ES1072632U - Rotor inercial (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Inertial rotor, characterized by being formed by a set of coaxial bodies (1) each comprising a set of circuits (2) arranged symmetrically with respect to an axis of rotation (3), and because each of the circuits is constituted for at least three portions: - a first portion (22) proximate the axis of rotation (3), with an outer end (32) and an inner end (31); - a second portion (23), curve, extending in an arc of circumference with respect to the axis of rotation (3), from the first portion (22) to cover a certain angle, with a first end (33) adjacent to the end outer (32) of the first portion (22) and a second end (34); - a third portion (21) joining the second end (34) of the second portion (23) to the inner end (31) of the first portion (22), said circuit being partially filled with a liquid. (Machine-translation by Google Translate, not legally binding)

Description

Inertial rotor.

The present invention aims at a inertial movement device of a rotor comprising about circuits formed by conduits for the passage of a fluid, with some chambers that allow the accumulation of fluid in certain angular positions and fluid withdrawal in other positions towards an area closer to the center of rotation.

State of the art

Numerous devices have been described that take advantage of the energy developed by the device itself as means to generate the movement of the device itself. Sayings devices are usually mechanical devices that act by yes alone or that can be combined with electrical devices, magnetic, hydraulic, chemical, etc. However, to date there has been no device that solves the problem so satisfactory, in particular.

WO 02/35090 describes a motion generator continuous consisting of a double axis body in which due to a asymmetric displacement of the masses occurs a "imbalance" of energy resulting from an exploitation energy in at least one of the axes.

Description of the invention

The proposed invention consists of a rotor provided with a set of juxtaposed coaxial bodies sequentially Each of said bodies is provided with a plurality circuits, arranged in said body symmetrically with respect to the axis of rotation, so that according to one embodiment The main symmetry is quaternary. These circuits are formed by a set of ducts and a set of cameras, by those that travels and accumulates a liquid that circulates inside of the circuit

Each of these circuits has different portions;

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a first portion next to axis of rotation, with one outer end and one end inside;

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a second curved portion that extends in an arc of circumference with respect to the axis of rotation, from the first portion to cover a certain angle, with a first end adjacent to the outer end of the first portion and a second end;

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a third portion that joins the second end of the second portion with the inner end of the first portion.

At the junction between the second end of the second portion and the third portion of each of the circuits are it has a first camera; also, a second chamber is arranged at the junction at the inner end of the first portion and the third portion, and a third chamber between the outer end of the first portion and the second portion; the circuits are essentially coplanar in each of the coaxial bodies juxtaposed, the cameras can emerge laterally from the plane correspondent.

The cameras can be made up of small tanks, tubes thicker than those that constitute the first, second and third portions, by bulbs, or be constituted by more than one tube, both in open or closed loop. Possibly and preferably at least some of the cameras are arranged transversely.

The circuit is partially filled with a liquid, preferably a high mass liquid; also it is it is desirable that the liquid in question has a low viscosity. It has been chosen mercury as a liquid element that meets the desired requirements, since although its viscosity is not the minor, it is to an acceptable degree, being a large liquid density at room temperature. It could also, however, use another liquid such as heavy water or even common water. Obviously the amount of liquid in each of the circuits is the same and the liquid is the same in all of them.

As the rotation of the rotor occurs, it will produce a displacement of the liquid contained in each of the circuits, so that the weight of the same exerts a force tangential on the rotor, so that the more to the extreme outside the rotor is the liquid, greater force will exert on the axis of rotation of the same.

When one of the circuits is rising there will normally be another that will be descending, in the opposite position in the same rotor body or in another of the bodies joined in a Same axis of rotation. And there will also possibly be other circuits in the upper and lower areas or in other positions of transition.

We will make the following explanation about different positions of one of the circuits that make up one of the rotor bodies, being equally applicable to any of the other bodies and circuits in said bodies. When one of the circuits begin their ascent phase, the entire liquid is is arranged in the second portion, which is the one that is located further down. As the liquid rises descends through said second portion until it accumulates in the first chamber, since the third portion is empty, and above said First camera By continuing the turn the third portion is set to horizontal position, so it fills up the liquid that up to that moment is in the first chamber, emptying said first chamber and passing its content to the third portion, as the third portion is tilted due to rotation, the liquid passes to the second camera, that being very close to the center exerts a very moment Small on the axis of rotation.

This circuit continues to rise without the liquid move from the second chamber, since both the third portion as the first one is placed above said second camera.

When the first portion adopts the position horizontal, the second chamber is emptied, and passes its content to the first portion, and, as the turn continues, the third chamber, becomes positioned below the first portion, so the circuit content moves to said third chamber, exerting a lever arm from the raised position until reaches the bottom point, repeating the cycle successively. Since the arc in which the liquid is in the outer zone in the lifting position is smaller than the one in the position of descent results from a pair of forces from which it is possible harness energy

The thicknesses of the ducts that form the different portions of the circuit and the shape and size of the cameras they will be suitable for an optimal embodiment of the invention, being it is desirable that the entire liquid fit in each of the cameras

The part of the circuits that is not occupied by liquid it can be subjected to a certain pressure or to the empty.

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Brief description of the drawings

In order to illustrate the explanation that will follow, we attach to this description, four sheets of drawings, in which the essence of the present invention, and in which:

Figure 1 shows a perspective view of an inertial rotor body of the invention, provided with a set of closed circuits for the circulation of a fluid;

Figure 2 shows a side view of the body of the rotor, of figure 1;

Figure 3 shows an exterior view tangential of the inertial rotor body of the invention; Y

Figure 4 shows a view of a rotor formed by a set of bodies of figures 1 to 3.

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Description of a preferred embodiment of the invention

According to a preferred embodiment of the invention, as shown in the attached figures, the rotor of The invention comprises a plurality of bodies (1) provided each one of them four circuits (2), said bodies (1) being joined each other by means of a rotation axis (3). Even when figure 4 represents a set of eight bodies (1), it is considered convenient that the bodies (1) have an angular displacement of 5º with respect to to the circuits (2) of another of the bodies, covering all of the circumferential angle with the circuit set (2) of each body (1), eighteen being the number of bodies (1). But nevertheless, that angular displacement will be variable depending on the number of circuits (2) and the number of bodies (1).

Each circuit includes:

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a first portion (22) next to the axis of rotation (3), with an outer end (32) and an end interior (31);

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a second portion (23), curve, which extends in an arc of circumference with respect to the axis of rotation (3), from the first portion (22) to cover a certain angle, with a first end (33) adjacent to the end exterior (32) of the first portion (22) and a second end (3. 4);

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a third portion (21) that joins the second end (34) of the second portion (23) with the end interior (31) of the first portion (22).

At the junction between the second end (34) of the second portion (23) and the third portion (21) of each of the circuits a first chamber (24) is arranged; also available a second chamber (25) at the junction at the inner end (31) of the first portion (22) in the circuit and the third portion, (21) and a third chamber (26) between the outer end (32) of the first portion (22) and the second portion (23); the circuits are coplanar all juxtaposed coaxial bodies (1), and chambers (24, 25, 26) emerge tangentially from the plane correspondent.

The second (25) and third (26) cameras are formed by small deposits consisting of arranged tubes transversely; the thickness and length of said tubes will be the suitable to accommodate the volume of liquid required. In the embodiment shown, the first chamber (24) has a shape essentially rectangular.

Claims (6)

1. Inertial rotor, characterized by being formed by a set of coaxial bodies (1) each comprising a set of circuits (2) arranged symmetrically with respect to an axis of rotation (3), and because each of the circuits is constituted for at least three portions;

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a first portion (22) next to the axis of rotation (3), with an outer end (32) and an end interior (31);

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a second portion (23), curve, which extends in an arc of circumference with respect to the axis of rotation (3), from the first portion (22) to cover a certain angle, with a first end (33) adjacent to the end exterior (32) of the first portion (22) and a second end (3. 4);

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a third portion (21) that joins the second end (34) of the second portion (23) with the end interior (31) of the first portion (22).

said circuit being partially filled with a liquid.

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2. Inertial rotor according to claim 1, characterized in that the liquid is heavy water. 3. Inertial rotor according to claim 1, characterized in that the liquid is mercury. 4. Inertial rotor according to claim 1, characterized in that it further comprises at least one liquid accumulation chamber in its rotational movement. 5. Inertial rotor according to claim 4, characterized in that the duct comprises three chambers:

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a first camera (24) arranged between the second portion (23) and the third portion (twenty-one);

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a second camera (25) disposed between the third portion (21) and the first portion (22); Y

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a third chamber (26) arranged between the first portion (22) and the second portion (2. 3).

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6. Inertial rotor, according to claim 4 or claim 5, characterized in that at least one of the chambers consists of a tube arranged transversely to the plane that forms the circuit.