ITRM20090211A1 - SYSTEMS AND MEANS ABLE TO OBTAIN MOTOR MOMENT USING THE EFFECT OF HYDROSTATIC PRESSURE WITH THE THREAD D ARCHIMEDE COMBINED WITH THE STRENGTH OF GRAVITY IN TWO DIFFERENT DENSITY FLUIDS. - Google Patents

Description

â € œSystem and means capable of obtaining motor moment by using the effect of the hydrostatic pressure together with the Archimedes thrust combined with the force of gravity in two fluids of different density.

Description:

The object of the present invention is an energy converting transformer capable of rotating when immersed in water or other fluid, exploiting the action of the hydrostatic pressure / thrust of Archimedes, also in combination with the force of gravity by virtue of suitably arranged floating elements. , capable of moving within predetermined paths in order to provide an always asymmetrical thrust to the rotating system. It is known that: hydrostatic pressure is the force exerted by a fluid at rest on every surface in contact with it. The value of this pressure depends exclusively on the density of the fluid and on the sinking of the point considered by the free surface or, more generally, by the plane of the hydrostatic loads.

If there are two or more non-miscible fluids with different densities, the hydrostatic pressure is represented by the sum of the pressures caused by the different fluids. In the case involving the devices object of this patent, the absolute pressure applied to the bottom of a container full of water in contact with the atmosphere is the sum of the atmospheric pressure and the relative pressure of the water present in the container. In this case the effects of the two fluids can be considered separately or the surface can be imagined as subjected to the pressure of a single fluid (also considering the pressure of the other fluid compared to the first). In the previous example, knowing that the earth's atmosphere causes a pressure equal to about 10.33 meters of water column, we can add this height to the sinking of the point and thus calculate the absolute pressure in the point considered.

It is also known that it is not possible to give a thrust to a body and expect it to move without ever stopping, because part of the energy administered will turn into friction and the yield that we would obtain by wanting to convert the movement produced into energy will always be lower than the starting one.

It is also known that the principle of conservation of energy states that although energy can be transformed and converted from one form to another, the total amount of energy of an isolated system is a constant, i.e. its value is keeps unchanged over time.

It is also known that the scientific literature adopts the definition of the principle of conservation of total energy, as it includes all possible forms of energy, including mass (after Einstein).

In mechanics, the formula for the conservation of energy can be summarized as follows: U + T = Lnc in which the algebraic sum of potential energy U plus kinetic energy T is equal to the work performed by the non-conservative forces. In the presence of only conservative fields this algebraic sum is null (there is, in fact, no work by conservative forces). Physics teaches that a conservative field par excellence is the gravitational one, another example is the electrostatic field, moreover it teaches that a conservative field cannot give rise to any usable driving force.

It is also possible that the concept of conservative force is not applicable to the hydrostatic pressure / gravity force system as it is used here to move the proposed system and means, as it is also possible that with the experience that will derive from the method unpublished here indicated, to use natural forces apparently unable to provide useful energy for the movement of a system, as well as other studies and applications that hopefully will follow, perhaps it will soon be possible to use other forces present around us, hitherto unused.

The instrumental tests carried out made it possible to build a technological demonstrator capable of proving the consistency of the assumption defined in the title of this patent application and that it is possible to use the energy present in a fluid in the form of pressure hydrostatic thrust of Archimedes also combined with the effects of the force of gravity, to obtain the rotation of an ad hoc apparatus, partially or totally immersed. Said discovery, it bases its functionality on the ability to collect the thrust on the floats placed on the circumference of a wheel immersed in water in an asymmetrical manner.

The discovery, already built in experimental form in several specimens by the undersigned applicant, was subsequently made by the lng. Raffaele Giordano with the collaboration of his parent Attilio and further working specimens were made in the Comeg SrL precision mechanical workshop by Mr. Antonio Grimaldi, all on specific and precise indications of the undersigned applicant. Through all these functioning specimens, it is possible to see that by mounting particular devices on a rotating element partially immersed in water, the system is able to rotate in the presence of still water, pushed by naturally present forces, used asymmetrically by the mechanism.

In particular, as will be seen from the accompanying drawings, in order to allow the forces present in a fluid (in our case: water), to act asymmetrically on the floats applied to a wheel partially immersed in it vertically, first of all it will be necessary to have a system which allows the opposite floats to the right and left of the wheel center to position themselves at a different distance from the center itself, in order to exert a thrust proportional to their distance from the wheel center, always different between opposite floats, on the whole system, moreover, since © the wheel will be partially immersed so that its upper part can touch the surface of the water, the floats that come out of the water due to the rotation, will be arranged by gravity, at the minimum distance from the center and will be blocked in that position by means of a locking mechanism of the same, capable of anchoring them at a minimum distance from the center of the wheel even when, for f tto the rotation, they will enter the water, so as to exert a lower thrust on the system than that produced by the floats on the opposite side of the wheel. Blocking and unblocking the floats that enter the water naturally costs energy, but as long as this expenditure is less than that obtained by the asymmetrical thrust on both sides of the wheel, the system will continue to move. With better materials than those used for the prototypes and through more efficient mechanisms, it will be interesting to verify the possibility of obtaining the movement of the system even by renouncing the locking / unlocking mechanisms of the floats, using the slight energy supremacy obtained only from the different distance of the floats. from the center it rotates on both sides of the same and also check the efficiency of the additional circular and elliptical devices illustrated, to be used totally immersed in water, which require different blocks of the floating elements.

Description of the technological demonstrator already created by the applicant and collaborators, in various examples, in annex schematically represented in graphic form as well as further models not yet realized but exemplifying the solutions to be adopted to obtain the same operating potential:

Fig. 1 shows a double slide that houses 2 ping pong balls with the function of floats that can move freely only in the delimited space in various ways (sticks, threaded bars, other material), so as not to be able to interfere with Cuna. other. The operational choice of using a double slide with two balls side by side was only dictated by the low cost of the materials and by the fact that two balls push twice as much as one, but it is clear that it is possible to use any number of balls or other floats. of other shapes and sizes. The slide of fig. 1 is also characterized in position 1a, by a locking / unlocking system for the movement of the balls where a non-round rod slides in a mask that does not allow it to rotate on itself, but only to slide in the direction of the balls. darts.

Two stops are applied to the movable rod in position 1b and 1c with the function of locking / unlocking the run of the balls when the rod is pushed to the right or left as indicated by the arrows. It is also possible to use a locking / unlocking system for the balls based on the use of a round rod which in this case must necessarily be equipped with an additional safety element that does not allow it to rotate under the thrust of the balls. balls once immersed in water. This safety element can consist of a lateral arm applied to the movable rod, forced to move only along a sliding guide which, in addition to preventing lateral movement, will have the additional function of unloading the effort produced by the balls when, due to the rotation of the wheel, they will immerse. A further blocking / unblocking system of the floats is described below because it is particularly efficient and easy to make among the countless possible ones, including electric ones equipped with electromagnets or magnets equipped with the same pole that repel each other.

It, shown in fig. 3, consists of an underwire 3a capable of rotating in a support 3b and is made up of various arms of which: 3c having the function of making the underwire 3a rotate in its support 3b when it encounters a fixed obstacle outside the wheel (e.g. long nail anchored to the base of the system). The rotation will cause the displacement of the 3d element until the movement of the float in the slide to which it is applied is blocked. An example of this is shown in 3f, where you can see a slide with the lock / unlock system of fig. 3 applied and open that allows the ball to move while in fig 3g you can see the closed system that blocks the movement of the ball. Similarly, in position 3h you can see the same locking / unlocking system of fig. 3 applied to another type of slide with another type of float where in position 3h the open system is seen with the float free to move and in fig. 3i with the float blocked. Now we must consider the movement of the appendix marked 3e which has a different angle from the others and which also moves as a consequence of the rotation of the underwire 3a in its base 3b.

The importance of this last appendix 3e lies in the need to have an automatic release system, simple and with very low friction, therefore, when necessary, appendix 3e will encounter a fixed obstacle outside the wheel (e.g. a long nail anchored to the base of the wheel but on the opposite side to the first) which, touching it, will bring the underwire back into position, releasing the float only in the position in which, due to the hydrostatic thrust, it will no longer weigh on the locking underwire. For low friction handling of the ferrules with minimum energy expenditure, it is essential that they meet the stops, only in the positions in which, due to the rotation, they are free to rotate because they are not subjected to the pressure of the floats. Fig. 2 shows a variant of the slide 1 characterized by a low friction movement system built on rotating elements such as wheels, pulleys or marbles, which allow a floating body to move only inside the space delimited by the rotating elements. Fig. 2 is also characterized by a system for blocking / releasing the movement of the floating body of the type already indicated in figure 1. When the rod is pushed in the directions indicated by the arrows, the stop on the sliding rod will be positioned in in order to block / unblock the movement of the float body. Since the float block and release ball is anchored to the slide, the force exerted by the floats on the slide cannot in any way constitute an impediment to the propulsive force developed by the particular applications of the assembly.

It should be noted that the number of balls in fig. 1 as well as the size, shape and possible number of the float (s) as in fig. 2 contribute to increase the available thrust and the efficiency of the devices, not their functionality which is already satisfactory in the simplest form. Figure 3 shows a variant of the cell already seen in fig. 1 defined slide, where in position 3a a cylinder trunk has been added in position 3a made from a portion of light plastic tube, positioned so that the ball has the possibility of moving along the path delimited by the elements of support if it does not stop inside the tube. In figs. 3b and 3c you can see how the cylinder trunk is applied to the slide at such an angle that depending on the positions it will assume once in the water, the ball can move in the direction of the actual slide or remain imprisoned in the portion of tube. Position 3c is characterized by the application of a single cylinder trunk to better show in which point of the slide the application will be engaged, but in the construction practice the cylinder trunk will be applied to all the elements of the slide so as to standardize its operation, it should also be remembered that a greater number of slides means more thrust and better distributed.

Fig. 4 schematically shows the application of the slides on a rotating element with a round shape (wheel) where it is noted that each of it is inclined with respect to the Cartesian axes and all inclined in the same direction. In particular, the behavior of the floats inside the elements defined as slides is described, assuming that the wheel is partially immersed in water whose sinking level is that defined in 4a. It can be noted that the balls inside the sled in position 4b are pushed into an external position by the hydrostatic pressure / thrust of Archimedes and forced to arrange themselves in the position furthest from the center of the wheel while those inside the sled diametrically opposite, they are pushed into the position closest to the center of the wheel so that each sled, due to the rotation of the wheel to which they are connected, will have to travel through all the positions shown in such a way that the floats contained in them, being at different distances from the wheel center, will impart different thrusts to the wheel system.

All the sleds are equipped with an adjustment system of their own inclination, in order to experience the optimal one. The scheme in fig. 4 also shows the positioning of all the other balls, all in a position closer to the center of the wheel except for 4b, 4c, 4d and 4e which, being all in an external position and further away from the center of the wheel, create an advantageous moment which provides pushing the wheel allowing it to rotate. As a result of the rotation, the other slides will find themselves occupying the forward positions described, behaving in the same way and gradually providing the propulsion to the system. The only balls that could oppose the movement of the wheel are: partially the 4f when it enters the water, the 4g and the 4h for the moment in which it remains in a disadvantageous position, however in the schematic representation of fig. 4 they are shown closer to the center of the wheel, because they are harnessed by the ball locking / unlocking system of which an example has been described and shown in fig. 1, 2 and 3 of table 1. The operation is different if the slides equipped with a cylinder trunk are applied to the wheel as in fig. marked with the number 3.

The slides equipped with a cylinder trunk or other equivalent blocking element, must be carefully positioned on the wheel with an inclination such that at the moment of entry into the water as in the position schematized in letter 4f, the ball must enter the cylinder trunk / other blocking element (which remains at the top of the movement of the ball) to remain imprisoned in position near the center of the wheel and thus remain until, due to the effect of the rotation, the sled is on the opposite side of the wheel where the balls will be forced to come out of the trunks of cylinders that block them, because the latter will be at the bottom with respect to the balls that will be pushed up and away from the center of the wheel due to the inclination of the slide, therefore they, when in position 4b, 4c, 4d and 4e will behave like all the others illustrated so far, unbalancing the system and providing the propulsion necessary for its rotation. The systems created and proposed so far, as well as the countless possible variants using the methodology illustrated, certainly need careful adjustment and improvements on all aspects relating to their construction and application, however it is remarkable that even with technologies approximate as those used up to now, each model has contributed to demonstrate the validity of the initial assumption and that it is possible to collect an asymmetrical thrust using an ad hoc device, partially or totally immersed in a container full of water or at sea or in a lake. Naturally, as soon as it will be possible to proceed to transfer all the aforementioned data into a computer environment using a suitable simulation program to which the data referred to in this system and means must necessarily be entered, it will be possible to calculate the best circumference to be used, with the floats more efficient in terms of shape or number, the best system locks - unlocks floats as well as anything else necessary for a better functionality of the whole.

Figures 5 and 5a show further variants among the very many possible ones, concerning the method illustrated up to now, where hollow elements, mounted in a sequential way, are mounted on a circular and an elliptical rotation system. The details characterizing the two systems are shown in fig. 6 where schematically shown in 6a: the set of various elements consisting of 6b: triptych of hollow elements of which the central one is movable around an eccentric axis inside the triptych itself or even hinged to its rear part so as to have only the movement as shown in the figure; 6c: soft rubber element capable of covering the joints between the various elements 6b and giving them the possibility of adapting to the circular shape of the wheels; 6d: spiral in light plastic or even metallic material, capable of giving the rubber of element 6c the characteristic of incompressibility and resistance to external pressure found below the water level but at the same time allowing the rubbery material to follow the folded shape of the wheel. Of course, it is also possible to achieve the same result through other processes such as a bi-component mold that allows injections of different materials where more rigid elements can be spaced from rubber elements to obtain a partly rigid and partly flexible element that is well suitable for the circular or elliptical shape of rotating systems.

Description of operation: The circular system as well as the elliptical system as per fig. 5 and 5a, must be completely immersed in water and the more they are immersed, the better they work. Since the elements defined as triptych as in fig. 6b are equipped with an internal eccentric hinge as shown or also an external rear hinge to allow the movement of only the central element, when they are in position 5b and 5 c, this central element will be moved upwards as shown in the figure at the aforesaid positions as well as in fig. 6e, because pushed by the hydrostatic pressure / Archimedes 'thrust and will maintain this position until it reaches the opposite position depicted at the apex of the two systems 5 and 5a where, again due to the hydrostatic thrust / Archimedes' thrust, the mobile element is it will close again as its internal or external hinge, which is always posterior to it, will allow it to close, see also fig. 6f where the position of a triptych is highlighted when close to the apex of the wheel and fig. 6g where, finally at the apex, it is forced to close again by virtue of the thrust exerted by the liquid on the mobile part of the float. Of course, this simple principle is also achievable with other configurations. Obviously, locking and unlocking elements may be provided to help the closed elements remain in position as long as this will be useful to the system, such as a spring applied to the hinge of the triptych as shown in fig. 6, adjustable to allow the opening / closing of the mobile element of the triptych only when subjected to a certain pressure. When in position 6e (i.e. in the lower position with respect to the circular or elliptical rotation system, the mobile element of the triptych, overcoming the resistance of the spring (internal or external) because that point is the resultant of the hydrostatic thrust on it is orthogonal to its longitudinal axis and the force of the spring that hinders its opening is less than the thrust, therefore, it opens and remains open until the rotation of the wheel brings the same element to the apex of the wheel , when it is overturned, it will be forced to close again, overcoming the resistance of the adjustable spring and remaining closed until it is again in the low position. As a result of what has just been said, the wheels in 5 and 5a will be characterized by one part (in figure a right), where for the reasons explained, the arrangement of the elements defined as triptych are open allowing the water to lick the greater surface of the same exerting the s moreover, due to the open ture of the trittic symmetry between the right part and the center part of the wheel (or focus of the ellipse) of the so that the thrusts exerted will be left in the two systems shown and have all the closed elements that the lower part and the water, not being able p exert pressure on the walls of its base. For the above, the will be different and will allow the ro

â € ™

Claims (10)

mobile floats inside cells or slides inclined in the same direction, capable of creating an asymmetrical propulsive thrust on both sides of the rotating systems. 2) System and means for obtaining movement of a system immersed in still water as in claim 1) in which a sled or propulsion cell houses one or more floats that can / can move freely only in its own delimited space in such a way that it cannot interfere with another adjacent float, equipped with any device for blocking / releasing the movement of the floats, as long as it can be activated by means of minimum energy and having a low level of friction. 3) System and means for obtaining movement of a system immersed in still water as per claim 2) in which the slide or other propulsion cell is characterized by any float of spherical shape or other regular or irregular shape moved with low friction by of rotating elements such as pulleys or marbles that allow it to move only within the delimited space. 4) System and means for obtaining movement of a system immersed in still water as per claims 1 and 2) in which a float capture compartment has been added to the sliding slide of the float (s) in position 3a, all mounted on a rotating system with an angle such that due to the rotation, upon entering the water, the float remains trapped in the additional compartment but can move freely when the slide is overturned on the opposite side, giving different thrust to the system in the different positions it will find itself in. 5) System and means for obtaining movement of a system immersed in still water as per claim 1) and 2) in which the floats inside the slides or other type of propulsion cells are pushed into an external position by the hydrostatic pressure / Archimedes thrust placing themselves in the position furthest from the center of the wheel producing motor moment while those in a mirror position, on the other side of the wheel, are forced to assume the position closest to the center of the wheel due to the inclination with which the propulsion cells or skids are mounted on the wheel itself. 6) System and means for obtaining motor moment as per claims 1), 2) e 5) in which the positioning of the floats 4b, 4c, 4d and 4e in an external position and farther from the center of the wheel, creates an advantageous moment that provides the thrust to the wheel allowing it to rotate in the same way as any other type of float that can only be opened through the forces present in a given position in order to offer greater surface to the hydrostatic pressure / thrust of Archimedes and reclosable only through the same forces when in a position opposite to the first with respect to the center of the rotating system on which they are applied. 7) System and means for obtaining motive force as per claim 1) and 2) in which the rotating systems 5 and 5a equipped with hollow triptych elements, of which the central one movable around an eccentric axis or hinged to its rear part, joined the € ™ one to the other by means of an element of soft rubber capable of giving them the possibility of adapting to the circular shape of systems of circular or elliptical shape, containing a spiral in light plastic or metal material, capable of giving the rubber the characteristic of incompressibility and resistance to external pressure found below the water level. 8) System and means for obtaining movement of a system immersed in still water as per claim 1), 2) and 7) in which the propulsion elements are shaped as in fig. 6b in order to facilitate the exit of the central mobile element with minimum friction when it reaches the low position as in 6e, overcoming the resistance of a spring calibrated ad hoc to remain with this configuration open until the apex of the system rotating where it will be closed as in 6g by the pressure exerted by the fluid on the mobile float which will overcome the resistance of the spring which will allow it to remain in this closed configuration until the low position is reached. 9) System and means for moving a system immersed in still water as per claims 1), 2) and 8) where the rotating systems 5 and 5a are characterized by the different configuration assumed by the triptych elements or other type of floats on their two slopes allowing the water to lick the greater surface of the same when they reach one side of the systems depicted allowing the fluid to wet and then exert its thrust on triptychs or other types of open floats that once reached the apex of the rotating systems they will close and remain closed until the lowest position is reached, preventing water from penetrating inside them and behaving like a single long tube where water can only exert pressure on its walls but not the thrust present in the positions in which the trìttici or other type of floats are open. 10) System and means as per claims 1 to 9 capable of demonstrating that it is possible to build an energy converting transformer capable of rotating when immersed in water or other fluid, exploiting the action of the hydrostatic pressure / thrust of Archimedes, also in combination with the force of gravity by virtue of suitably arranged floating elements, capable of moving within predetermined paths or opening up favoring the removal from the center of the rotating system, of hollow and floating elements when in a certain position and the approach by sliding or closing of the floats when in diametrically opposite position, in order to obtain differentiated upward thrusts on the opposite sides of the rotating systems, capable of moving the aforementioned systems by forces naturally present in a container full of water or in the sea or in a lake, in order to create systems energy efficient, even large ones with low cost and zero impact