WO2002067408A1

WO2002067408A1 - Autonomous electrogravitational energy alternator

Info

Publication number: WO2002067408A1
Application number: PCT/ES2001/000055
Authority: WO
Inventors: José GARCIA JEREZ
Original assignee: Garcia Jerez Jose
Priority date: 2001-02-15
Filing date: 2001-02-15
Publication date: 2002-08-29

Abstract

The invention relates to an electrogravitational energy alternator, comprising an alternator assembly which has been designed to operate in a fully autonomous manner without requiring other auxiliary means or the use of any other type of fossil fuel. The operation of said alternator is based on combining mechanical and electromotive forces by means of magnetic fields and levitation of its rotors in horizontal position. By levitating the rotors on the body of the chassis, frictions and angular displacements are avoided.

Description

AUTONOMOUS ELECTROGRAVITATORY POWER ALTERNATOR

D E S C R I P C I Ó N

OBJECT OF THE INVENTION

The present specification refers to a request for an Invention Patent, relating to an autonomous electrogravitational energy alternator, whose obvious purpose is to be configured as an alternator that has a fully autonomous operation, without any need to be used by other auxiliary means , such as diesel engines, gas turbines, coal, nuclear power plants etc.

The invention, being totally autonomous and does not require fossil fuels, does not contaminate, which does not give off residues of any kind.

FIELD OF THE INVENTION

This invention has its application within the industry dedicated to the manufacture of alternators and the like.

BACKGROUND OF THE INVENTION

The applicant is not aware of the present existence of an invention that contemplates an autonomous electrogravitational energy alternator.

DESCRIPTION OF THE INVENTION The autonomous electrogravitatqria energy alternator proposed by the invention is based on the combination of mechanical and electromotive forces by magnetic fields and levitation of its rotors in a horizontal position, which means that the rotors when levitating. on the chassis itself, avoid friction and angular displacements, presenting a homogeneous operation, to maximize the mechanical forces of the main rotors, thus obtaining electrical energy.

More specifically, the autonomous electrogravitational energy alternator object of the invention is constituted from a main shaft, as well as by an upper inertia rotor, having a fixing nut and a bearing bearing, presenting upper stabilizers and lower lateral inertia and induction fields.

The invention incorporates upper and lower electromagnetic coils, as well as circular magnetic rings of variable polarity in upper and lower chassis, having an axle chassis and upper fixing, dynamotor crowns and main alternator, as well as crazy intermediate crowns, presenting a porta chassis axes of crazy crowns and a dynamotor endowed with its relevant dynamotor crown and crazy intermediate crowns.

The invention has a main alternator provided with its corresponding axis, as well as levitation base plates of the main alternator mentioned above, incorporating magnetic rings of alternator base plates and field dynamotor variable, as well as intermediate chassis plates carrying axles and fixings of all the elements.

Finally, it should be noted that the invention is provided with a lower rotor of inertia, a threaded ring approximating the main shaft to the chassis, fixing nut, bearing holder separator of the main rotor and several main shaft bearings, with two central crowns of the shaft at the top, the axes of the upper and lower intermediate intermediate crowns and the emergency and needle side bearings for the orientation of the main shaft.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, a descriptive sheet is attached as an integral part thereof, with an illustrative character and not limiting, the following has been represented:

Figure number 1.- Corresponds to a duly sectioned side elevation view of the object of the invention, relating to an autonomous electrogravitational energy alternator.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the number 1 and unique figure, it can be seen how the autonomous electrogravitational energy alternator that is recommended, is constituted from a dynamotor (12) that is responsible for Put the whole assembly into operation as follows. Namely:

The dynamotor (12) is equipped with two traction crowns (9) and (13) at its exit which are responsible for moving the crowns (10) and (14) intermediaries which in turn are responsible for moving the crowns, (25) and (26) of the main shaft (1) producing a solidarity movement in the upper and lower rotors (2) and (22) respectively.

The main axis - (1) upon receiving this movement of the dynamotor (12) transmits movement to the crowns (10) and (14) configured as crazy intermediaries located on the side of the alternator, engaging with the output crowns (9) and

(19) of the main alternator (15).

Once the rotation of the rotors (2) and (20) has been set at the desired revolutions by the coils (6) and (6 '), the disconnection of the dynamotor (12) occurs, passing this same dynamotor to become an electric generator, together with the main alternator (15), thus creating free energy to use.

In the main rotors (2) and (20) to avoid friction, the incorporation and installation of the electromagnets (7) and (7 ') in the upper part, configured as two couples and as many pairs in the lower part referenced, have been planned. with (37) and (37 ') that are responsible for levitating the entire central assembly.

The spherical masses (5) and (5 ') located on the periphery of the rotors (2) and (20) are responsible for entering the magnetic fields produced by the coils (6) and (6 "), to displace the rotors (2) ^' and (20), producing these movements in mass pentagon with 90 ° angles and cosines of pi of 40 °, 5 producing a perfect turn and the use in all of its inertia.

Both the dynamotor (12) and the alternator (15) are provided with two fixing plates e

10. inertia (16), planned for the installation of the two electromagnets (17) and (17 '), which in turn work faced by the two electromagnets (18) and (18), which in turn are responsible for levitate the alternator (15) and the dynamotor (12).

fifteen

As a consequence, both in the rotors (2) and (0) and in the lower fixing plates (16) and (16 ') ,. when the electromagnets (17) and (17 ') are installed,' as well as those referenced with (18) and (18 ') are

20 produce repulsive forces, which cause both the rotors (2) and (20) and the dynamotor (12) and the alternator (15) to levitate, picking up the fundamental Law of gravity.

In summary, the movement of the main rotors (2) and (20) that are responsible for producing sufficient inertia on the alternators

(15) and the dynamotor (12), generate a usable movement transforming it into electrical energy.

30

. ^• The invention presents the possibility of adding or reducing elements to the machine itself, according to the calculation of energy that is made.

35 ^• The constituent elements of the machine are the following . Namely:

- Main shaft (1),

- Upper rotor of inertia (2),

- Fixing nut (3),

- Support bearing (4),

Upper lateral inertia stabilizers and induction fields (5),

Lower lateral inertia stabilizers and induction fields (5 '),

- Upper electromagnetic coils (6),

- Lower electromagnetic coils (6 '),

- Magnetic circular rings of variable polarity in upper and lower chassis (7), (7 '), (37) and (37'),

- Shaft carrier chassis and upper fixing (8),

- Dynamotor crowns and main alternator (9),

- Crazy intermediary crowns (10),

- Chassis of axes of crazy crowns (11),

- Dinamotor (12), - Dynamotor crown (13),

- Crazy intermediary crowns (14),

- Main alternator (15),

- Main alternator shaft (15 '),

Levitation base plates (16) of the main alternator (15),

- Magnetic rings ¹ (17 ') of base plates (16) of the ^' alternator (15) and variable field dynamotor (12),

- Magnetic rings (18) and (18 ') of the base plates (16) and- (16') in the alternator chassis

(15) and dynamotor (12),

- Chassis plates (19) and (19 ') intermediate between the axle carrier and the fasteners of all the elements,

- Lower rotor of inertia (20),

- Threaded ring (21) approaching the main shaft (1) to the chassis,

- Fixing nut (22),

- Separator (23) bearing carrier. lower rotor,

- Bearings (24) of the main shaft (1), - Central crown (25) and (26) of the shaft at the top and bottom respectively,

- Axes (27) and (27 ') of the upper and lower intermediate intermediate crowns,

- Lateral bearings (28), (28 '), (28 ") and (28"'), as well as bearings (29) and needles for the orientation of the main shaft (1).

Claims

RE IVINDI CA CIONES

1.- Autonomous electrogravitational energy alternator, characterized by being constituted from a main shaft (1), upper inertia rotor (2), fixing nut (3), support bearing (4), upper lateral inertia stabilizers and induction fields (5), lower lateral stabilizers of inertia and induction fields (5 '), electromagnetic coils (6) and (6') upper and lower respectively, magnetic circular rings of variable polarity (7) and (7 ' ), axle carrier chassis and upper fastening (8), dynamotor crowns and main alternator (9), crazy intermediate crowns (10), axle crowns chassis (11), dynamotor (12), dynamotor crown (13), crowns crazy intermediaries (14), main alternator (15), main alternator shaft (15 '), levitation base plates (16) of the main alternator (1), magnetic rings (17), (17'), (18) and ( 18 '), chassis plates

(19) and (19 '), lower inertia rotor (20), threaded ring (21) for approximation of the main shaft (1) to the chassis, fixing nut (22), spacer (23) bearing carrier, bearings ( 24) of the main shaft (1), central crown (25) and (26) of the shaft at the top and bottom respectively, shafts (27), (27 '), (27 ") and (27'") of the upper and lower intermediate intermediate crowns, side bearings (28) and (28 '), emergency and needle bearings (29) for the orientation of the main shaft (1).

2. Autonomous alternator and electrogravitational energy, according to the first claim, characterized in that the dynamotor (12) is responsible for operating the alternator, providing two traction crowns at its exit (9) and (13), responsible for moving the crowns (10) and (14) intermediaries which in turn are responsible for moving the crowns (25) and (26) of the main shaft (1) producing a solidarity movement in the rotors

(2) and (22) upper and lower respectively, with the central axis having received the movement of the dynamotor (12) a transmission of movement to the crowns (10) and (14) configured as local intermediaries - located on the side of the alternator , gearing with the output crowns (9) and (19) of the main alternator (15).

3.- Autonomous alternator or electrogravitational energy, according to the preceding claims, characterized in that the rotation of the rotors' (2) and (20) at the revolutions desired by the coils. - (6) and (6 ^r ) generates dynamotor disconnection

(12), ^' -passing the dynamotor (12) to become an electric ^' generator ', together with the main alternator

(fifteen).

4. Autonomous alternator -e electrogravitational energy, ¹ according to the preceding claims, characterized in that the main rotors (2) and (20) are intended for the installation of the electromagnets (7) and (7 ') in the upper part, and the installation of electromagnets (37) and

(37 ') at the bottom.

.

5.- Autonomous alternator ζ | e electrogravitational energy, ^' according to the preceding claims, characterized in that the spherical masses (5) and (5') located on the periphery of the rotors (2) and (20) are responsible for entering the magnetic fields produced by the coils (6) and (6 'to displace the rotors (2) and (20).

6. Autonomous electrogravitational energy alternator, according to the preceding claims, characterized in that the dynamotor (12) and the alternator (15) are provided with two fixing and inertia plates (16), on which electromagnets (17) and (17 '), facing the two electromagnets (18) and (18).