FR2894706A1 - Apparatus for checking the existence of gravitational centrifugal acceleration, as in a gravitational centrifugal converter, comprises a motorised rotating head with two carousels, each with four suspended pendulums - Google Patents

Abstract

Apparatus for checking the existence of gravitational centrifugal acceleration, comprises a horizontal reinforced circular head forming a pulley driven by a motor and a driving belt, carrying two carousels mounted on two truncated conical or tubular columns fixed to the head, with four pendulums suspended from the cap on each carousel. Apparatus for checking the existence of gravitational centrifugal acceleration suggested in the description of a gravitational centrifugal converter, comprises a horizontal circular head (1) in the form of a relatively thin drum of medium plate, reinforced with two longitudinal beams (2) of heavy plate, forming a pulley driven by a motor (3) via a pulley (4) connected to (1) by a driving belt (5), bearing two carousels (6) with caps (7) mounted on two columns (8) in the form of truncated cones or tubes fixed to the head (1), with four pendulums (9) suspended from each cap (7).

Description

The present invention relates to an apparatus for verifying the existence of

  the gravitational centrifugal acceleration proposed in the description of the GRAVITATIONAL CENTRIFUGAL CONVERTER.

  The gravitational centrifugal converter is an invention, the purpose of which is to employ centrifugal force, gravity and pendulums to produce energy without resorting to the use of a natural energy source which it either renewable or non-renewable.

  According to the analysis the gravitational centrifugal converter starts to produce energy, from a certain angular velocity which must correspond to the frequency of the back and forth pendulums which are placed in the converter, the frequency of the comings and goings being determined by the angular parameter, the angular parameter being the angular velocity which lies between the angular velocities which cancel the back and forth pendulums when they are placed in a centrifuge and those which do not cancel them.

  According to the analysis, the optimum frequency, ie the frequency that could produce the greatest amount of energy, lies at the center of a range that ranges between 10 and 35 rotations per minute for the converter, and 10 and 35 back and forth for pendulums, outside this range the acceleration would not be sufficient to compensate, among other things, the aerodynamic forces that oppose the movement, taking into account these data the optimal frequency is found at about 22.5 back and forth per minute to get this frequency the length of the pendulum string should be about 2 meters and the dimension of the converter exceeds 10 meters in diameter, things that make it very expensive to finance an experiment .

  The object of the invention is to construct a reduced model of the gravitational centrifugal converter, to check whether there is an acceleration, using the same means as in the aforementioned converter, but whose financing would be very small.

  According to the invention it is possible to construct a reduced model of the gravitational centrifugal converter for a relatively low price, which would make it possible to check whether there is an acceleration, although it is not sufficient to produce a movement without assistance, the The frequency to be selected is a frequency that is greater than 35 cycles per minute, the aforesaid frequency being achieved with a chord approximately 75 centimeters in length, and it is the length of the chord which determines the dimension of all the components of the apparatus, which consists of a circular plate on which are arranged two maneuvers and pendulums which are suspended under the capitals of the mangaes, the rotation of the capitals being synchronized with the rotation of the circular plate, by pulleys which are connected to each other by chains.

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

  Figure 2 a top view of the device.

  Figure 3 a top view of the rotational correction pulleys.

  Figure 4 and 5 are two views of the longitudinal members that reinforce the circular plate that carry manéges.

  The circular plate (1) is arranged horizontally, it has the shape of a relatively thin drum made of medium sheet, it is reinforced by two longitudinal members (2) made with strong plate, the aforementioned plate forms a pulley which is driven in a rotational movement by a motor (3) the pulley (4) of the aforesaid motor is connected with the pulley formed by the circular plate (1) by a transmission belt (5) which transmits the driving force produced by the motor (4), the circular plate (1) carries two handles (6) whose two capitals (7) rest on two columns (8), which have the form of a truncated cone or a tube, the aforementioned columns are fixed on the circular plate, four pendulums (9) are suspended under each of the capitals (7).

  Each of the capitals (7) is driven in a rotational movement by an orbital pulley (10) which rotates about a central pulley (11), the aforementioned pulley is disposed on the central pillar (12) which is fixed in the ground (13), the orbital pulley (11), the central pulley (10) and the two rotation correcting pulleys (14) are connected to each other by a chain (15). The role of the two pulleys (14) is correcting the rotation of the orbital pulley (10) so that it rotates in the same direction as it rotates around the central pulley (11), the orbital pulley (10) is disposed on the shaft (16); ) which passes in the center of the column (8) and drives the capital (7) in a rotational movement. The circular plate is carried by a central bearing (17), which is arranged at the top of the central pillar (12) and the two capitals (7) of the two maneuvers (6) are carried by two bearings (18) which are arranged at the top of the two columns (8), four pendulums (9) are suspended under each of two maneuvers (6), each pendulum (9) consists of a sphere (19) suspended at the end of a rope (20) which is attached to a ring (21) allowing the sphere (19) to come and go freely.

  It is the length of the cord (20) which determines the size of all the components of the apparatus, the aforesaid length is equal to the distance which separates the center (22) of the sphere (19) from the point of the ring (21) on which the rope (20) swings, the acceleration is proportional to the mass of the sphere (19) and the force which opposes the movement is proportional to its volume, so it is necessary that the sphere be made with a high density material, to give the sphere as small a volume as possible for maximum weight.

  Manéges (6) are arranged between the central axis (23) of the circular plate (1) and its periphery (24), the spheres (19) which are suspended from the capitals (7) must perform their revolution around the shaft (16) in the same direction and at the same time as the aforementioned shaft revolves around the central axis (23), to obtain this synchronism the central pulley (11) and the two orbital pulleys (10) must to have exactly the same dimension, the direction of the rotation of the maneuvers (6) on their axis (24) as well as the rotation of the circular plate (1) on its central axis (23), are indicated by the arrows (26 and 27) . The frequency which has been chosen in order to calculate the size of the components of the apparatus is 43 come and go per minute, which is obtained with a rope (20) of about 50 centimeters in length, the diameter of the two capitals the length of the rope, that is to say 100 centimeters and the distance between the two capitals (7) 50 centimeters, 30 things which give to the whole of the apparatus a diameter of 250 centimeters, the weight of each of the spheres is 50 kilograms and they are full of a material such as iron, their volume is 50: 7.8 = 6.2 liters.

  The method used to check for acceleration consists of several tests, which are made at different angular velocities which are increasing, the first test being made with an angular velocity of 8 rotations per minute for the apparatus on its central axis (23), the 2894706 -4-

  second test 13 rotations per minute, the third test 18 rotations per minute, the fourth test 23 rotations per minute, the fifth test 28 rotations per minute, the sixth test 33 rotations per minute, the seventh test 38 rotations per minute, the eighth test 43 rotations per 5 minutes. If there is an acceleration it will reach its maximum when the angular velocity of the apparatus will be equal to the frequency of the comings and goings of the pendulums, that is to say 43 rotations per minute for the apparatus, if the frequency of the va and comes from the pendulums is 43 cycles per minute, if there is no acceleration the amount of energy required to drive the rotation of the apparatus will go up to reach its maximum at the eighth test, s' there is an acceleration the amount of energy to cause the rotation of the apparatus could stabilize or even diminish, but it is likely that unattended movement can be achieved with the proposed frequency

  If the driving force that drives the rotation of the apparatus is produced by an electric motor, it is the amount of energy used by the motor during each test, which determines whether there is an acceleration.

Claims (6)

  1) Apparatus for checking the existence of the gravitational centrifugal acceleration proposed in the description of the gravitational centrifugal converter, characterized in that it consists of a circular plate (1) arranged horizontally, it has the shape of a relatively thin drum made with medium sheet, it is reinforced by two longitudinal members (2) made with strong plate, the aforesaid plate forms a pulley which is driven in a rotational movement by a motor (3) the pulley (4) of the aforementioned motor is connected with the pulley that forms the circular plate (1) by a transmission belt (5) which transmits the driving force produced by the motor (4), the circular plate (1) carries two maneuvers (6) whose two capitals (7) rest on two columns (8), which have the form of a truncated cone or a tube, the aforementioned columns are fixed on the circular plate, four pendulums (9) are suspended under each of the capitals (7) .   2) Apparatus for checking the existence of gravitational centrifugal acceleration according to claim 1 characterized in that each of the capitals (7) is driven in a rotational movement by an orbital pulley (10) which rotates around a central pulley (11), the aforesaid pulley is disposed on the central pillar (12) which is fixed in the ground (13), the orbital pulley (11), the central pulley (10) and the two rotation correcting pulleys (14) are connected to each other by a chain (15) the role of the two pulleys (14) is to correct the rotation of the orbital pulley (10) so that it performs its rotation in the same direction as it performs its revolution around of the central pulley (11), the orbital pulley (10) is disposed on the shaft (16) which passes through the center of the column (8) and drives the capital (7) in a rotational movement.   3) Apparatus for checking the existence of gravitational centrifugal acceleration according to claim 1 and claim 2 characterized in that each pendulum (9) consists of a sphere (19) suspended at the end of a rope (20) which is attached to a ring (21) allowing the sphere (19) to come and go freely, and that it is the length of the rope (20) which determines the size of all the components of the apparatus, the aforesaid length being equal to the distance between the center (22) of the sphere (19) and the point of the ring (21) on which the rope (20) is swinging.   4) Apparatus for checking the existence of gravitational centrifugal acceleration according to any one of the preceding claims characterized in that the maneuvers (6) are arranged between the central axis (23) of the circular plate (1) and its periphery (24), the spheres (19) which are suspended from the capitals (7) must perform their revolution around the shaft (16) in the same direction and at the same time as the aforementioned shaft performs its revolution around the central axis (23), to obtain this synchronism the central pulley (11) and the two orbital pulleys (10) must have exactly the same dimension.-7- CLAIMS   5) Apparatus for checking the existence of gravitational centrifugal acceleration according to any one of the preceding claims characterized in that the frequency which has been chosen to calculate the size of the components of the apparatus is 43 comes and goes by minute, which is obtained with a rope (20) of about 50 centimeters in length, the diameter of the capitals twice the length of the rope, that is to say 100 centimeters and the distance between the two capitals (7) 50 centimeters, things that give the whole device a diameter of 250 centimeters, the weight of each of the spheres is 50 kilograms they are full of a material such as iron, their volume is 50: 7,8 = 6.4 liters.   6) Apparatus for checking the existence of the gravitational centrifugal acceleration according to any one of the preceding claims characterized in that the method used to check whether there is an acceleration consists of several tests, which are made at angular velocities The first test is made with an angular velocity of 8 rotations per minute for the apparatus on its central axis (23), the second test 13 rotations per minute, the third test 18 rotations per minute, the fourth test. test 23 rotations per minute, the fifth test 28 rotations per minute, the sixth test 33 rotations per minute, the seventh test 38 rotations per minute, the eighth test 43 rotations per minute.