FR2671832A1 - DEVICE HAVING DIFFERENTIAL CENTRIFUGAL FORCE. - Google Patents

Abstract

The invention relates to a device comprising a plurality of groups of movable forearms which rotate about a fixed axis. Arms holding masses (11) rotate at the extremity of said forearms. The arms (8), driven by gears or electric motors, effect the number of revolution per second than the forearms (15). The arms rotate in a direction opposite to the rotation direction of the forearms and one half of the forearms rotates in a direction opposite to that of the other half. Thus, at each rotation, the arms and the masses at the extremities thereof are periodically in the extension of the forearms while other arms are superposed to the forearms with their masses being behind the fixed axis. These synchronized differential motions generate forces which may be used essentially to displace vehicles without bearing on air, water or the ground, and to convert thermal energy into mechanical energy.

Description

 The present invention relates to an autonomous motor device and thermomechanical converter with differential centrifugal force.This device makes it possible, when it is supplied with energy, to move in space the vehicle which serves as its support, with or without load and without This device allows, in addition, in a variant of mounting of its constituent parts, to produce mechanical energy from the ambient thermal radiation. Both variants, engine and converter, can be mounted on the same vehicle.

 Apart from the rocket, all the known engine devices require, for moving the vehicle that contains them, a material support, be it solid ground or gaseous air.

And the so-called "anti-gravitational" machines, with the exception of rocket engines that eject gases, have never risen in space from the Earth. With regard to the known attempts of driving wheels associating masses with leverage arms, integral with the axis, and made longer on one side of the axis than on the other, they have a handicap which consists in the need to raise more masses on the short side than on the long side; which prevents the release of a sufficiently different centrifugal force between two diametrically opposite masses.

 The device according to the invention makes it possible to remedy, with regard to the differential centrifugal force, the aforementioned drawback. It is constituted, in its simplest version, of two axes of which one is fixed and the other mobile.A forearm, of form and any matter but of finite length, is pierced with a hole to the one of its ends to be rotatable, in the plane of its length, about the fixed axis. A second hole is convenient, at the other end of the forearm, to allow the attachment of the second axis.

perpendicular to the plane of rotation of the forearm. This second axis rotates at the same time as the forearm, but it is integral with the latter and does not rotate itself relative to the forearm. On the second axis, attached to the extremity of the forearm, turns in the same plane as the forearm and in relation to this forearm. the actual arm of the device. This arm is, like the front arm of shape and of any material but rigid enough to withstand important centrifugal forces. The length of the arm is always slightly smaller than the length of the forearm to allow the operation of the device. The arm is pierced with two holes: one at each end. One of these holes allows the arm to rotate around the movable axis at the end of the forearm.

The second hole of the arm serves to fix the mass that will produce when the device is set in motion. the differential centrifugal torus the motor and, in a particular configuration, the transformation of radiant energy into mechanical energy. The arm and the forearm do not rotate at the same speed, but at the same frequency. ie when the forearm has made a complete turn around the fixed axis, the arm has also been a complete turn around the movable axis. The arm and the forearm always rotate in the opposite direction l When the device consumes energy, that is to say when it moves its support for example, the forearm is set in motion by a conventional motor, thermal or electrical.

This basic version is illustrated by Figures 1,2,3 and 4.

In these figures, for clarity of the drawing, the organs are shown in very schematic sections.The support (1) of the fixed axis (2) is a U-shaped stirrup of which only one branch of the U is represented.The fixed axis (2) is integral with the support bracket and a circular track (3) centered on this fixed axis.Une wheel (4), secured to the forearm (5), via an axis (6) movable in the forearm, rotates, by friction, on the fixed circular track (3) .The wheel (4) has the same outer diameter as the fixed circular track (3) and drives, also by friction but in opposite direction, another wheel (7) integral with the arm (8) and thus rotating, as the arm (8) around the movable axis (9) .All the wheels (3,4 and 7) have the same diameter so that the arm (8) and the forearm C5) each perform the same number of revolutions per second. The friction drive system of the wheels between them can be replaced in other variants of the invention. invention by a gear or loom drive lie when the forearm is very long for example and it is cheaper to provide standard manufacturing pulleys. It is only necessary that the movable wheel (4) has the same diameter as the wheel or the fixed track (3). Thus the axisCS) can carry, in other variants of the invention another pulley whose diameter will correspond to the diameter of the pulley (7) ;; and it will synchronously drive in reverse this pulley (7) by friction, by gears, by belt, by chain or by an electrical connection device known as the electric shaft. connection of the forearm to a conventional thermal or electric engine is provided by a fourth foal (10) secured to the forearm (5) and shown in the figures by a dotted circle inside the track The pulley (10) for driving the forearm, which may be an electric motor rotor, is also the driving pulley of the use, when the device invented provides energy instead of absorbing it.The mass (11), at the end of the arm (8) is represented felt by a small black cylinder.

 Figure 1 shows the position of the arm (8) and the forearm (5) at the time of starting the device, they are superimposed, the arm folded in front of the forearm in the low position below the arm fixed axis (2). This figure 1 shows that the arm (8) can not be as long as the forearm (5) because at the end of the arm, the mass (ii) would hit the fixed axis (2).

Figure 2 shows the respective positions of the arm and the forearm after a quarter turn of the assembly. The centrifugal force, developed by the arm (8) and forearm (5) and massC11 assembly, has increased with respect to the starting position illustrated in FIG. 1 and is always directed upwards from the FIGS. 3 represents the respective positions of the brast8) and of the forearm (5) after a half turn of the assembly. The arm and the forearm are in the extension one of the other.The mass (11) reaches its maximum distance from the fixed axis (3) and the centrifugal force is maximum. FIG. 4 shows the respective positions of the arm (8) and the forearm ( S) when this set is three-quarter turn.On this Figure 4, the mass (11) occupies with respect to the axis, a symmetrical position of the position it occupied in Figure 2, without changing the direction centrifugal force, but decreasing it with respect to FIG.
The direction of rotation of the device is indicated in all the figures by curved arrows. The direction of the differential centrifugal force is indicated by straight arrows.

Despite a constant sense of differential centrifugal force obtained by this first version of the invented device, the variations, sometimes increasing and sometimes decreasing the centrifugal force, cause a defective operation of the assembly which moves in space while spinning on itself in the direction of rotation of the forearm.

To overcome this defective operation, a preferred version of the invention consists in associating, face to face two elongated forearms, as shown in Figure 5 which is a section parallel to the fixed axis (2). elongate forearms (15) are twice as long as previous figures
This length of forearm is doubled, to be able to drill a hole in the center and a hole at each end. Thus, these new elongated forearms will each be provided with two arms (8). An arm (8). ) at each end of each elongated forearm (15) .These arms (8) have a length slightly less than half the length of the elongated forearm (15) for the reason already indicated.In addition to the pulleys (3,4,7 and 10), a new pulley or sprocket 16) is fixed on the other arm (8) of each elongate forearm (15) .This second arm (8) rotates, with its pulley (16) on a second movable axis (9).

The central hole of the elongated shafts (15) is traversed by the fixed axis (2) and, during operation of the device, an endless belt or chain (17) joins the two pinions (7) and CsS), which have same number of teeth or same diameter so that they have the same number of revolutions per second and that they have synchronized positions relative to the elongated forearm (15). brast83 is in the prolongation of the elongated forearm15), the other arm (8) is folded exactly above the part of this forearm (liquid is below the fixed axis (2) of this way, it is not necessary to provide a second wheel or intermediate gear (4) :: but it is then necessary to provide a static balancing mass on the part of the extension shaft (15) which does not carry the intermediate pulley (4) and as shown in Figure 5. All the masses attached to the arms are identi that the forearm elongest (15) facing each other. In one of the forearms 15) is driven by a conventional motor and by means of the pulley (10) .1l entaine.a turn, but in the opposite direction the second elongated forearm 15) either by means of a conventional electromagnetic servo system or by a double gear or friction angle gear as shown in FIG. 5.

In this figure, each of the elongated forearms (15) is secured to one of the axial gears (12) of the double angle transmission.
These axial gears (12) fixed on the elongate forearms (15) face each other, on either side of the intermediate gears are perpendicular to the axis fixeet2) .The intermediate gears (13) face themselves, from and other of the axis fixeet29.et and rotate freely on a axis auxiliary (14) perpendicular to the fixed axis (2) .Les two perpendicular axes, (2) and (14) are both fixed because rigidly linked to each other and to the support (1)
The fixed axis (2), however, has the possibility of rotating, relative to the support (1) and under the effect of a conventional non-reversible mechanical control, for example tangent wheel and worm, to guide the production of differential centrifugal force in the chosen direction. As shown in FIG. 5, when the arms (8) of the extended forearms (15) are aligned on these forearms, there still remains, in this second version of the invented device, a risk of tilting of the support in one direction. or in the other of the movements of the forearms.

To make the operation of the device even more stable, under all walking conditions, a third variant of the invented device consists in fixing, on each of the elongated forearms (15), which turn in opposite directions, one or more other sets of forearms. elongest15) and arms (8).

The elongated forearms thus superimposed and crossed are regularly shifted. relative to each other, 90 when there are two or 60D when, for example, there are three, on each side of the double angle gear.

Thus the centrifugal force differential and uni-directional, produced by the device, is manifested smoothly and without risk of tilting of the support in a different direction from that of the direction chosen relative to the support. To bind with certainty the movements of the arms between them and to ensure the phase shift of their movements opposite to those of the forearms, the pinions (16) of the arms (8) of each elongated forearm group (15), each side of the double angle, are joined together and the motor pinion (7) by a belt or a chain Ga, or by an electro-magnetic servo
Figure 5 shows such an assembly with two forearms (15) elongated on each side of the double angle gear.

These elongated forearms (15) are offset from each other by 90 and the operation of their respective arms is similar so that, at each quarter turn, the positions of the arms (8) are those shown in this figure 6. The arms 83 who face each other on either side of the double angle gear always occupy the same position with each quarter turn that moment. when viewed, perpendicular to the fixed axis (2) they overlap and that is why Figure 6, which is a schematic view perpendicular to the fixed axis (23, shows only four arms. Between quarters of turn, the positions of the eight arms are offset but symmetrical. The differential centrifugal force produced by the invented device is a function of the dimensions of the arms.

the number and the importance of the masses, all identical. It is also and especially a function of the rotation frequency of the assembly. The force produced by each mass varies, during the rotation, from CF = mD 51. (R + R)} to (F = m, G12 .R) .R representing half the length of the elongated forearm, and R representing the length of the arm.

A high frequency of rotation makes it possible to reduce the dimensions of the device and the importance of the masses.

The variant generator or thermo-mechanical converter with differential centrifugal force, which is also the fourth variant of the device, is illustrated in FIG. 7.This last variant uses the same elements as the third variant, illustrated by FIG. 6. But on this 7, the arms (8) of the elongated forearms (15) facing each quarter of a turn and rotating in opposite directions, two by two, on each side of the double angle gear, are no longer superimposed at no time of displacement; unlike 9 what happened in the third variant.On this figure 7. during the reverse movement of the sets, the fictitious lines that go from the movable axes (9) to the masses (11) are in opposite directions, on the one hand and on the other. other than the double angle gear, and the differential centrifugal forces are also in the opposite direction to the right and to the left of the figure.If a driving force, external to the device, acts on the pulley (lO) and if the two differential centrifugal forces are equal, there can not be movement of the support (1). The low tilting torque, which manifests itself perpendicular to the length of the fixed axis (2) and which results from the non-zero distance separating, on the fixed axis, forearms rotating in the opposite direction, is canceled by arranging on this fixed axis (2), and in the direction of the length of this axis, two device similar to that just described. This fifth variant balances all the lateral rotation torques, because, following the last forearm (15) of the first device which rotate in a certain direction on the fixed axis (2), the forearms (15) are ) of the second device which rotate in the same direction.Thus extreme forearm groups (15) which rotate in the same direction, but which belong to two different devices, are separated by two other groups of forearms ( 15vcentrals which both turn in the opposite direction to the direction of rotation of the forearm groups (15Bextremes and which also belong to two different devices. One of these devices can be an autonomous motor device and the other device a converter thermomechanical like that shown in Figure 7.On this Figure 7, two circles in broken lines represent, when the support remains fixed, the figures described by the masses in space at each complete turn of the forges lengthens s (15) .The vertical lines in phantom lines (19) represent both the direction of the gravitational field attraction force and the separation of the field input and output fields. Without movement of the entire system, the similar masses thus positioned in the figure can not move, that is to say, initiate a descent. because, because of their connection with the elongated forearms15), they would cause an equivalent rise of 17 forearms and thus their own ascent. On the other hand, if the forearms (15) are set in motion, in the direction of the curved arrows, the device will continue to rotate because the moment of the masses entering the field is constantly greater than the moment of the masses which Indeed, during the rotation of the device and because of the centrifugal force that binds arms and forearms, the moment of the masses (11) is no longer the product of each mass (11) by the length of the arm (8), but, depending on the rotational movements of the sets, the product of each mass (11J by the length of the arm gradually increased by half the length of the forearm and then gradually decreased by the same length This is shown by the force component diagrams shown at the top of Figure 7 on the left-hand side and in the center. The horizontal arrows represent the local centrifugal force. The vertical arrows represent the moments of the local forces of attraction exerted on them. masses (11) The resultants of these moments are unequal on both sides of the lines, 19 which separate, each, the zone where the masses (11) enter the field, from the zone where the masses leave the field. This imbalance maintains the rotation of the device, rotation initially initiated by an action outside the device and via the pulley10) .This is the effect of the differential centrifugal force; abbreviated: Effect FCD

The action of radiations, of all wavelengths on the masses, always results, finally, by a heating of the bodies. The masses thus catch the radiations and warm up.

To warm a cold body, simply shake it in the air and, as it warms up, this body expands. Conversely, a body that loses energy contracts and therefore cools.

A body in motion, under the effect of an acceleration or which enters a field (which is equivalent to an acceleration produced by the force of the field), contracts all the more as the acceleration is strong. It therefore releases, as a result, a potential energy that becomes visible only at deceleration, by shock, friction or when the mass moving provides a job. Conversely, a body that comes out of a field expands and absorbs energy because you have to overcome some resistance to start the movement. In the current practice of a wheel with a concentrated mass at a location on the periphery, when the mass passes from the high position to the low position, it supplies energy by pressing this mass on the radius which joins the mass. to the axis. Conversely, when the mass passes from the low position to the high position, it absorbs energy by traction of this mass on the radius which joins the mass to the axis. The energy passes mechanically, through the moving bodies. by these simple, elementary, fundamental phenomena, which are called compression, traction, torsion.

So that the mass which leaves the field does not absorb, by means of the traction which it exerts on the radius of the wheel, all the energy which it had given, by compression, while entering into itself. In the field, it is necessary for a particular assembly to cut the amount of mechanical traction that goes from the mass to the center of the wheel, passing through the radius. This is one of those theoretical assemblages realized by the invention device examining the diagrams. The composition of the forces shown in FIG. 7 shows that the diagrams at the center of the figure have a resultant of compression for the masses (11) which leave the field, and with respect to the fixed axes (2). Normality and according to the above-mentioned example of a single wheel with a mass at the periphery, the resultant, with respect to the center of the wheel, of a mass which rises from below upwards, is always a traction force. The invented device, as a result of the length variation of the lever arms, allows, without modifying the ratios of the masses on either side of the fixed axis (2), to raise a mass while preventing this mass of to take from the mechanical system that raises it as much energy as it provided him when entering the field. The mass (11) which has contracted by losing energy and thus cooling downhill is going to have to to expand and heat upwards, to borrow, by conduction, convection or radiation, energy from its immediate environment and more specifically from the air in which the device is moving.When the field in which the device is the gravitational field, the rotation frequency of the device is not very large and the cooling of the masses (11) little marked. this cooling is even less marked when the device runs empty and does not provide energy for outdoor use. The image of liquids that vaporize at room temperature and cool especially as their relaxation is accompanied by a production of work by pressing a piston in a cylinder for example, the cooling of the mass (11) which enters a field, is all the more marked that the device invented provides its maximum energy at the expense of the speed which decreases.A vacuum, for a given length, arm number, mass size and field nature, there is a corresponding limit speed.If the load becomes too large, the device stops.The maximum energy that can be produced is a function of the lengths of the arms (S), the forearms C15), the importance of the masses (11) and the nature of the field.To produce more energy without having too large arms and masses too much imp In the sixth variant of the invented device, the masses (11 are magnets or electromagnets). In this variant six, the dipositive is similar. to that of variant four, except for the masses (11) which are moving magnets so that their magnetic axes are always parallel to the direction of the magnetic field produced by a hollow coil or by a large fixed magnet secured to the support .

In FIG. 7, the hollow spool is represented by a rectangle (20) .The invented device, in this variant six, is placed at the inlet of the hollow spool so that the movable magnets11), when they are lowered, always meet a magnetic field.An arrow on the masses (11) represents the mobile magnets.Un such device is either a transport vehicle or a mechanical force generator.

 But the simple balancing of the differential centrifugal forces on either side of the fixed axis (2) with groups of arms (8) and forearms (15) in opposition of orientation, is not sufficient for that the device provides an appreciable work, because the acceleration of the masses. in the direction of the force, is immediately followed by a deceleration of the same progressiveness. In addition to the different position of the arms (8) and the forearms (15) the invented device, in its variants intended for the conversion of thermal energy into mechanical energy, also has additional members and this is shown in FIG. 7. In this FIG. 7, there is no mass (11 ) at the end of the arms (8) which lie below the horizontal line joining the arms (8) which are. at the same time, in the extension or superimposed on their forearms (15) In the variants, of the device with differential centrifugal force 1c, intended for the conversion of thermal energy into mechanical energy, the masses C1) must be able to be detached from the ends of the arm or they are momentarily place.Leur fixing, at the end of the arms (8), must be removable.

Fastening systems are conventional systems which may be, for example, mobile cuvettes or pneumatic or magnetic suction cups. Figure 8 shows a pivoting cradle attachment the mass (11) being in the cuvette.

The purpose of this mobile attachment is to allow the mass to leave the end of the arm (8), when the latter is in the extension of the forearm (15). At this time the acceleration the mass (11), located at the end of this arm, is maximum.

The massetll) must then be transferred to the periphery of a single drum pulley (25> .This drum pulley (25) rotates on an axis (22) integral with the support (1) common to the entire device, but it is mechanically connected. to one of the forearm groups (15) which rotate in one direction or the other, depending on whether it is placed to the right or to the left of the device, so as to turn itself in the same direction and at the same frequency of rotation as the forearm group to which it is connected.The classical mechanical links between forearm and pulley drum (25ss are not shown in Figure 7 so as not to overload the drawing.There are two drum pulleys (25) per energy converter device. In variant five or there are normally four pulleys (25) since there are four forearm groups (15). Each pulley drum (25) is placed between two groups of avant-brast15) which turn in the opposite direction as shown in Figure 8.A periphery each drum pulley (25) is regularly spaced, as many swivel bowls as there are arms in a single system, rotate in the same direction. When an arm (8) is in the extension of his forearm. it is also perpendicular to the direction of the gravitational field or the magnetic field and it is at this point that fixed cams, integral with the support (1) and not shown, for the clarity of the drawings of FIGS. 7 and 8, act on the fins (23) of all the bowls (21)) to counteract the force of the rappelt springs-4) .The positions of the bowls are, then, as shown in Figure 8.La massage 11>. which is at the end of the arm (8) .dans the extension of the forearm (15) can roll, by falling dramatically, on the fixed bridge (26) and slip into the bowl (21) which is in front on At the same time, the mass (11) which is in another bowl, diametrically opposed, at the periphery of the drum (25), can roll likewise, by taking another fixed bridge (26) towards the bowl. (21) of the arm (8) replicated on his forearm (15) .Les masses (11) pass, with the minimum energy expended, a system of arms that rotate in one direction, the system of arms that turn in the opposite direction and realize, in a simple manner, their continuous transfer, from the maximum energy position to the starting energy position of the acceleration, without changing the direction of the centrifugal force.In fact, the condition of operation of the device for converting thermal energy into mechanical energy being that the contraction of the masses never stops; that is, not only does the acceleration of a mass never become zero, but the centrifugal force acting on a mass (11) is always greater, when the device is started, by the force of attraction of the field in which it is dipped, otherwise the device will stop rotating
The radius of the pulleys drum (25) is substantially equal to the length of the breasts so it is substantially less than half the radius of the accelerated mass system, which is equal to the length of an arm (8) increased by half of the length of the forearm. Due to the conservation of the kinetic momentum, a mass accelerated to the maximum by the arm8) and forearm (15) system and which falls on the periphery of the pulley drum- (25eva tend to maintain its kinetic momentum and accelerate, the pulley drum (25) up to twice the rotation frequency of the arm and forearm system on which the mass (11) was originally linked.It is this phenomenon that allows the it forces the device to its normal speed and from an external force applied to the pulley (10) and sufficient to start, even slowly, the invented device.

 Indeed the kinetic moment is equal to JQ and 3. moment of inertia being equal to mR, the smallest radius of the pulley drum (91) causes its maximum acceleration when a mass is transferred to it. Maximum acceleration compatible with the losses of energy due to work supplied to the outside and to frictional heating inside the device itself.

When the device for converting thermal energy into mechanical energy operates, it behaves. Near the ground and from the point of view of energy production. Like a satellite attracted by a planet but which does not strike this planet because its centrifugal force is sutfisammant important. The satellite bypasses more or less the planet and uses the energy acquired during the approach to move away by ricocheting on other planets or to return more or less early towards the same planet. The analog of the passage of the perigee at apogee in the invented system being the transfer of the masses (11) from the maximum centrifugal acceleration (perigee) to the basic centrifugal acceleration (apogee) via the drum pulleys (25)

Claims (2)

1) Motor device for moving a vehicle in space, without this vehicle leaning on the air, and also device for converting thermal energy into mechanical energy, characterized by synchronized movements of arms and forearms; (8) forearm (15), each arm (8) being secured to the forearm (15) via an axis (9) implanted at one end of the front arm, a mass (11) being fixed to the end of each arm (8), the forearms (15) rotating, via a central hole, about a fixed axis (2) integral with the support (1); the arms (8) rotating about the movable axis (9) in the same plane as the forearms, performing the same number of revolutions per second as these forearms (15), but with relative positions set such that the way that each arm (8), which always turns in the opposite direction of its forearm (15) is, at a given moment, in the exact extension of the forearm which carries it while the other arm ( 8) is exactly superimposed on the same forearm (15); the synchronization of all these movements, between the arms (S), all of the same length, the forearms (15), all of the same length, and relative to the fixed axis (2), integral with the support (1) , being ensured: either by toothed wheels and chains, or by pulleys and belts, or by servo electric motors; half of the forearms (15), when there are several, rotating in the opposite direction of the other half to: either balance the tangential forces and leave only the differential centrifugal forces them, in the use of the device invented as an autonomous motor: the periodic differential centrifugal forces then pulling the support (1) as well as the vehicle which is moored to it in the selected direction, with possible modification of the direction of traction by relative and non-reversible displacement of the fixed wheel ( 3) and the fixed axis (2) with respect to the support (19. This relative and non-reversible displacement which constitutes the control of the device is also a modification of the direction of the centrifugal force which differs the direction of which in the space is that represented by the direction of the arms (8) of each forearm (153Where they are concordance :: that is to say when one of the arms t8) is superimposed on the forearm ( 15) and the other in its extension; to balance the differential centrifugal forces in the use of the device as a thermomechanical generator, when the assembly (s) is set in motion and the continuous modification of the length of the lever arm constituted by the length of the forearm ), between fixed axis (2) and movable axis (9). to which is added or subtracted the length of the arm t8) which carries the mass (11). brings the continuation of the movement because at the moments when these arms of the lever are the longest or the shortest. they are set to be as perpendicular to the direction of the field. the mass tii being at the end of the arm in pro ement of its forearm and rotating in a certain direction being transteree end of an arm turning in opposite direction and being bent folded on his forearm. by the interminable removable fasteners and drum pulleys mechanically connected to the forearms so that the rotation frequencies are equal and that, parallel to the attractive field, for a same distance of entry and exit, a time thick, or a temples 2) Device according to claim 1, characterized in that in a drive of the arms (8) and forearms (15), by gears or pulleys, a wheel (4) integral, by a axis (6), of an elongated forearm 15), rotates around a wheel or circular track (3) of the same diameter, this wheel (3) being fixed because integral with the fixed axis (2> and centered on the latter, the forearm (15) which carries the wheel (4) being driven by a thermal or electrical motor external to the device and by means of a pulley or a rotor (10) 3) Device according to claims 1 and 2, characterized in that the reversal of movement of the arms (8) relative to the forearms (1S) is obtained, in the variants s with gears or pulleys, by the wheel (4) integral with a forearm (15) and which drives, in the opposite direction, directly or by a twin wheel fixed on the same axis (6) another wheel (7) , always of the same diameter as the wheel (4) or its twin wheel, this wheel (7) being integral with an arm (8) and centered on the movable axis (9) which is implanted at the end of before- arm, perpendicular to the plane of rotation of the forearm; synchronization of all the movements of the arms (8) relative to each other and with respect to the forearms (15) being ensured by a belt or a gall chain which connects to the wheel (7) driven, all the wheels (16) sol idaires each of a movable arm (8); 4) Device according to claims 1.2 and 3, characterized in that the arms (8) are all the same length, but the length of each arm (8) is slightly smaller than half the length of the front- elongated arm (15), so that the arms (8) and the masses (11) which are also all similar to the end of the arms, can pass during the rotation of the assembly, behind the fixed axis (2 ); the relative movements of the two arms (S) of each forearm (15) and with respect to these forearms being adjusted so that, when one of the arms (8) is in the exact extension of the forearm (15); ), the other arm (S) is exactly superimposed on the same forearm, the mass (11) of the second arm (8) being just behind the fixed axis (2); 5) Device according to any of the preceding claims, characterized in that there is an even number of forearms (15) all similar and that a forearm (15), or half of the forearms (15). ), rotate in the opposite direction of the other half and at the same speed around the fixed axis (2); these reverse movements being performed: either by electronic control when the arms (8) and the forearms (15) are moved by electric motors, or by a double angle transmission placed between two forearms (15) which face each other when the control of the arms (8) and of the forearms (15) is performed with friction or belt-driven gears or pulleys; 6) Device according to claim 5. characterized in that when there are several forearms (15) which rotate in one direction and periodically face several other forearms (15) which rotate in opposite directions and at the same speed around the fixed axis (2), the forearm groups (15) which rotate together in one direction or the other, are staggered regularly with each other and with respect to the fixed axis (2) 90 for example if there are two or 60 for example if there are three;  7) Device according to claims 1,5 and 6, characterized in that the arms (S) of the forearms (15) which rotate in the same direction facing the forearms which rotate in opposite directions, are set to be:  periodically in front of the arms (8) of the other forearms (15), in the same direction and the same position with respect to these forearms (15), that is to say that the arms (8) which rotate in one direction, are periodically opposite the arms (8) which rotate in the opposite direction at the moment when the arms (8) are in the exact extension of the forearms (15), or exactly superimposed on these same forearms ( 15), in use as an autonomous motor; the direction of the arms (S) and of the forearms (15) being then parallel to the direction of the differential centrifugal force that pulls the support (1) and in opposition to the direction of the force or the field that attracts or holds at standstill support (1)  periodically in opposite directions to the directions of the arms (8) of the other forearms (15), at the moment when the arms (8) are in the exact extension of the forearms (15), or exactly superimposed on the same before -arm (15), or when the arms (8) make a right angle with their forearms (15), in use as a thermomechanical converter; the opposite directions of the arms (8), when they are in the extension of the forearms (15), or exactly superimposed on these forearms (15), then being on the same line perpendicular to the direction of the gravitational field or the electromagnetic field which attracts the neutral or magnetic masses (11) placed at the end of the arms (8); 8) Device according to claims 1 and 7. characterized in that, when the field of attraction, in which the device is placed, is an electromagnetic field. the masses placed at the end of the arms (8) are no longer neutral and immobile relative to the arms (S). but are magnetic masses. that is to say permanent magnets or electromagnets, these magnets being movable relative to the brace8) so that the direction of the magnetic field of these magnets is always parallel, during the movements of the arms (8) and forks (15), in the direction of the magnetic field of the hollow coil (20) in which the device is placed;  9) Device according to any preceding claim, characterized in that the torque which tends to rotate the fixed axis (2), in the plane of its length, as a result of the reverse movements of the front-brast15), is balanced by 1 adding, on the same fixed axis2), a second device placed such that the two groups of central forearms rotate in the same direction; 10) Device according to any preceding claim. characterized in that, in the variants which convert the thermal energy into mechanical energy, the masses (11) are removably attached to the ends of the arms (8), ie by pneumatic or magnetic suction cups, or placed in pivoting bowls (21), so that they can be transferred individually, each time the arms (8) are in the extension of the forearms (15), in other removable attachments, suction cups or swivel bowls ( 21) facing them and which are regularly distributed at the periphery of pulleys drum (25) of radius substantially equal to the length of an arm (8) ;; these pulleys drum (25) .in number of two, when there there are only two groups of forearms (iS) placed on the right and left of the device, each mechanically connected to a group of forearms (15) which rotate in the same direction to be able to rotate in the same direction. the same meaning and the same frequency; each pulley drum (25) being also placed between two groups of forearms (15) to be able to retransfer, after a half turn, the mass they have received from the arm (S) in extension of before arm (iS) of a forearm group (15), to the folded arm (8) of the other forearm group (iS), so that the masses (11) can pass continuously from one arm system (8) which rotate in one direction, to the arm system (8) which rotate in opposite direction;