned length being the distance which separates the center (14) from the sphere (12) of the ring ( 15) to which is attached the rope (13), because with a length of 2 meters a frequency of about 21.5 comes and goes per minute the aforementioned frequency corresponding to about 22.5 rotations by minute which is according to the analysis the angular speed required to obtain the differential actions, the number of rotations to be equal to the number of back and forth, the aforementioned length is used to calculate the dimension of the apparatus and its components C ' is the length of the rope (13) which determines the diameter of the manege (1) and the number of handles arranged on the circular plate determine the diameter of the apparatus (7), the maneuvers are arranged between the periphery (16) of the apparatus and its central axis (17) to enable the sphere (12) which is suspended from the tent (5) to travel around the axis of the manege (10), the diameter of the aforementioned capital is at least 4 meters, and if there are 4 maneuvers arranged on the circular plate the diameter of the apparatus (7) and 10 to 12 meters, the weight of the mass of the sphere (12) is about 500 kilograms and its diameter about 60 centimeters.

  FIG. 5 represents in black the movement of the comings and goings of the four spheres (12) which are suspended from the capital (5), to obtain this movement the aforementioned spheres must make a revolution around the axis of the manege (10) in the same time that the aforementioned axis makes a revolution around the central axis (17) of the device, and in the same direction as indicated by the arrows (18) and (19).

  FIG. 6 represents, in four phases, the movement of the back and forth of the pendulums, during their revolution about the axis (10) of the maneuvers, and the revolution of the aforementioned axis around the central axis (17) of the 'apparatus. During the phase N 1 the action of the centrifugal force produced by the revolution of the sphere (12) around the axis (10) of the maneuver is canceled, that is to say that the sphere loses its angular velocity, c ' is from this phase that the sphere returns to the increasing angular velocity during the phase N 2, to reach its maximum during the phase N 3, it is during the phase N 4 that the mass of the sphere (12 ) which is started continues its course in the direction of the rotation of the apparatus.

  2883049 -4- In order to initiate the centrifugal force the rotation of the apparatus must be initiated by a launcher (20) which consists of two circular strips (21) made of strong plate, which are assembled with the circular plate ( 6) of the apparatus and form a circular frame in which the throwing wheels (22) are arranged, the aforesaid wheels are driven by the electric motors (23), and they rest on the circular track (24) which is arranged on the ground. (25) and carry the entire device.

  The electric generator (26) which converts the acceleration generated by the differential actions into electric current is arranged in a circular passenger compartment (27), the circular plate of the apparatus (7) is connected with the aforementioned generator by the transmission shaft (28, the circular passenger compartment (27) is firmly fixed in the ground (25).

  So that the lateral forces do not drive the apparatus, and that its central axis (17) is maintained above a fixed point, the circular plate is equipped with rolling devices (29) which are fixed under the plate above, around the circular passenger compartment (27) and form a bearing which controls the position of the transmission shaft (28) which drives the electric generator (26).

Claims (3)

  1) Device for producing an acceleration which is converted into energy by an apparatus (gravitational centrifugal converter), characterized in that it consists of a manege (1) whose base (2) of the pillar (3) is a truncated cone, which houses the motor (4) which causes in a rotational movement the capital (5) to which pendulums are suspended, the base (2) of the pillar is assembled with the circular plate (6) of the apparatus (7), the capital (5) is carried by a rolling device (8) which is arranged at the top (9) of the pillar, and its axis is maintained in the axis (10) of the manege (1) by the bearing (11), each pendulum consists of a sphere (12) full of a material of high density suspended from a rope (13), which is itself suspended from the capital (5), the circular plate (6), the whole of the pillar (3 ) and the capital (5) are made of strong sheet whose thickness is suitable for the manufacture of the three aforementioned components.   2) Device for producing an acceleration according to claim 1 characterized in that it is the length of the rope (13) which determines the frequency of the comings and goings of the pendulums, the aforementioned length being the distance between the center (14) of the sphere (12) of the ring (15) to which is attached the rope (13), because with a length of 2 meters a frequency of about 21.5 comes and goes per minute the frequency above, corresponding to approximately 22.5 rotations per minute which according to the analysis is the angular velocity required to obtain the differential actions, the number of rotations to be equal to the number of comings and goings, the aforementioned length is used to calculate the dimension of the device and its components. REVENDIACTIONS   3) Device for producing an acceleration according to claim 1 or claim 2, characterized in that it is the length of the rope (13) which determines the diameter of the manege (1) and the number of rnanéges arranged on the circular plate determine the diameter of the apparatus (7), the maneuvers are arranged between the periphery (16) of the apparatus and its central axis (17), in order to allow the sphere (12) which is suspended from the capital (5) to travel around the axis of the manege (10), the diameter of the aforementioned capital is at least 4 meters, and if there are 4 maneuvers arranged on the circular plate the diameter of the apparatus (7) and 10 at 12 meters, the weight of the mass of the sphere (12) is about 500 kilograms and its diameter about 60 centimeters.   3) Device for producing an acceleration according to any one of the preceding claims characterized in that Figures 5 and 6 show in black the movement of the comings and goings of the four spheres (12) to obtain this movement the aforementioned spheres must perform a revolution around the axis of the manege (10) at the same time as the aforementioned axis performs a revolution around the central axis (17) and in the same direction as indicated by the arrows (18 and 19).