ITTO20110022A1 - GRAVITATIONAL ENERGY ENGINE. - Google Patents

Description

DESCRIPTION OF THE INDUSTRIAL INVENTION BY TITLE

"GRAVITATIONAL ENERGY MOTOR"

The present invention has as its purpose the use of a new energy source, previously hypothesized and developed by the inventor, which can be used for countless types of applications.

As we are going to highlight, this study has enormous practical potential that mainly concern the ecological and economic components; in fact it is aimed at that product sector that is usually referred to as "renewable energy", even if it has a much greater field of use.

The characteristic of this application is due to an intrinsic and wider possibility of exploiting natural springs, both from a technical and an economic point of view.

This invention is based on the construction of an engine that uses Archimedes' thrust to be able to exploit the gravitational field as an energy source, and is composed of:

a Container, adapted to be filled with a Fluid, which is characterized by the presence of an opening built on an area having the shape of a part of a circular sector;

and where this area is positioned to be perpendicular to the axis of rotation.

Furthermore, the previous opening is made up of a series of valves which are in the open or closed position and which allow the other part of the engine to be connected, even partially; the Container, then, is connected to, or includes, a Labyrinth Structure, which allows a series of functional operations that will be indicated later.

And from:

a Rotor, mainly having the shape of a cylindrical crown, which is equipped with one or more circular crowns, to be opposed to the similar ones indicated in the previous paragraph and made on the Container;

and is composed of a number of 2 * N elements, possibly equal.

And where the latter have the characteristic that the Fluid contained in each of them cannot be placed in direct contact with that present in another Element, even adjacent.

Furthermore, inside each single Element, bags are built, such as to occupy almost all of its available volume, made with a very light material so as to float, if they were closed and left free on the surface of the liquid; this hypothesis obviously starts from the assumption that the Fluid in question is a liquid.

The bags, then, are made in solidarity with the Element that contains them.

As we have previously explained, the Rotor is composed of one or two circular crowns which constitute the connection interfaces between the Rotor and the Container; for simplicity we will treat this fact as if the interface were single, subject to on-site corrections.

The Elements that make up the Rotor, moreover, are constrained to the rotation axis through suitable supports and are connected to the Container either directly, through the circular crown described above, or through ducts, preferably very small, even not fixed, which are always connected to the circular crown just mentioned.

As a last consideration, it should be noted that there is also an opening in the container which allows the liquid not only to enter or exit, but also to transmit any additional pressure to the fluid.

The circular crown drawn on the Rotor, a shape that is the section normal to the rotation axis of the Rotor, delimits inside a series of openings, we suppose circular, which allow the flow of the Fluid contained in each of its Elements and with that present in the Container than with that inside each other Element.

This passage takes place through an opening, practically continuous, built in the circular crown of the container, in contact with the Rotor, and which also has the shape of a part of a circular sector with a central angle of at least 180 °; and where this opening is a part of the circular crown on which it is built, so that the remaining part can also be opened following operational logics.

In addition to this, it is asserted that the opening of the Container which connects the Fluid contained in the Rotor with that of the Container, covers all the openings present in the Rotor;

and that the opening of the container can be partially or totally closed, so as to be able to vary the force generated by the fluid.

Furthermore, the value of the angle corresponding to the opening configured in the Container can assume the value of 180 ° 180 ° / N, where 2 * N identifies, as seen previously, the number of Elements that make up the Rotor.

In addition to this it is established that the contact surfaces between the Rotor and the Container prevent the escape of the Fluid present in the Rotor-Container system, and that, in addition to the aforementioned function, they are capable of rotating and sliding.

It is also required that the force necessary to balance the counter-motion component, generated as a consequence of the thrust due to Pascal's law, is determined by a hydraulic system, a more convenient solution than an electromagnetic or other type of balancing.

And again, it is pointed out that the resultant of the forces applied to the Rotor does not pass through the Rotor Axis of Rotation.

The latter, then, is equipped with a series of gears capable of transmitting motion to a user system and not being in a vertical position.

There is also the possibility that the coupling surface of the Rotor is external to the Rotor itself; in this case the surface can be connected to the Rotor through an element consisting of a series of fixed or mobile channels.

Likewise, however, it can also be assumed that the coupling surface of the Container may be external to the Container itself and that, therefore, it will be constructed with characteristics similar to that described above for the Rotor.

The use of an even number of Elements making up the Rotor is a convenient but absolutely non-binding solution.

Furthermore, the radius Ri, the internal radius of the cylindrical crown and of its normal section with respect to the Axis of Rotation where R2 indicates the external radius, can also be zero.

The present invention is an improvement of a series of other patents already filed by the inventor with the name of "Hydraulic Machine" in the following States:

USA no. 4,499,725

Europe no. 0134.382 (including Italy)

Japan no. 1,331,809

Brazil no. VAT number 8303816

Spain no. 523.822

and finally, with the presentation of a new and more performing version, the patent with the title of “Hydraulic Motor” registered in Italy on 5/29/2000 with the serial number 01300805.

This invention differs in the technique for what is reported in those works for a more efficient industrial application, also providing greater reliability and some advantages of environmental insertion, as well as having other characteristics that will be highlighted later.

It is also important to remember that by Fluid, a term generally indicated, we do not only mean a liquid or a gas, but also those substances that are in this state in the work we are going to examine: a typical example is the use of mercury.

The Motor, object of the present invention, is based, as previously reported, on the Archimedes principle; this application is constructed in such a way as to obtain the rotation of a transmission shaft, connecting the liquid present in the Rotor with that of the Container, through suitable openings, included in the circular crowns of the contact surfaces.

These flanges are generally made of materials which allow rotation and at the same time prevent the fluid contained in it from escaping; typical are those that use ceramic disks as opposed to graphite disks, made, however, perfectly smooth.

Furthermore, by means of suitable connections, it is possible to modify the resultant of the Archimedes thrust exerted by the Fluid on the Elements of the Rotor.

This application is based on one of the simplest forces present in nature that owes its existence to the Gravitational Field, but the writer has no energy implications, except for the conceptually trivial and destructive one of power plants that exploit the gravitational potential in one-sided and potentially dangerous way

In this case, however, it is possible to create motors capable of powering any type of source, be it electrical, through the use of an alternator, or mechanical. With the use of suitable gears, in fact, it is possible to directly produce motion as may be required, for example, in the construction of cars, buses, trams, boats, and various other applications.

In this way, since we are talking about an inexhaustible energy source, or at least so it is hoped, there will never be supply problems again; but from this series of considerations also derives another characteristic, namely that of being above all ecological, which is very important in today's world, because it has a zero environmental impact in any of its components, both atmospheric and acoustic.

As previously mentioned, this application is based on the development of the aforementioned patents, but which differs for these fundamental characteristics.

The patent filed in 1982, and registered in 1985 as a US patent, for example, was characterized by the presence of a Rotor having an asymmetrical shape with respect to the Axis of Rotation and where the motion was produced by a variable load, see, for example , Fig. 6 (a).

Asymmetry is of fundamental importance for the creation of motion, see Fig. 4, since only in this way is it possible to create a pair of forces that can then be used.

In the Italian patent filed in 1998, a symmetrical Rotor was created with respect to the Axis of Rotation, but the asymmetry necessary for motion was generated in the load point of the Fluid, see Fig. 6 (b).

It is known, in fact, that a body immersed in a Fluid having its own center of mass not coinciding with the center of thrust of the Archimedes force, receives a thrust equal to the weight of the displaced Fluid and is subjected to a torque of maximum forces. for an angle of 180 °.

In addition, two reservoirs were used in the previous treatment to create the source of the force.

The first container was used as an energy source, the second to achieve the hydraulic balancing necessary for the motion.

In this case, however, the entire application requires only the presence of a single tank.

As regards the definition of the angle, however, it should be remembered that this limit refers to the angle described by the centers of mass of the bodies subject to the Archimedes force, the result of the application of what in nature is defined as the principle of action and reaction.

In the current work the asymmetry in the load point remains, as in the 1998 patent, but a larger opening has been created, which thus allows to obtain more energy, and the load source has been unified, as well as creating a completely different structure for exploitation.

Furthermore, a more constructively effective form has been introduced, characterized by the fact that the flanges that connect the two components of the system can also be external to the structures that ideally contain them. what this allows a great ease in construction and cost reduction and, at the same time, an increase in construction precision and better maintenance management.

In this regard, referring to the definition of the angle in the load point (value always referred to the corresponding opening of the container) it is good to build it with an opening slightly wider than that theoretically allowed and which, in reality, refers to the angle traveled by the centers of mass, as already mentioned.

This orifice, in fact, could be constructed with a value that normally should not exceed (180 ° 180 ° / N), where 2 * N always highlights the number of segments into which the Rotor has been divided.

The previous considerations, however, do not require either that the number of elements be defined by an even number or, on the other hand, that the segments are all the same, a hypothesis which is the most logical and the easiest to make, but not the only one.

In the hypothesis of constructing the widest angle, it is good to realize the angle by adding the additional value of (180 ° / N) partly to the lower base and the remaining quantity to the upper one, as shown, for example, in Fig. 7 from the corner AOA '.

In this way, in fact, the angle traveled by the center of mass of each Closed Body of the individual Elements is actually equal to 180 ° and is widely and completely usable.

In any case, however, the previously defined value requires that the segments that make up the Rotor are all the same: in the other situations a certain figure should be taken into consideration before being able to describe the real additional width.

Furthermore, one could always foresee that the number of effectively active segments is N 1, (this consideration, however, which also concerns the extreme segments, which in the phase considered, could have, in one point, the thrust value equal to zero. ).

Likewise, however, the shape must be studied in such a way that the maximum utilization value is actually equal to 180 °

In the work we are going to analyze, the Rotor (3) is characterized by the fact of being built in its components in a symmetrical way in the form, but it has the peculiarity of having the shape of a cylindrical crown, a solid figure much more convenient to build, where each single Element (E) is connected to the others either directly, through a Labyrinth Structure (7) built in the Container (2), or separately, through the construction of ducts, in the case in which the coupling surface of the Rotor ( 3) is external, but always connected to the Labyrinth Structure (7), through a coupling surface, where each Element (E), which determines it, can have any shape;

and where the fluid contained in the container (2) must always be at a level higher than that of the rotor (3).

Only this last characteristic, in fact, allows to fully exploit the existing gravitational potential.

The construction of a connection surface between the Rotor and the Container outside the Rotor (3) would allow easier management both in assembly and in reducing production costs.

From a technical - constructive point of view, in this way the objective of reducing friction due to rotation is achieved, because it makes it possible to create smaller and, at the same time, cheaper rotating seals, a characteristic of the latter, due to a constructive simplification.

And, after what has been analyzed and highlighted in the previous points, it is also concluded that the main peculiarities of this work can be summarized in the following fact:

The maximum value that can be used by the thrust is obtained when the loading opening measured on the container (2) is 180 ° effective, and not, as in the previously mentioned patent, 180 ° - 180 ° / N, where N always refers to the number of Elements making up the Rotor.

Furthermore, in order to balance the force against the motion, the same structure of the Container (2) is used, and not of an external Container.

Ultimately, it is clear that the engine is composed solely of the container and the rotor, a hypothesis that is valid both in a logical and constructive context.

The use of a connecting element, the Element (15), built in the event that the coupling surface (4) of the Rotor (3) is external to the Rotor itself, is not functionally definable, as its purpose would be only that of a connection that would make the connection of the various components involved in the rotation; however it would be extremely important, for the purposes of the current discussion, because its construction would allow to have characteristics otherwise denied due to construction difficulties: think, for example, of the possibility of using a very large number of Elements (E), which would allow greater continuity in motion adjustments.

Furthermore, this hypothesis has the particularity of simplifying the couplings and reducing friction, since the main components, and the more complex ones, are easier to make.

Furthermore, the previous hypothesis would also create the opportunity to create more compact structures and much more rational systems in their configuration.

The present discussion aims at the design of an engine which has the characteristic of repeatedly exploiting what is represented, for example, in Fig. 1.

The left side of the Rotor (3), in fact, represents the active part of the Motor, a part which is subject to the Archimedes force and which owes its specificity to the fact of obtaining motion by canceling the opposite force, produced by Pascal's law and indicated with the value of (12), with a hydraulic balancing, realized, for example, with the opening of the Elements (E) represented by the angles BOC or BOD, as shown in Fig. 7.

Another typical peculiarity of this engine is to be found in the fact that the motion is rotational and non-linear like that produced by internal combustion engines which require a series of corrective interventions.

The present invention is realized through the construction of a Rotor (3), characterized in that it is composed of a set of Elements (E), composed in turn of one or more Closed Elements (6), whose mass is less than that of the corresponding volume of Fluid (F), and by an Empty Space (9), capable of being filled with the Fluid (F), and by one or more Openings (10) placed in each Element (E).

In this way the Fluid (F) present in each Element (E) can be connected with that present in the other Elements (E), and with that existing in the Container (2), through the Contact Surfaces (4) of the Rotor (3) and (5) of the Container (2).

In addition to this, it is determined that the Surface (5), present on the Container (2), see Fig. 1 (d) and (b) and Fig. 8, 9 and 11, is substantially identified by the Opening ( 11) which has the shape of about half of a circular sector defined by the angle of (180 ° 180 ° / N), seen previously, and built on the circular crown that covers all the Openings (10) made in the various Elements (E) of the Rotor (3).

The construction of the Surface (5), having the characteristic mentioned in the previous paragraph, serves to create the necessary asymmetry for motion.

The construction of Elements (E) that have more Openings (10), or possibly even more Closed Elements (6), although theoretically possible, does not seem to have any practical relevance at the moment; however, a particular application will be described below where this aspect may also be of some interest.

Furthermore, the system described above can be sealed, with all the Fluid (F) contained therein, by an actuator means (30) in order to create a constant quantity of Fluid (F) in the Rotor - Container system; the actuator means (30), then, can also be constructed in such a way as to transmit an additional pressure.

It is obvious that other solutions for the transmission of pressure can be considered: this fact, however, does not concern this discussion which aims to give a theoretical direction to the subject dealt with, leaving some details, even important ones, to other drafts.

If the Motor uses a Fluid (F) under pressure, it is advisable to configure the Element (30), and all the Openings (10), obviously together with the Motor structure, in such a way as to support the pressures used, but also to take into consideration the need to realize relief valves, in order to reset the existing pressure.

This assumption should not be necessary in the normal condition.

Through the Openings (10), and possibly also through the Surface (15), it is possible to make contact between the Fluid (F) existing in all the 2 * N Elements (E), contiguous or not, otherwise excluded, using the Opening (11), connected to the Labyrinth Structure (7).

This last component should then be managed by an electronic control unit, given the complexity of the control operations.

The Surface (4) of the Rotor (3), see Fig. 11 (a), is a surface normal to the Axis of Rotation (1) having the shape of a circular crown and is perfectly smooth and opposes the Surface (5) , see Fig. 11 (b), of the Container (2), which contains the Opening (11), see Fig. 1 (d).

The Opening (11), moreover, has inside the sealing rings, a series of valves, placed in correspondence to each Opening (10) of the Rotor (3), which are connected to a Labyrinth Structure (7) and which they are managed by normal combinations of closing or opening, thus allowing to connect all the Fluid (F) existing in the Rotor - Container assembly.

In conclusion, there is a valve of the Surface (5) of the Container (2) for each Opening (10) of the Rotor (3).

With a determined angle, indicated, for example, with the angles BOC and COD of Fig. 7, the position of the balance that opposes the resultant of the Archimedes thrust due to the component perpendicular to the Rotation Axis (1) produced is also determined by Pascal's law, that is the Element (12) of Fig. 1 and Fig. 7. The sealing rings that make up the two components of the Motor are normally different only in the material they are made of, see Fig. 1 (b) and).

It should be remembered, however, that the sealing rings offer a space that is more logical than physical, since the areas near the Openings (10), located in the center of the rings, are practically surfaces that have the same properties as the rings of which above, see Fig. 11 and 13.

Consequently, the logical area is generally larger than the physical area.

The term "sealing rings" will also be used for areas closely adjacent to the Openings (10), since this expression is more effective for identifying a specific function.

Although only one entity will be considered in this description, it can be assumed to have two different actuating means for the balancing functions: one, for example, to define movement in one direction only and the other, the Element (12), to counteract the force A contrary to motion.

Of the two, the first would have, for the most part, a safety function and, consequently, a feature that is not logically necessary and which is beyond the scope of this discussion: the second, on the other hand, the one that determines the hydraulic balancing, implicitly depends on how it is the driving force has been defined, i.e. from which part of the Rotor (3) the thrust is obtained.

From this point on, the Rotor (3) - Container (2) assembly can be defined as:

”GRAVITATIONAL ENERGY ENGINE

It is also good to dwell on what we have defined as the Labi Rintica Structure (7).

This very important part of the Container (2) concerns a fundamental aspect.

In the 1982 patent, motion was created starting from the assumption of having a Rotor (3) with an asymmetrical shape and connected to a fixed Container (2), equipped with openings in the base, so as to alternatively create motion.

This setting, although perfectly functional, had the defect of being impractical for the purposes of construction and, above all, of being able to present some limits in reliability.

With the current version this situation has been overturned by creating a structure where the Container (2) is no longer just a tank, in which to enter and store the Fluid (F), but it is a reality to be used continuously, and which is equipped with of all the fundamental peculiarities necessary for motion.

Furthermore, and this is a very important novelty, there is a single tank, this entity responsible for all the functions, contrary to what is reported, and required, in the 1998 patent.

In fact it is here that the Fluid (F) is found, which is the source of the gravitational potential, and which is used in the present work; moreover, the mobility of the Fluid (F), required by the motion, is obtained from the use of the Container (2), which must therefore be structured in such a way as to be able to take advantage of the peculiarity of its state.

And it is precisely for this reason that the Container (2) has been constructed in such a way as to always be seen as static in reference to the Rotor (3), so that its contents can activate each Element (E) to which the Force is applied. of Archimedes, and, consequently, can exploit it.

The motion obtained by the Element (E) must be seen relative to the Container (2), but to do this, the Rotor (3) must appear as static and for this it is necessary to create a hydraulic balance, or of any other nature, so such that the force described can be used.

In Fig. 2 (b), for example, the immersed body is subject to Archimedes' thrust, but this cannot be exploited.

To be able to do this, in fact, an environment must be created in which it is possible to create a pair of forces and, consequently, a resultant to be used.

If hydraulic balancing is created to neutralize the negative component to Archimedes 'thrust, a container must be created with respect to which the body subjected to Archimedes' thrust appears to be stationary and, only as a consequence of this fact, a couple of forces can be available. .

This is, in fact, the fundamental purpose of any form of balance.

To understand this argument well, see what happens in Fig. 2 (c) where, if a constraint is removed from the body immersed in the Fluid and, at the same time, it is assumed that the remaining one can allow motion to the body, a rotation with respect to the only existing constraint.

In other words, to be able to exploit Archimedes' thrust the body subjected to it must have a moment with respect to the point of rotation, which cannot be integral with the body.

In fact, in the construction of each Element (E) any form must be taken into consideration, but this must have only one characteristic, which is also its limit; this must be realized in such a way that Archimedes' thrust is always valid.

Conversely, nothing can be used.

From this it also follows that the Empty Body (9) can have an undetermined shape and volume, but it has a single constraint highlighted by what was previously explained: it must be built in such a way that Archimedes' thrust is always usable.

Consequently, the Empty Body (9) can have in some part of its volume the null volume, but never be totally null.

In fact, if Archimedes' thrust is not valid in every Element (E), it can never be used in the Element (E) considered and, consequently, it should not constitute a component of the Engine.

Furthermore, for the balancing of the forces, one could also hypothesize the use of a force based on an electromagnetic system, but this probably, in addition to being more expensive, would not be as accurate.

It is good then to dwell on another fundamental point.

When we talk about the Empty Body (9), and consequently the mass of the Rotor (3), we must remember that it is the Empty Body (9), once filled with the Fluid (F), that determines the thrust used and defines, therefore , the available energy; vice versa, the mass of the Rotor (3) is never directly involved in the work we are analyzing, but it is however very important for performance.

In fact, its prerogative derives from the consideration that a Rotor (3) having a high mass can create a great inertia and also reduce usable energy.

As a consequence of this it is advisable that the motor has a limited mass and, possibly, concentrated near the rotation axis.

The supporting structure of the motor can also be built with ferrous or, in general, metallic materials, but it is strictly essential that the various Hollow Bodies (6) are made with plastic or composite materials.

The Labyrinth Structure (7) on the other hand, has the characteristic, through the use of suitable openings that constitute the Opening (1 1) and which are made on the Surface (5), of being in the open or closed state and of always presenting a constant face, relative to the Container (2); in this way, in fact, it is possible to obtain the continuous exploitation of Archimedes' thrust.

We will see its peculiarities later.

Preliminary theoretical conditions:

The source of energy

Before describing the motion of the Rotor (3), it is necessary to analyze the energy component connected to the Archimedes thrust, since, since it is a motor, it is necessary to understand the origin of the energy source.

There are two types of reference systems in nature:

Isolated System - where either there are no forces or they are balanced.

Non-isolated system - where there are one or more forces.

To evaluate the influence of the interaction between the force of gravity and the position of the body, let's analyze the examples shown in Fig. 2 (a), (b) and (c).

In Fig. 2 (a) the body is free to float on the water.

In Fig. 2 (b) the body is constrained in one point, but is free to move around it; in this way it reaches its equilibrium position.

Finally, in Fig. 2 (c), the body is constrained and cannot move; if we observe the ideal flow lines, the isobars, we see that these are more curved than the point of Fig. 2 (a).

This means that some work has been done; by freeing the body, the same work done by the hypothetical external force that created those changes in state, can be recovered, provided that some fundamental considerations are respected.

Similarly, if we observe the isobars around a constrained body and where the pressure is greater than the atmospheric one, we see that they approach and, therefore, work has been done, see Fig. 5.

It is good to consider for the materials that make up the Rotor (3) substances that have characteristics of lightness and resistance to pressure, the latter characteristic which must also be present for the valves used.

From an interaction between Pascal's law and a free to move Element, nothing is produced; this, in fact, only reaches its position of minimum energy.

But if we exert a pressure on the liquid, compressing the floating body and constraining it in the position reached, the work done is given by the relation: L = P * V

and, since the only force existing in this context is due to Archimedes' thrust, it can be deduced that the work done assumes the value measured by the difference between the volume of the solid - the buoyancy volume;

and, if this is positive, there is the possibility of producing energy.

The system consisting of the Rotor (3) and the Container (2) constitutes a non-isolated system since the thrust to which the Rotor (3) is subject, together with any other Element (E), when it is in contact with the Container ( 2), it is normally not balanced.

Now let's analyze Fig. 2 (a), (b) and (c), where a very light Body (K) is shown placed in a container full of liquid: this is a situation that is comparable to that determined by the Element (E), whose mass is less than that of the identical volume of the Liquid (F).

It can be seen, see Fig. 2 (a), that the system is isolated, since the Element (K) floats, that is, it is in its natural state, that of minimum energy.

The system of Fig. 3, on the other hand, represents a non-isolated system.

The Element (K), in fact, is in this state, because it is possible to hypothesize the presence of a Force ϋ which has modified its natural condition and the difference (A'C '- B'C') of the liquid level measures the work that has been done.

If we determine the pressure on the base AA ', we see that this has increased; the increase in pressure is caused by the weight of the volume of the Liquid (F) in which the Body (K) is immersed, where the submerged part of the Body (K) has ideally been replaced with the Liquid (F).

That is, some work has been done and the energy consumed was previously indicated as L = P * V.

Another consideration immediately follows from this figure.

The work done leads to the consequence that the level of the Liquid (F), which generates the pressure P on the bottom of the vessel ΑΑ ', has increased, as shown in Fig. 3; from this it can be deduced that in this way the interaction due to the resultant of the force exerted by the hypothetical external force against the Fluid (F) is used as a source of pressure and, therefore, as an energy source.

This force uses, in fact, the reaction produced by the walls of the Container (2).

Since the thrust center to which the foreign body is subject is external to the liquid itself, it is obtained that in this case a minimum quantity of Fluid (F) is sufficient to obtain a great action.

Consequently, it is possible to exploit this resource as an energy source which can then be reused with zero waste of resources and which requires, among other things, the use of a small quantity of Fluid (F).

This situation is a direct consequence of Pascal's law.

This fact is very important, because it allows us to obtain two fundamental things.

The first generates Archimedes' thrust, based on the principle of action and reaction, and, since we are talking about a Body (K) forced to stay below its own buoyancy level, it is possible to obtain part of the energy consumed during this phase.

The second, as previously mentioned, allows to obtain great results with little liquid, thus limiting the weight and inertia of the motor.

Furthermore, since the increase of the pressure also determines the increase of the hydraulic potential, and since a force other than the force of <1> gravity is associated with this, it is possible to obtain energy.

When we talk about perpetual motion, the reference is always to an isolated system.

This is, in fact, the starting hypothesis of what is stated in thermodynamics.

Now let's analyze the energy content.

The Rotor (3) and the Container (2) are conceptually a communicating vessel.

A similar situation can be highlighted in Fig. 3, where on the left side a Body (K) is represented, having the shape of a cylinder that can be compared to the Rotor (3), object of this work, while on the right side there is only the force shown by the column of Fluid (F) present in the Container (2) and in contact with the Rotor (3).

A similar example can also be a representation of the hydrostatic paradox which defines the force currently available and which can be used, provided that the forces existing in the two opposite parts of the Rotor (3) are related.

If we analyze the external element that generates the thrust U in Fig. 3, we see that the Body (K) seen before, raises the level of the liquid from point BB 'to point C C, obviously, in both branches of the vessel communicating, this consideration is sufficiently clear;

more generally, if the Body (K) is bound and the Liquid (F) is poured into a branch of the communicating vessel, the same effect is obtained: and this is what will now be examined.

The hypothesis of a constrained body is very important, because its effect is comparable to that obtained through the activation of an external agent that does work, therefore it determines an energy source, while in the case of a free body, the energy transmitted would only increase the level of the liquid together with the float body, thus obtaining a normal increase in the hydraulic potential.

From this derives the fact that it is possible to hypothesize the replacement of a floating body with a quantity of liquid equal to the mass of the submerged body.

In this way, however, only the level of the liquid in the two branches of the container has increased.

The energy deriving from this work, on the other hand, is the difference between the level reached by the Liquid (F), when the bound Body (K) is submerged, less that dictated by the level in which this body floats: this exposure is represented by the difference (AC -A'B ') illustrated in Fig. 3.

And from this immediately follows the need to have a Body (K) with a very small mass.

Following what has been described above, special attention must be paid when talking about an increase in hydraulic potential, because in practice these are two very different situations.

In the normal position, that due only to the height of the body, the potential can only be exploited as a potential from position; while in the other, which is the object of this work, a repetitive system is obtained, as the increase in potential is due to a series of frequent and continuous actions, even if, apparently, this action is carried out in a system reference indicated as static.

In the first case, in fact, the hydraulic potential is used only once, developing energy from position, in the other hypothesis, however, provided that the Body (K) or the Element (E) always remain below the level of the Fluid (F ), this limitation and feature is no longer valid.

This peculiarity is of fundamental importance: the hydraulic potential from the position of the Container (2) is not exploited, but the interaction between the hydraulic potential generated by the gravitational field and the Constrained Body, whose mass is less than that of the identical volume of the Fluid. (F) corresponding.

Now we can assert that it is the hypothetical Foreign Body that generates the increase in pressure on the base of the vessel, even if this is nothing more than the consequence of Pascal's law; and the Archimedes thrust that is obtained is the resultant application that allows to exploit this force.

From the analysis of Fig. 2 (c) and (b) we see the characteristic we are examining; in fact, if we remove the constraint that holds it still from the body represented in part (c), we obtain, in the hypothesis that the remaining constraint allows it, that the body moves and exploits part of the energy due to the gravitational potential of the Fluid (F) : if this is not possible, or due to natural or constructive problems, it would generate, however, a pressure on the remaining bond which could also lead to its breaking.

In any case, however, this would demonstrate what we are examining.

Furthermore, since it refers to a non-isolated system, it is not at all possible to speak of perpetual motion.

And more precisely, if the value of the segment HH 'of Fig. 3 is analyzed, the following is obtained:

where ÀR = Archimedes thrust

mK * g = body weight

mL = mass of the liquid

OR = resulting force applied

Static field.

ÓR <0 There are no forces

HH '> 0 and ÓR = 0 there is a static range.

The flow lines of Fig. 3 in the left branch are curved and this demonstrates the presence of an external force ϋ which has done some work, evidenced by the increase in the hydraulic potential indicated by (CC - BB '), but not a force is attached, and therefore this cannot be used.

Dynamic range.

ÒR> 0 HH '> 0 and m ic <mL there is a force.

OR = Àr- mk * g which keeps the Body (K) constrained and is directed downwards, that is, along the direction and the direction of the gravitational field.

U and Oks are the same in module and differ in the direction of application (principle of action and reaction and conservation of energy).

When moving in the direction of a field, energy is taken away from the field itself: therefore, in this case, it is the gravity field that provides the energy to increase the hydraulic potential.

Furthermore, there is a force: from this it can be assumed that it is possible to make an energy exploitation.

The Rotor (3) and the Container (2) are equivalent to the communicating vessel of Fig. 3, in which Rotor (3) is constrained to the clockwise movement, as illustrated in Fig. 7, by an actuator means (or by a hydraulic balancing) which also balances the counter-motion force À, indicated with the Element (12).

Remember that each Element (E) of the Rotor (3), when it comes into contact with the Fluid (F) contained in the Container (2), behaves like the Body (K) of Fig. 3 and the analysis of the flow highlights it, or, more precisely, each Element (E) of the Rotor (3) is identified with the Constrained Body (K) and is subjected to a pair of forces, see Fig. 4, with respect to the Rotation Axis (1 ).

In summary, it is possible to state that the Gravity Field has provided the energy used, and since energy and force are functions of the gravity field, that is, of the acceleration of gravity G, when this is zero, or is balanced, the engine does not run.

A typical example can be seen in the construction of an engine to produce electrical energy in a spacecraft, placed in Earth orbit; here, under normal conditions, nothing would be obtained, however ....!

The difficulty of what is exposed is in the association of a force to the hydraulic potential, because usually the resultant of the Archimedes thrust, to which each Element (E) of the Rotor (3) is subjected, when it is connected with the Container (2), cannot be used, as it passes through the Rotation Axis (1), i.e. it is in stable or unstable equilibrium conditions, depending on where the thrust center is.

After this introductory note, let's analyze the beginning of the work.

As a boundary condition, however, it is good to remember the existence of the constraint on the speed of sound in the Fluid (F) used.

In fact, the transmission of pressure, a condition that determines the possibility of using the engine in question, has this physical characteristic as its limit.

In most cases, however, this limit is not very important, since, even if the Fluid (F) used was water, this limitation would be irrelevant and such as to create problems of a practical constructive nature and not a theoretical application.

In any case, however, an example will be given below of the potential energy produced by this engine which also has the characteristic of presenting a very high and easily obtainable torque.

General consideration.

After examining the general characteristics of the energy source, let's take a closer look at the structure of the engine.

As we have stated, we build a machine made up of two components:

a Rotor (3) and a Container (2), placed in communication through flanges, identified as the Surface (4) of the Rotor (3) and the Surface (5) of the Container (2), and made integral with the use of suitable supports, at the same Rotation Axis (1), where this is in a non-vertical position.

Furthermore, in the Container (2) there is a small container, defined as Labyrinth Structure (7), equipped with one or more valves which allow, through the Opening (11) and according to appropriate operating logics, the selective connection between the Fluid (F) present in the Container (2) itself and the various Elements (E) of the Rotor (3), in order to achieve an appropriate application in the use of the Gravitational Energy Motor.

We also remember that the Labyrinth Structure (7) can also be built externally to the Container (2), a feature that does not invalidate what is logically defined, but depends only on construction needs: this fact, however, does not affect the presence of the Opening (11) which always remains defined in the same way.

The Rotor (3) consists of a number of 2 * N of Elements (E), possibly equal.

This hypothesis, as we have seen previously, is the most logical one, because it allows a simpler management both operational and constructive of the Motor; moreover, it is the easiest one to manage through the use of an electronic control unit, but it is not the only one.

Along with this, it should be remembered that this application allows for greater precision in the construction of the hydrodynamic equilibrium point.

Another fact, however, must be taken into consideration in the design of the Rotor (3).

This hypothesis derives from the consideration that the dimensions of the Empty Spaces (9), within the individual Elements (E), must be as small as possible.

In fact, if on the one hand it is true that empty spaces are fundamental for motion, when they are filled with the Fluid (F), as they are the generators of Archimedes' thrust, on the other hand they can constitute a considerable inertia.

In addition, they also limit the energy that can be obtained.

To obtain the result of minimizing the volume, loading areas can be built where, in some points, the internal space, the Empty Space (9), is also zero.

To this end, it is sufficient to verify that the hydrodynamic thrust is not zero; the limits, in fact, are those of the validity of Archimedes' law.

Another required element is the lightness of the Empty Bodies (6), since the hydraulic potential that is created with Pascal's law, and its subsequent application determined by Archimedes' thrust, is exploited only for the upper part of the index of buoyancy.

Therefore, the lighter the body, the greater the usable hydraulic potential.

The sealing rings, the Surfaces (4) and (5), must also be made of materials which offer the least possible friction and which, at the same time, close the Fluid (F) present inside.

The hypothesis highlighted above, i.e. that of the construction of the coupling surface of the Rotor (3) with the Container (2) external to the cylindrical crown, allows, in the construction of large rotors, to have small contact surfaces and, consequently , a reduction in the friction surface, as well as presenting simplifications in assembly.

This feature, however, is not the only one; in fact, with the construction of small coupling surfaces it is possible to have a much higher mounting precision and to obtain, at the same time, a reduction in production costs.

In addition, they offer the possibility of building more compact motors.

The realization of the Surface (15) to create the connection between the Rotor (3) and the Container (2) does not create great difficulties, as it is a simple structure and, despite the required precision, it offers the possibility of using mobile elements, reducing thus, the constructive complications.

Consequently, the realization of an external Structure (4) can be much cheaper both from the construction point of view and from the economic point of view, where, among other things, by cost-effectiveness we also mean the value of maintenance.

Similarly to what we saw for the construction of the Surface (4) external to the Rotor (3), it would be conceivable to create the Surface (5) of the Container (2) external to the Container (2) itself, in order to make flexibility at the highest levels .

This could require the construction of a connecting element, defined, for example, Surface (16), which would be suitable to be placed between the Surface (5) and the Labyrinth Structure (7).

In summary, the Gravitational Energy Motor could be determined as composed of:

a moving part:

Rotor (3) → Element (E) → Surface (15) → Surface (4);

and from:

a fixed part, starting from the contact surface with the rotor (3):

Surface (5) → Surface (16) → Labyrinth structure (7) - → Container (2).

With regard to the Rotor (3), the individual Elements (E) are, as seen previously, isolated from each other and are connected to the Container (2) through the Labyrinth Structure (7), which also allows the connection of the Fluid (F) contained. in every part of the engine.

The connection between the Fluid (F) in the two main components of the Motor takes place through the Openings (10) placed in each Element (E): these holes are opposed to the Opening (11) which is obtained in the structure of the Container (2) and is formed, in its active component, by a part of a circular crown with in the center, one for each Element (E), an opening having the shape, for example, of an ellipse or an ellipsoid connected to each other, figure comfortable but absolutely not binding, see for example Fig. 1 (b) and Fig, 1 (d).

These steps allow to construct a practically continuous Opening (11) which corresponds to the maximum value of the use angle equal to at least 180 °, and, in the case where 2 * N always represents the number of Elements (E) of the Rotor in question, allow to connect also N 1 Elements (E) for the realization of the motion.

The peculiarity of the Opening (11) consists in the fact that, as previously explained, it must contain inside the openings, placed in correspondence with the Openings (10) of each single Element (E), and that these openings are necessary to generate the motion, see Fig. 11 (a) and (b), as they serve to transmit the pressure existing in the Container (2), ie the gravitational potential which constitutes the energy source.

The only logical and constructive constraint to which the holes represented on the Opening (11) are subject derives from the fact that the distance between two ellipses, or ellipsoids or any other type of figure is drawn, is less than the diameter of the Opening. (10), so as not to have pressure losses.

Furthermore, these ellipsoidal openings determine a shape due to the fact that the individual parts of the circular crown on which they are configured must be closed, and are determined by the fact that in this way it is possible to manage with greater precision and ease of construction, compared to the creation of continuous opening, the need to make hydraulic seals.

Furthermore, hydraulic seals can be made by constructing underlying inlets to reach the connected valves, thus leaving the upper part of the contact surface with the task of sealing and the one below with the function of connecting the Fluid (F).

The valves, whose construction is as free as possible, obviously without prejudice to the operating logic, can be made in various ways.

Another constructive hypothesis could be to create the holes making up the Apertura (11) through the use of circles, even small ones, one for each Element (E), which are connected, through the creation of small circular sectors, ( see, for example, Fig. 11 (b) and the representation of the angles TOT "and T'OA") to the other openings, where obviously, the salient characteristics are those seen in the previous paragraph and used for the alternative form analyzed.

Normally the connecting circular crowns, which refer to the Surface (5), could be a few millimeters, as well as their depth, while for circular openings, a diameter of five millimeters would be more than sufficient.

As stated above, the logic should be, for example:

- Closed, position 0

- Open, suitable for hydraulic balancing, position 1

- Open, for the connection between the various Elements (E); position 2 for connection with the lower element and 3 with the upper element, for example.

If we analyze the drawing of Fig. 7 we determine the existence of a Rotor (3) with the Axis of Rotation (1) parallel to the ground and the circular section on view, where the hydraulic balancing is set on the right side, while in the left one, where there is an opening equal to at least 180 ° which connects the Fluid (F) contained in each part of the Engine, the Archimedes thrust is generated which operates on all the Elements (E).

Now if we measure the pressures on the bottom of the Rotor (3), in its two parts, we see that these are identical; therefore the Rotor (3) is in equilibrium, even if in the left side a force has been created due to the interaction of Pascal's law; this, in practice, is the demonstration of the hydrostatic paradox.

As we have seen in the previous pages, the resultant of the applied forces creates work, so there is energy that can be used.

Now it is appropriate to examine the importance of the Labyrinth Structure (7), located in the Container (2), which must be built to distribute the Fluid (F) in every part of the Motor, and which in its essence is reproduced in Fig. 10.

This Structure determines the connection with a series of elements arranged in an asymmetrical way and able to create motion under the thrust of a force, that is the thrust of Archimedes, hereinafter referred to as ÀR.

Furthermore, this structure allows to distribute the various forces that operate in the engine.

If a pressurized Fluid (F) is used, it is advisable to study any optimizations necessary for the reduction of surface tension resistances due to the movement of a Body (K) in a Fluid (F).

These will be generated at the melting point between the individual Elements (E) and the Labyrinth Structure (7) present in the Container (2).

The latter, in fact, can be represented as a particular valve, or as a series of valves, the purpose of which is to transmit pressure in every part of the Rotor.

It is this reality that allows the positive part of the Rotor (3) to distribute the thrusts and to be able to present new active Elements (E), in order to define a structure that allows to exploit, in a repetitive way, the hydraulic potential due to the force. of gravity.

This component is simple to make conceptually, see for example Fig. 1 and 7, but it is more complex in practice.

MOTORCYCLE DESCRIPTION.

It is good to analyze Fig. 1 which gives an overview of the Gravitational Energy Motor; and from this we can understand what we are going to examine.

Once the Fluid (F) has been, in a first phase, introduced into the Motor through the Element (30) and that the Openings (10) are all in the open position, to allow the Fluid (F) to reach any the empty part existing in the Engine, the Element (30) is closed, a condition which is used even in the presence of means capable of transmitting a state of pressure.

This starts the engine starting procedure.

As we have previously mentioned, the system starts up only if the part of the Rotor (3) is open, corresponding to the Opening (11) present on the Container (2), which has an angle in the center equal to at least 180 ° and where the sides of the angle are perpendicular to the Axis of Rotation (1).

In this case, the value of the angle represented refers to that described by the thrust centers of each single Element (E) which is subjected to Archimedes' thrust;

and where, the amplitude of the angle of the Aperture (11) can also be increased by an additional angle equal to 180 ° / N; consequently the active phase of the Motor is generated by N 1 Elements (E), even if the extreme ones could have zero thrust in one point.

Furthermore, the direction of rotation of the Rotor (3) is determined, which is a function of the Openings (10) which are in the open or closed state, and it is also defined which Opening (10) should be used to achieve the balancing. hydraulic.

It is then possible to create a more complex structure, in case you want to compensate for any inclinations of the Rotation Axis (1).

In this case all the Elements (E) must be redefined, as the starting positions change.

Obviously, the need for an electronic control unit derives from this case. Despite everything, however, this fact describes the flexibility of the system we are examining.

Let us now suppose that we operate according to what has been described in Fig. 7; in this situation it is defined that the direction of rotation is clockwise, because the thrust to which the motor is subject is that determined by Fig. 10, where the hydraulic balancing angle is identified by the angle AOB or BOC, of the same figure . To be able to start the motion we must close all the Openings (10) located on the right side of the same figure, excluding the one used for hydraulic balancing. In this way, the load asymmetry necessary for the motion and staticity, caused by the hydraulic balancing, of the Rotor (3) with respect to the Container (2) are created.

It should be emphasized that the motion is generated by a component relating to the fixed structure, that is the Container (2), and consequently the movement of the Rotation Axis (1) is generated by the movement of the Rotor (3).

The change of the direction of rotation is obtained simply by inverting the open Openings (10) with the closed ones.

Furthermore, since the power is produced by the number of Openings (10) in the open state in the active part of the Rotor (3), it is sufficient to open or close the latter to vary the power expressed by the Motor.

Furthermore, it is possible to reduce the power by increasing the number of openings (10) in the open state.

The hypothesis of opening more Openings (10), to reduce the power, derives from the fact that two Elements (E), which are in opposite positions of the Rotor (3) with respect to the Rotation Axis (1), have as a result the zero value.

It is in this hypothesis, in fact, that the peculiarity of the use of an even number of Elements consists.

Let's go back to what was highlighted in the initial part of the discussion, that is, the creation of more Contact Surfaces (4): this feature could be required in case you want to manage the change of the direction of rotation.

In fact, two Surfaces could be constructed (4); through the first one to realize the motion in one direction and in the other, built at the other pole of the Rotor (3), the opposite direction of travel; in this regard, see, for example, Fig. 14.

This fact, obviously, would require the realization of a second interface (5) and of another Apertura (11), having the same identical peculiarities seen previously and also those we are going to deal with.

It is obvious, however, that only one of these Surfaces would be active; the other would come into operation only when required and would always be managed by the Labyrinth Structure (7), which would also be responsible for defining the states of opening and sorting the pressure of the Fluid (F).

In Fig. 14 reference is made to two possible Surfaces (4), where the Rotor (3) has been replaced with the Rotor (31); this is composed of the same Rotor (3) and two truncated cones, where the major base of the truncated cone is connected with the circular surface of the cylindrical crown.

The truncated cones are built in the same way as the Rotor (3) previously described and have 2 * N Elements inside that connect to those of the Rotor (3), forming a single body that can also be equipped with three Empty Bodies ( 6).

These truncated cones will be indicated as the Element (17) and, in the reported case, have their major bases coinciding with the circular surface of the cylindrical crown; however this may not be the only solution, because one could imagine a reality where this coupling is not coincident.

A typical example would be the one where the base of the truncated cone would be larger and thus create a space where it is possible to build part of the Container (2), increasing the compactness of the Gravitational Energy Motor.

This application would involve the construction of a power unit for cars, for example.

This realization, although more complex and expensive, would have the advantage of being able to create more compact units and find applications in every product sector where this feature is required; the previously mentioned case is a simple example.

Furthermore, it is possible to take into consideration a complementary reality to that examined previously.

The representation that was made in the previous paragraph, in fact, could be defined as a Rotor (31) characterized by a structure that would take the form of a convex figure or, more precisely, mono or bi-convex (depending on the presence of a or two truncated cones) whose cusps would be determined by the minor bases of the truncated cones.

The complementary shape would give rise to a concave or, better, mono or bi-concave shape, where the minor bases of the truncated cones would be turned towards the inside of the cylindrical crown thus creating one or two cavities.

The two forms represented are alternatives and could also be used for identical product sectors, albeit with different purposes.

At the same volume, however, the bi or mono-concave structure would have the advantage of having a greater torque.

It is also good to remember that the level of the Fluid (F) present in the Container (2) in the reference condition, i.e. the one where the Rotation Axis (1) of the Motor is parallel to the ground, must always be in a upper point, or at most, equal to that of the Rotor (3).

Otherwise, in fact, there would be a loss of load up to the extreme point which would imply the absence of motion, since there would be no gravitational potential to exploit.

Now consider very carefully Fig. 7.

The various segments into which the Rotor (3) has been divided, and which are displayed with values ranging from number 1 to number N, indicate which force each Element (E) is subjected to.

The Element (1), for example, has its own component, the Closed Element (6), which is subjected to the thrust of Archimedes; this, with respect to the Axis of Rotation (1), forms a pair of forces with a non-zero resultant, which tends to move it clockwise.

In fact, the other force that acts, and that pushes the Rotor (3) counterclockwise, a force that we define with A, is balanced by an actuator means (12), which can simply be obtained with the pressure of the Fluid (F) present. in the Container (2), through the opening, for example, of the inactive Elements BOC and COD of Fig. 7. Then the Body (6) of the Element (1) is subjected to a force, with reference to the Axis of Rotation (1), as if it were a static body.

Consequently the force to which it is subject is totally exploitable.

This, of course, is repeated for each Element (E) that forms the Rotor (3); when the Engine starts and the Element (1) is on the right side of Fig. 7, the valves that connect it to the Container (2) are closed and, consequently, it is no longer an active part of the motion.

In contrast to it, however, the Element (N 1), which at first was closed, in the sense that its Closed Body (6) did not feel the pressure transmitted by the Container (2), opens the valve, through the Surface (11), which puts it in contact with the Fluid (F) it contains, and which connects with that present in the Rotor (3).

The existing pressure makes its effect felt, i.e. the Fluid (F) found in the Container (2) would tend to drop, but this is not possible due to the presence of the Fluid (F) previously introduced in the Element (E) in question. ; on the other hand, however, the pressure of the Fluid column (F) present in the Container (2) is transmitted, making possible the energetic activation of the corresponding Element (E).

To understand what has been stated, it is good to examine Fig. 2 (b) and (c), which indicate in a simple way the situation we are analyzing and which highlight what has already been stated previously: the fundamental importance of using very light bodies and, that is, how, see for example Fig. 3, it is possible to determine the existence of a state in which the gravitational potential is transmitted, with the consequent possibility of exploiting it.

This fact, however, requires presence as a force; Archimedes' thrust, for example.

And from this derives the practical use that interests the present discussion and that allows to obtain energy without any apparent effort.

Obviously, this state applies to each Element (E) of the Rotor (3); this illustration is represented, in schematic form, by Fig. 3.

Now go back to the starting hypothesis, the one where it was set that all the Openings (10) of the single Elements (E) were open.

Furthermore, the indication of the angles BOC or COD of Fig. 7, to determine the hydraulic balance, is represented by the extreme position of an Element (E), that is the Element (N) or the Element (N + l), position indicated by the angles F'OA 'and FOA of the same figure, which make the most of the Aperture (11), thus highlighting the characteristics of the Motor.

From this, assuming that:

H = Rotor width (3)

R2 = outer radius of the Rotor (3)

Ri = internal radius of the Rotor (3)

DF = Liquid Density (F)

IR = Angular momentum of the Rotor (3)

g = acceleration of gravity

it can be deduced that the force exerted is:

placed at a distance of indicative of

L = 1/2 * (R2 + RI), value referred to the Element (E) perpendicular to the Rotation Axis (1).

The total Archimedes thrust generated by the Fluid (F) is given by:

where the summation extends to all the segments that generate the motion

and, where, Ps = mass of the Rotor (3).

Assuming the Fluid is sea water, where density is measured by;

and where, moreover, the speed of sound is = 1460 mt / sec;

we obtain, therefore, as a first approximation, since the figure of the Motor is not completely defined, and supposing, also, that the mass of the Rotor (3) is 20 Kg, and where, moreover;

R2 = 0.3 mt

Ri = 0.1 mt

H = 0.6 mt,

that the available power, after 1 sec., is 25 HP.

By examining the above data, it can be deduced that the maximum value reached for the rotation of the Motor is about 2400 / revs per sec.

This is a huge value, which, approximations aside, describes the potential of this equipment.

Any other characteristics can only be determined when the construction of the Rotor (3) is defined in every detail.

In any case Ps is indicative of the force that limits the motion, and consequently, it is the component that must be reduced with appropriate constructive choices, as previously highlighted.

Furthermore, the Rotor (3) is characterized in that it can be connected via a mechanical transmission, the Element (13) (e.g. a gear reducer) to a user device such as a vehicle, plane, ship, alternator or any peripheral that can exploit this force.

From the application point of view, this invention provides high advantages due to. the complete lack of any form of pollution produced and the fact that it can produce great powers, without difficulty in environmental or logistical installations.

Further features and advantages of the Motor, according to the present invention, will be highlighted by the description, with reference to the attached drawings, which will be provided and which constitutes a non-limiting example of the application we are analyzing:

Fig. 1 - Example of the Gravitational Energy Motor complete with the Rotor (3), which has the shape of a cylindrical crown and where R2 represents the outer radius and Ri the inner radius, and of the Container (2), which contains the Labyrinth Structure ( 7), Fig. (C); also highlighted the Connection Surfaces, i.e. the interfaces (4), see Fig. (b), and the interface (5), see Fig. (d), between the Rotor (3) and the Container (2).

The Surface (15) is also represented, an element of union between the Rotor (3) and the Container (2), through the Surface (4), when the latter is external to the Rotor (3), and the Surface (16 ), connection between the Container (2) and the Surface (5), when this is external to the Container (2).

The highlighted motion is clockwise.

Also depicted is the system of gears designed to exploit the motion, the Element (13) and the force A contrary to the motion, that is the Element (12).

Fig. 2 - Example of a free body in a container containing liquid:

(a) - Free body that floats normally.

(b) - Body fit to float, which is under the link index, and constrained at a point. In this case the Body is subject to a couple of forces with respect to the constraint.

(c) - Body able to float, completely bound, and immersed in a Fluid (F)

Fig. 3 - Example of a Body capable of floating and immersed in a branch of a communicating vessel where there is an external force U which compresses it.

Consequently the level of the Fluid (F) rises and this represents the work done.

Fig. 4 - Pair of forces to which a Body immersed in a liquid is subjected if the center of thrust and the center of mass do not coincide.

Fig. 5 - Light body pushed by a force P below the floating point which allows to recover the effort made.

Fig. 6 - Example of the asymmetry necessary for the motion shown in the analyzed patents:

(a) reference to the year 1982

(b) reference to the year 1998

(d) referring to the year 2010, where, however, the Rotor (3) takes the form of a cylindrical crown that exploits a greater passage.

Fig. 7 - Representation of the Rotor (3) with the single active forces.

In this case the determined motion is clockwise. Furthermore, the thrust contrary to the motion, the force A, indicated as the Element (12), and the maximum opening angle, indicated with the angle AOA ', and the hydrodynamic equilibrium points, the angles BOC and COD are also represented. .

Fig. 8 - Section of the cylindrical crown that defines the Rotor (3) with the Elements (E) that compose it; furthermore, the Empty Body (9) and the Closed Body (6) are indicated.

Fig. 9 - Single Element (E) of the cylindrical crown.

Fig. 10 - Overall view of the Rotor (3) in its individual Elements (E) suitable for motion and made integral with the Rotation Axis (1).

Highlight the Feed holes (10), referring to the Opening (11). Fig. 11 - Detail of the connecting flanges between the Rotor (3) and the Container (2), indicated as the Surface (4), Fig. (A), and the Surface (5), Fig. (B), with reference to the individual coupling elements.

Also represented is the Surface (11), which allows to connect the Fluid (F) in every part of the Motor, and which determines the motion.

Fig. 12 - Example of the Labyrinth Structure (7), with the various connections, which defines the motion of the Rotor (3) and its direction of rotation.

Fig. 13 - Example of the Contact Surface between the Rotor (3) and the Container (2).

The Surface (4) is represented, incorporated in the Rotor (3), and the external one, the Surface (15), connected to the Rotor (3) through a series of channels. Also represented is the eventual external surface (16), the joining element between the surface (5) and the labyrinth structure (7).

Fig. 14 - Example of a Rotor, biconvex * shaped built by the union of three geometric figures, two truncated cones and a cylindrical crown, with the major bases coinciding, which thus identifies the Rotor (31).

Fig. 15 - Example of Opening (11), made up of a series of orifices having different radii, and where the sum of their amplitudes can also be greater than Opening (11).

And now, after having taken into consideration the legend of the attached drawings, which should give a more precise idea of what we are analyzing, let's review some practical and theoretical evaluations regarding this study.

The number of Elements (E) that make up the Rotor (3) is not binding. It can be deduced, however, that the Element (9), i.e. the empty space of the Element (E) used for filling the Fluid (F), must be as small as possible.

Furthermore, after what has been seen previously, it is appropriate that for each Element (E) there is a single Closed Element (6).

Although this condition is neither a constructive nor a logical constraint, it represents, however, the best consideration for obtaining more practical and economic results.

It is good to remember that to have the maximum thrust it is necessary that the Apertures (10) are all in the open state, in the part that generates the motion.

However, if we want to vary the force available, it is possible to decrease the number of open Elements (10), or to increase the number of open ones so that the resultant, with the opposite ones, has zero value.

From this fact also derives the characteristic that would require the presence of an even number of Elements (E).

After having examined the salient features of this application we can see a different shape of the Rotor (3), already previously introduced, and which could be a compendium of what we have seen previously.

This application, in fact, in the face of a greater constructive complexity, could, however, be very useful for the construction of compact motors.

It is possible to set the shape of the Rotor (3), for example, in such a way that it is composed of a cylindrical crown and one or two truncated cones; the truncated cones then have their major bases attached to the lateral faces of the cylindrical crown and are coaxial and integral with the Rotation Axis (1).

The major bases of the truncated cones may have a different surface from that of the circular crown.

Furthermore, the two (or one) truncated cones are composed, in turn, of a number of 2 * N Elements, and are connected to the Elements (E), analyzed first for the Rotor (3), so as to form a single Element (E), which can also be equipped with several Empty Bodies (6), and which contemplate all the previously developed characteristics.

This structure could be named as a mono or bi-convex body.

A typical application would be that where the major bases of the truncated cone would be greater than the cylindrical crown; in this case the space would be created to build the Container (2) inside.

In this case, then, the Contact Surface (4) of the Rotor (3) would be configured on the smaller base of the truncated cone.

This new realization, to which the name of Rotor (31) will be attributed, could be further modified, according to specific applications concerning particular product sectors.

In any case, however, all the considerations reported here indicate the flexibility of this engine which can be used for very different purposes.

The Elements (E), in the case just introduced, could be composed of several Empty Bodies (6): this fact would assume a particularity that it did not have before.

We could then consider a figure where the truncated cones would be turned towards the inside of the Rotor (31), thus creating a mono or biconcave structure.

This solution could be convenient for Rotors to be inserted in narrow environments.

To this reality we could then also add the construction of an Opening (11) equipped with several holes, having a different radius, and where the total value of the passage could be greater than the Opening (11) itself.

In Fig. 15, a representation of this solution is given which could be taken into consideration to build more compact structures of the Rotor (3), where the Surfaces (4) and / or (5) would be external.

After what has been previously explained, however, we must draw another very important hypothesis.

Due to its construction characteristics, the Gravitational Energy Motor has a very important constraint.

This, in fact, is a self-exciting system, that is, if it is not slowed down in some way, or speed regulated, it will always tend to move until it breaks.

It is necessary to build an electronic control unit which, with an appropriate software, manages what has been seen previously, and thus regulates the motion, so as not to incur this inconvenience.

It could be useful, in some cases, to increase the number of Elements (E) that make up the Rotor (3) (or all its variants), in order to have a more precise regulation of the power, even if this, obviously, could lead to more constructive complications.

As a final consideration of this work it is possible to consider the construction of an engine with infinite energy and power.

This hypothesis could, perhaps, be seen as a theoretical exercise, but in reality it illustrates the characteristics of this Engine whose only limit is that it has no limits, at least theoretical.

Here we do not consider this possibility, even if its construction is actually very simple, at least theoretically.

The realization of the Gravitational Energy Motor does not present enormous conceptual difficulties; the only essential necessity derives from the realization of an electronic control unit to be able to manage the various phases of the movement, and from the use of materials that must be light and resistant at the same time.

With this, in fact, and with a particular Labyrinth Structure (7), it is possible to create a form of control that allows to solve the problems of reliability and operation.

Without this control unit it would not be possible to manage an engine that is conceptually simple, but slightly more complex in its management.

It is also good to specify a point.

We have often spoken of a Labyrinth Structure (7); this, in essence, is represented by a series of valves that serve to manage the transmission of a pressure.

From the construction point of view, we can think of creating a valve for each Opening (10), a valve that we can combine with the Surface (11), and which constitutes the passage for the connection of the Fluid (F) between the Container (2) and the Rotor (3).

And in the event that a pressurized Fluid (F) is to be used, it would be convenient to use, in any point of each single Element (E) of the Rotor (3), a valve to reduce the effect of the existing pressure, so such that, at the subsequent transmission of the pressure, there could be greater confirmation of the gravitational potential transmitted.

In this discussion we do not plan to analyze this topic, because we believe that what has been previously explained may already be sufficient to determine a remarkably wide use of this type of engine, leaving this aspect to other and subsequent considerations.

Naturally, the principle of the invention remaining the same, the details of construction and the embodiments may vary widely with respect to what has been described and illustrated purely by way of example, without thereby departing from the present invention.

Claims (14)

CLAIMS 1. Gravitational Energy Motor, characterized by the fact of being composed of a set of Elements subjected to Archimedes' thrust, and which is built with: a Container (2), capable of being filled with a Fluid (F), or in any case with a substance that in this application appears in the liquid or gaseous state and, where, the form is absolutely not binding; moreover, it has the characteristic that a Labyrinth Structure (7) is built inside it, able to control the connection between the Fluid (F), present inside, with that existing in the Rotor (3); and a Rotor (3), which has the shape of a cylindrical crown, where R2 indicates the external radius and Ri the internal one, and which is made up of a number of 2 * N Elements (E), integral with the Rotation Axis (1). The Rotor (3) is then connected, through a series of gears, highlighted with the name of Element (13), built either directly on the Rotor (3) itself or on the Axis of Rotation (1), to a user machine; moreover it has on the circular crown, a section of the cylindrical crown perpendicular to the Rotation Axis (1), of the Openings (10), at least one for each Element (E), which allow the passage of the Fluid (F) in every part of the Engine; and where the annulus, or a part thereof, constitutes the Contact Surface (4) between the Rotor (3) and the Container (2). In addition to the above, the Container (2) is equipped with a device (30), suitable for introducing and sealing the Liquid (F); and a Coupling Surface (5) to the Rotor (3), which offers the possibility to the Fluid (F) it contains to connect, through the Surface (11), to that present in the other parts of the Rotor (3); and also, that the Surface (11), defined on the Surface (5) and having the shape mainly of a part of a circular crown, represents the Surface of the Container (2) which is opposed to the Surface (4) of the Rotor (3), and is characterized by the fact that it is normal to the Axis of Rotation (1); and that the Surface (4) and the Surface (5) have the characteristic of being perfectly smooth and able to rotate and crawl and, at the same time, to prevent the Fluid (F) contained in the Motor from escaping. It is also possible to hypothesize the creation of the Surface (5) external to the Container (2), using in this case a Surface (16) which connects to the Labyrinth Structure (7) and to the Surface (5) through an interface, even if not fixed. . The Container (2) must be constructed in such a way that the level of the Fluid (F) contained in it, in the condition of normal use, i.e. the one where the Rotation Axis (1) is parallel to the ground, is always at a height higher than that of the Rotor (3): and where this feature is extended, if possible, to every position. The Surface (5) of the Container (2) is then composed, or is in contact, with the Labyrinth Structure (7) which, by means of suitable cavities, determines Γ Opening (11); and where this passage is built practically continuously and has the peculiarity of being made with an angle in the center equal to at least 180 °, a value which determines the active phase of the motor. Furthermore, Γ Opening (11), through the use of a series of valves controlled by a control unit, possibly electronically controlled, makes it possible to make contact between the Fluid (F), present in the Container (2), with that existing in the Rotor (3), in such a way as to create a common environment; and where the Fluid (F) must be able to reach all parts of the Rotor (3), even in a selective manner; and where the sides of the angle corresponding to the value of 180 ° are perpendicular to the Rotation Axis (1), to which it is usually possible to add an angle of 180 ° / N, partly to the upper side and partly to the lower one, in such a way that the actual number of elements (E) that can be connected can also be N l. Furthermore, the Opening (11) consists of a series of openings, placed in opposition to the Openings (10) of the Rotor (3), which are built one for each Element (E); and where each Element (E) has the shape of a circular sector with a width of 180 ° / N. It is also possible that the Opening (1 1) is built with a series of openings (always in reference to an Element (E)), having the characteristic of having the shape of a circular sector, even with a different radius, and where, the sum of their amplitude, can also be greater than the Aperture (11); moreover the Aperture (11) can logically be constructed as a circular crown, where the part that generates the motion is that previously described. In addition to this, the Rotor (3) rotates around an Axis of Rotation (1), placed in a non-vertical position; and where the Fluid (F), contained in each of its Elements (E), is not connected with that present in the other Elements (E), even adjacent ones. Furthermore, each Element (E) is made up of a Closed Body (6) and an Empty Body (9), where the latter is able to be filled with Fluid (F). The Closed Body (6), then, is characterized by having a mass lower than that of the identical volume of the Fluid (F). The Fluid (F) is introduced into the Rotor (3) through the Openings (10); these can be in the open or closed position and, using the management operated by the Labyrinth Structure (7), it is possible to allow the Fluid (F) to occupy all the available space of the Motor. There is also a half actuator (12), which creates the hydraulic equilibrium necessary to balance Pascal's thrust, indicated as the force contrary to motion A, which, in the work we are analyzing, is composed of an Aperture (10), which is located in the non-active part of the Rotor (3); and where, through this last opening, it is possible to transmit the pressure necessary for the hydraulic balancing generated by the container (2). Then there is the possibility of using actuator means that can open or close each Element (E), when the latter have either been, or must be filled, with the Fluid (F), a function generally managed by the Labyrinth Structure (7). Furthermore, it is also possible that the Surface (4) of the Rotor (3) is external to the Rotor (3) itself. In this case, an intermediate surface is used, the Surface (15), which connects the Rotor (3) on one side and the Surface (4) on the other, and which is made through a series of channels, also mobile, suitable for to allow the connection of the Fluid (F) in all parts of the Engine: these ducts can also be built in a structure having its own shape, but have only a connection purpose. 2. Gravitational Energy Motor according to claim 1 where the shape of the Rotor (3) is absolutely not binding. As a consequence of the foregoing and, given the particular importance, an example that could be particularly significant from a construction point of view is given below. One could, for example, construct the Rotor (3) equipped with two Surfaces (4), in order to simplify the inversion of the sense of rotation; these Surfaces (4), then, would be built with all the characteristics mentioned in the first part. Furthermore, in this case, but not only, one could hypothesize the construction of a new Rotor, called Rotor (31), built by joining the Rotor (3) with two (or one) truncated cones, where the truncated cones would take the name of Element (17); and where these, moreover, would have the peculiarity of presenting the major bases attached to the circular crown constituting the base of the Rotor (3), and would be made integral with the Rotation Axis (1) and with the Rotor itself (3). Furthermore, the major base of the Element (17), the one in contact with the base of the Rotor (3), could have the same area. In this representation, then, the Surfaces (4) would be realized on the lower bases of the Elements (17). The Elements (17), moreover, would be made up of 2 * N Elements, having within them both the Empty Space (9) and the Closed Body (6), and would be endowed with all the characteristics, previously examined for the other Elements (E) of the Rotor (3) in general. Furthermore, the Elements (17) would be connected, one by one, to the Elements (E) of the Rotor (3), so as to form a single Element (E), closed towards the outside, except for the Opening (10 ), and could be equipped internally with even more Closed Bodies (6). In addition to this, it could also be hypothesized that the major base of the Element (17) might not coincide with the lateral face of the central body of the Rotor (31), i.e. that solid which constitutes the Rotor (3), assuming also a higher value, to allow, for example, to build inside the Rotor (31), the Container (2), or a part of it. This configuration of the Rotor (31) has the structure that can be defined as mono or biconvex, where the cusps are represented by the minor bases of the truncated cones. From the hypothesis described above, however, a complementary structure could immediately be derived. What is now defined is a mono or bi-concave structure, where cavities would be obtained in the central part of the Rotor (31), the one that was built with the Rotor (3); and where the minor bases of the truncated cones would be configured at the inside of the Rotor (3) itself; moreover, the other characteristics of the Rotor (31) would not undergo variations. 3. Gravitational Energy Motor according to claims 1 and 2 where the shape, size and number of the Elements (E) is not binding and where, likewise, neither the shape nor the volume of the Empty Body are binding (9) and the number of Closed Bodies (6) referring to them. 4. Gravitational Energy Motor according to claims 1, 2 and 3 where for Half Actuator (12) also means the logic state determined by an electronic control unit that governs the passage of the Fluid (F) between the Container (2) and the Rotor (3), through the Openings (10) of the individual Elements (E) . 5. Gravitational Energy Motor according to claims 1, 2, 3 and 4 where the value of the internal radius Ri of the cylindrical crown is not determined, as it can also assume the value of zero. 6. Gravitational Energy Motor according to claims 1, 2, 3, 4 and 5 where the Labyrinth Structure (7) can also be built externally to the Container (2) and connected to it with the Element (16). 7. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5 and 6 where in each Element (E) there is a relief valve for the pressure existing at the end of the same Element (E), not defined either in the size nor in operation. 8. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6 and 7 where there is the possibility of an actuator means used to introduce and seal the Fluid (F) in each Element (E) of the Rotor (3), different from the Element (30). 9. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6, 7 and 8 where the dimensions, the shape and the number of the Surfaces (4) and (5) are not binding: these characteristics are examined simultaneously as they are the expression of a single reality. 10. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6, 7, 8 and 9 where the Surface (15) and the Surface (16) do not have a binding shape, but are normally treated simultaneously, because together they guarantee tightness and reduction of friction. 11. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6, 7, 8, 9 and 10 where the Surface (11) does not have a binding shape, as it can also be composed of several openings, also built with different edges. 12. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 and where to compensate the force A against the motion it is possible to use any type of actuator means . 13. Gravitational energy motor according to claims 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 and 12 where the determination of the position of the user means (13) is not binding. 14. Gravitational Energy Motor according to claims 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13 where the shape and number of the Elements (17) is not binding. All substantially as described and illustrated and for the specified purposes.