EP4066366A1 - Rotation driving device for driving a rotary shaft - Google Patents

Abstract

The rotation driving device for driving a rotary shaft is a novel system for producing a driving force from an assembly of magnetic or magnetised elements and toothed gears, releasing this driving force via one or two coaxial outputs. The rotation driving device for driving a rotary shaft comprises a centrally positioned axis carrying one or more magnetic or magnetised elements and a toothed synchronisation gear. This assembly forms the rotor. The system is also composed of other peripheral axes around the rotor, each carrying a magnetic or magnetised element and a toothed synchronisation gear. Finally, toothed transmission gears connect, by meshing, the toothed synchronisation gears of the rotor to those of the peripheral axes. In order to control the movement of the system, the latter uses an electromagnetic stator or a control means composed of rings having magnetic or magnetised elements, thus making it possible to control the slowing down, acceleration or resting of this movement. The production of the force of the system is substantially based on a contribution by magnetic elements of the rotor and those of the peripheral axes, as well as on the positioning of the magnetic poles of all the elements synchronised by the toothed gears. The latter are applied so that the speed of rotation of a magnetic pole of the rotor is greater than that of a magnetic pole belonging to an element carried by a peripheral axis.

Description

ROTATION DRIVE DEVICE FOR DRIVING A ROTARY SHAFT

The Rotary Drive Device for Driving a Rotary Shaft is a new motor-driven system designed to produce motive power to reduce the dependence of energy on the needs of our current machines.

The energy resources used for the movement of any device (vehicle, plane, boat, electric generator) are expensive and often harmful. Renewable energies also fail to meet the relentless needs of demand. To achieve the goal of attenuating the energy relative to the movement of our current machines, the rotary drive device for driving a rotating shaft represents a new reciprocating system.

The rotary drive device for driving a rotary shaft has several purposes.

First, it allows the system to generate a driving force to match any need.

Second, it provides a system which takes into account ease of manufacture, low cost of production, reliability in use and wide application scope.

It also offers a system that takes into account many means of adaptation. It can be coupled, for example, to a system or to a gearbox of a rolling machine or to that of various accessories such as alternators, air conditioners and pumps. It can also operate an electric generator, in atmospheric space or outside the Earth's atmosphere.

The rotational drive device for driving a rotating shaft is a system designed to provide driving force through one or two coaxial outputs from a set of magnetic or magnetized elements and toothed gears. The stability of the system depends primarily on a frame and the bearing brackets that hold the axes of the system. These bearings fixed to the supports allow this system a flexibility of rotation to the axes carrying magnetic or magnetized elements and toothed pinions. The frame should be made of a rigid material in order to avoid twisting of the system and thus allow the geometry of all the components necessary for its proper functioning to be held in place.

The system is composed of an assembly comprising axes, magnetic or magnetized elements and toothed synchronization gears. Each axis carries at the same time at least one magnetic or magnetized element and at least one toothed synchronization pinion. One of the axes of this system assumes a central position as the axis of the rotor, while the others serve as peripheral axes.

This system also employs other toothed gears. They are responsible for the transmission between a toothed synchronization pinion carried by the rotor axis and the toothed synchronization pinions carried by the peripheral axes. The timing gears carried by the peripheral axles mesh one by one, or in pairs, with one of the transmission gears. Another transmission toothed gear in turn meshes with the timing gear carried by the rotor shaft.

This axis is in a central position and carries an assembly made up of one or more magnetic or magnetized elements and one or more toothed synchronization pinions: this assembly represents the rotor. The other axes have a peripheral position around this rotor. The rotor axis has one or two coaxial outputs to release the driving force of the system.

The reduction in the volume occupied by the rotary drive device for driving a rotary shaft is only possible thanks to the size of the toothed transmission gears. All the toothed gears (transmission and synchronization) thus make it possible through these meshes to synchronize the rotary movement between magnetic or magnetized elements belonging to the rotor and those belonging to the peripheral axes.

In short, it is a rotary drive device for driving a rotating shaft comprising an annular motor frame (8), to which drives are called along its circumference, transmission toothed gears (7.2), a number of magnetic units (6 and 6.1) and of toothed gears for synchronizing the magnetic fields (7 and 7.1) carried respectively by an axis of the rotor (1.1) and its peripheral axes (1.2).

In order to control the rotary movement of the magnetic or magnetized elements synchronized by the toothed gears, the system uses a control stator. The rotary movement of this system being considerable, the control means engaged must therefore be up to their mission.

The interaction of the magnetic fields of elements carried by peripheral axes does not present a constraint that could block the continuous activity of the system. Each constraint between fields of peripheral elements is counter-square by its opposite. For example: a stress of two magnetic fields (north, north) has to oppose two other magnetic fields (south, north).

The interactions of the magnetic fields which relate to the repulsion and to the magnetic traction between the poles of peripheral elements and those belonging to the elements of the rotor, allow the poles relative to the rotor, to alternate respectively from peripheral elements in peripheral elements . This is thanks to the positioning of the magnetic poles and the application of synchronization and transmission toothed gears. For example: if the pole (P.2) note PMR is located between the pair of poles (P.2) note PMP, the pole PMR is expressed by the field of the same magnetic identity and at the same time it is attracted ( P.2) note RR, towards the field of an opposite identity belonging to the same element (P.2) note PMP Once PMR is between two elements, the repulsion remains active with respect to the element previous, and at the same time PMR is attracted to the opposite identity of the next element, so that PMR is located between the other pair of poles belonging to this (next) element. This application of the PMR pole alternately allows the continuous activity of the system.

However, this alternation is subject to a certain number of criteria such as:

The interactions of magnetic fields between the poles of one or more magnetic or magnetized elements carried by the rotor axis and those carried by the peripheral axes are constantly kept in synchronization by toothed pinions.

The involvement of toothed synchronization gears ensures at the poles of one or more magnetic or magnetized elements of the rotor (P.2) note PMR a high speed of rotation compared to the poles of any element carried by a peripheral axis P .2 PMP note

Preferably, the involvement of the toothed synchronization gears ensures that the magnetic poles of the rotor are at least three times faster than that of any magnetic pole belonging to a peripheral element.

The contribution of this involvement by the toothed synchronization gears allows a high force at any intensity of the field of a magnetic pole of the rotor, despite the resistance of the fields relating to the poles of elements carried respectively by the peripheral axes. .

However, this system must meet other criteria, such as:

- Whatever the magnetic pole of a rotor element, it moves alternately between the two magnetic poles of elements carried by the peripheral axes to create mechanical work.

- The alternation of the magnetic pole of an element of the rotor is synchronized by toothed pinions to create a variation of the magnetic flux. - The diameter of the toothed synchronization pinion carried by the rotor axis must be less than the diameter circumscribed by one or more magnetic or magnetized elements of the rotor.

- The diameter circumscribed by one or more magnetic or magnetized elements carried by the axis of the rotor must be greater than the diameter of an element carried by a peripheral axis.

- The magnetic or magnetized elements carried by the axis of the rotor and those carried by the peripheral axes, the whole of which is synchronized by toothed pinions, within the annular frame of the motor, can take another geometric shape and / or another name. For example: diametral or axial permanent magnet.

- The number of revolutions per minute of a magnetic or magnetized element carried by a peripheral axis may be greater than or equal to that of an element carried by the rotor axis. This depends on the number of peripheral axes used by the system.

However, if this number exceeds twelve peripheral axes and at the same time an increase in the volume of the system, the application results in an increase in driving force at depth. (The conception of this depth by the system is opposed to certain principles of general relativity, concerning: mass by gravitation in height (mgh), and at the same time to the notion of (mc2). However, the practical reality of the system makes it possible for the latter to agree with quantum theory, but the concept of the system provides for another theory.

Thus, the system of a rotary drive device for driving a rotary shaft is intended to produce a driving force released by one or two coaxial outputs by virtue of a number of magnetic or magnetized elements and of toothed synchronization pinions carried by a central axis of the rotor and its peripheral axes around, these pinions meshed by means of toothed transmission pinions.

- The system uses an electromagnetic stator, or rings made up of other elements with a magnetic field to control the slowing down, accelerating or resting the synchronized rotation of the system. These control rings allow the engine to have control means for controlling its motive force applied to a various fixed or mobile device such as: motor vehicle, airborne device, flight device, electric generator or another device requiring a driving force.

- The engine can be applied to a variety of fixed or mobile machinery, and depending on needs, arranged with one of its two coaxial outputs for a gearbox and the other to actuate other accessories.

According to the present invention, the system of a rotary drive device for driving a rotary shaft can thus be presented in various embodiments and combinations, while preserving at least one output by any axis.

However, regardless of the embodiment, arrangement or combination of the system, it retains the same characteristic features mentioned by the rotary drive device for driving a rotary shaft.

A basic model is proposed, the realization of which is designed from a single production set (P.1). It essentially consists of magnetic or magnetized elements aligned one by one around the rotor, a set of toothed pinions and finally, a possible ring control means. The other drawing boards illustrate the system components (P.2), (P.3), (P.4) and (P.5), (P.6), (P.7).

However, other models can be the subject of an addition of magnetic or magnetized elements aligned around the rotor both one by one and in parallel or on either side of the toothed gears, or else make the object of several peripheral axes.

Whatever the choice of the model produced, it cannot depart from the framework and the scope of the present invention. The phases for mounting a basic model concerning the rotary drive device for driving a rotary shaft (P.1) are as follows:

1. List the North (N) and South (S), respectively the positive (+) and negative (-) of all magnetic or magnetized elements (P.2). 2. Place the toothed gears (P.3), notes 7, 7.1 and 7.2, their axes (P.3), notes 1.1 and

1.2 and the rods (P.3), note 2, between their two supports within the frame (P.1), note 8.

3. Place the magnetic or magnetized (peripheral) elements according to the north, south positioning (P.2) note 6, and place the support (P.4).

4. Check the fluidity between the magnetic or magnetized elements carried respectively by the peripheral axes.

5. Place the control means (P.1), note 5 (in stop situation (P.2), note X).

6. Place the magnetic or magnetized element of the rotor (P.2), note 6.1 and close the cover (P.5).

To activate the system, simply pull the throttle cable (P.2), note 9, or another remote function to move one of the two rings located on position (P.2), note X ( system stopped) to position (P.2), note Y + X (system accelerating).

BOARD (P.1) The board (P.1) is the description of the device formed by toothed gears and a set of magnetic or magnetized elements in alignment one by one around the rotor.

1: Exit

2: Stem

3: Mobile magnetic or magnetized element 4: Magnetic or magnetized element

4 .1: Fixed magnetic or magnetized element

5: Fixed and movable rings

6: Magnetic or magnetized element

7: Toothed pinions 8: Frame

9: Throttle cable A: Cover B: Bracket PLATE (P.2)

The board (P.2) is the drawing of the control means, of the magnetic or magnetized elements carried by the peripheral axes and of the element carried by the rotor axis. 1.1: Rotor axis 1.2: Peripheral axis

4: Magnetic or magnetized element

5: Fixed and movable rings

6: Magnetic or magnetized peripheral element 6.1: Magnetic or magnetized element of the rotor

8: Frame

9: Accelerator cable

N. N: Poles of two magnetic or magnetized elements Y + X: System accelerating X: System stopped

P.M.P: Pair of magnetic poles of the peripheral element P.M.R: A magnetic pole of an element of the rotor S: South pole (-)

N: North Pole (+)

N. S: Poles of two magnetic or magnetized elements R. R: Direction of rotor rotation R. P: Peripheral direction of rotation A: Cover B: Support

PLATE (P.3)

Plate (P.3) is the drawing illustrating the formation of timing and transmission sprockets.

1.1: Rotor axis 1.2: Peripheral axis 2: Stem

7: Peripheral synchronization gear

7.1: Rotor synchronization gear

7.2: Transmission gears

8: Frame

PLATE (P.4)

The board (P.4) is the support for the peripheral axes. B: Support R: Bearing

PLATE (P.5)

The board (P.5) is the cover that holds the axis of the rotor. 1.1: Rotor axis A: Cover R: Bearing

PLATE (P.6)

The board (P.6) is an example of a magnetic or magnetized element of the axial type (this type can be used by the system).

PMA: Pair of magnetic poles. PLATE (P.7)

The board (P.7) is an example of a magnetic or magnetized element of the diametral type (this type can be used by the system).

P.M.P: Pair of magnetic poles.

Claims

1- Rotational drive device for driving a rotating shaft, comprising an annular motor frame (8), to which commands are called along its circumference, transmission toothed gears (7.2), a number of units magnetic (6 and 6.1) and toothed gears for synchronizing the magnetic fields (7 and 7.1) carried respectively by an axis of the rotor (1.1) and its peripheral axes (1.2), characterized in that whatever the magnetic pole of an element of the rotor it is directed alternately between the two magnetic poles of elements carried by the peripheral axes to create a mechanical work.

2- A rotary drive device for driving a rotary shaft according to claim 1, characterized in that the alternation of the magnetic pole of a rotor element is synchronized by toothed pinions to create a variation in the magnetic flux.

3- Rotary drive device for driving a rotary shaft according to claim 2, characterized in that the involvement of toothed synchronization pinions ensures the poles of one or more magnetic or magnetized elements of the rotor (P.2) PMR note a high speed of rotation with respect to the poles of any element carried by a peripheral axis P.2 note PMP

4- A rotary drive device for driving a rotary shaft according to claim 3, characterized in that the diameter of the synchronization toothed pinion carried by the axis of the rotor must be less than the diameter circumscribed by one or more magnetic or magnetized elements of the rotor.

5- A rotary drive device for driving a rotary shaft, according to claim 4, characterized in that the diameter circumscribed by one or more Magnetic or magnetized elements carried by the axis of the rotor must be greater than the diameter of an element carried by a peripheral axis.

6- A rotary drive device for driving a rotary shaft, according to claim 5, characterized in that the number of revolutions per minute of a magnetic or magnetized element carried by a peripheral axis may be greater than or equal to that of an element carried by the axis of the rotor.

7- Rotary drive device for driving a rotary shaft, according to claim 6, characterized in that one or more magnetic or magnetized elements carried by the axis of the rotor and those carried by the peripheral axes, the assembly of which synchronized by toothed gears within the annular frame of the engine, can take another geometric shape and / or another name.

8- A rotary drive device for driving a rotary shaft, according to claim 7, characterized in that the motor uses an electromagnetic stator, or rings composed of other magnetic field elements allowing it to control the slowing down, accelerating or resting its synchronized rotation.

9- Rotary drive device for driving a rotary shaft according to claim 8, characterized in that the motor can be applied to a various fixed or mobile machine, and according to needs, disposed of one of its two coaxial outputs for a gearbox and the other to operate other accessories.