ES2304317B1 - SYSTEM TO INDUCE ROTATING MOVEMENT IN AN AXIS. - Google Patents

Abstract

System to induce rotating movement in a axis.

It aims to achieve the turn in a same direction of the output shaft of a functional device in the involved levers (1, 16, 26, 27) that oscillate by the weight of a fluid from an upper tank (3) that discharges a dose to fill a tray (2, 17, 28) integral with the end of a lever (1, 16, 26), said tray being emptied (2, 17, 28) to the arrive at a lower deposit (10). During this tour, another vessel (29), hydraulic pump (6) or hydraulic wheel (14) that they were submerged in the lower tank (10), they raise higher volume of liquid and discharge it into the upper tank (3) consuming less energy, creating a free energy available on the output shaft.

Description

System to induce rotating movement in a axis.

Object of the invention

The present invention, as expressed by the set forth in this specification, refers to a system for  induce rotating movement on an axis and with it you get the rotation in the same direction of rotation, either pulsatingly or intermittent, or continuous through different units attached to the same output shaft with angularly offset pulses.

Background of the invention

Attempts to get the movement are known of an axis without applying a constant energy to the input, it is say, so that it works by itself with movement "continuous", or "perpetual".

Among the various gadgets used with this end, we can cite those who use hydraulic force, magnetic energy, lever system and weight shift, masses in constant imbalance, etc.

Description of the invention

In general, the system to induce rotating movement on an axis, object of the invention, achieves the movement from two deposits at different levels containing in principle a liquid such as water, although it could also use an aggregate or other fluids. Operating principle is based on managing to raise more fluid from the lower deposit to the upper deposit, than is necessary remove from the upper tank to transmit movement to a longline system taking advantage of the gravitational weight of the fluid which fills a tray or receiving container arranged at the end of the power arm of a carrier lever of such a tray or container. This lever can rotate around a fixed axis and more specifically, oscillate with a certain period as produce discharges of the received liquid (fluid) upon arrival lower point and that this movement occurs simultaneously water elevation in greater quantity from the lower tank to the superior, thus beginning a new cycle.

Be part of a swing lever at one point fixed intermediate located at an intermediate height between the two deposits, said oscillating lever having a support tray at the end of your longest arm or power arm and that can be filled with the liquid from the upper tank when opening a tap or valve. By gravitational action of the liquid in the tray, this lever rotates and at the opposite end or its arm of resistance has a counterweight mounted so that after unloading of the tray in the lower tank, the lever recovers its primitive position

During the descent of the tray filled with water, a water pump or hydraulic piston whose piston is operated  it is actuated by the lever itself when its rod is connected to a point close to the turning point of this one. The pressure to exert the stem to discharge the pump and raise its volume of liquid the upper deposit may be the one required and always greater that used to fill the tray, it is enough that it is far enough from the axis of rotation, since the forces are inversely proportional to the distances with respect to the axis of rotation of the lever as is known.

This higher volume that rises too much (difference between a hydraulic piston stroke and water admitted in the tray to cause the tilting), is the one that provides angular axis movement with available torque at your departure (counting on the counterweight counterpart thanks to which is able to recover the initial position) and which is usable to have extra energy available. When the tray arrives at its lowest point is discharged by its own inclination and when the force exerted by the weight of the water, the counterweight causes the rotation in the opposite direction and the piston recovers the original position.

Naturally according to this functional process, the lower tank would be emptied. To avoid it there is a return duct of the excess or overflow of the upper tank to the bottom There are no fluid losses except those caused by evaporation, if applicable.

The invention also provides that the liquid be lift from the lower to the upper tank by any another functional device, such as the use of a hydraulic wheel or ferris wheel whose buckets are filled to the turn it by means of a crank-crank mechanism operated by the same oscillating lever of the previous embodiment. The lever tray can be filled by being under one upper tank discharge valve and it can be opened or close commanded by the lever itself. So, rising rises a drain or discharge plug of the upper tank and when the tray is full and it descends, it closes until it is again raised and so on. The ferris wheel is partially submerged in the liquid in the lower tank and during the working stroke of the lever movement is transmitted to the crank-crank to turn the wheel and raise the buckets that are unloaded in the upper tank. After is the counterweight on the other end of the lever which raises the tray, the wheel being stopped by a ratchet device or unidirectional turn, being full buckets that have gone gaining height

The fluid can also be lifted.  through a system of two articulated levers, one of which it carries at its end of the power arm, the tray that is loaded with the liquid from the upper tank and that is discharged upon arrival lower; and the other lever, at the end of its resistance arm, It carries a container or tray that is filled when immersed in the lower tank and poured into the upper tank when it occupies the highest position, coinciding with the lower of the other tray that causes movement.

The container or tray carrier lever the water rises, is articulated by an intermediate point and its other  end of the power arm is connected to a connecting rod or rod anchored in turn to an intermediate point of the second lever which is swinging around one end and carrying the tray on the other active that is loaded with the liquid from the upper tank. With this force multiplication is achieved using less volume of liquid from the upper tank than the one that rises from the lower as in previous cases. If a single lever is used, it would raise less liquid than the one that descends and would not work, or well, it could raise more liquid but at the cost of doing it at a lower height that would not be enough because the power arm is more Long than resistance.

Once the tanks and levers are arranged in place to a certain length and their fixed points of rotation, if necessary, a counterweight could be attached to recover the original position, or have another one that can be adjusted if the resistant torque is excessive , as a certain counterweight fixed on the tie rod or connecting rod of the
levers

The higher volume of elevated liquid provides rotation with a desired torque, in any of the axes of rotation of the levers or of the hydraulic wheel, which determines the production of a surplus energy for consumption in any of the known usable energies.

To facilitate the understanding of characteristics of the invention and forming an integral part of this Descriptive report, accompanying some sheets of plans in whose figures, with an illustrative and non-limiting nature represented the following:

Brief description of the drawings

Figure 1.- It is a schematic view of a system to induce rotating movement on an axis, object of the invention, using a hydraulic pump or piston for lifting of the liquid to the upper tank, being in loading position the tray that will be filled with the liquid that causes the movement, filling up the upper tank.

Figure 2.- It is a view similar to Figure 1, in unloading position.

Figure 3.- It is a schematic view of another system of inducing rotating movement, in accordance with the invention, using a hydraulic wheel for liquid lifting, in resting position

Figure 4.- It is a view similar to Figure 3, in unloading position.

Figure 5.- It is a schematic view of a third  system of inducing rotating movement on an axis, using two articulated levers provided with the respective containers or trays: one for loading the liquid from the upper tank that discharge in the lower one, and the other lifting liquid lower tank and pour it into the upper one, in rest position or horizontal

Figure 6.- It is a view similar to Figure 5, filling the tray to cause the levers to tilt and the elevation of the liquid to the upper tank.

Figure 7.- It is a view similar to Figure 5, in unloading position of the trays.

Description of the preferred embodiment

Referring to the numbering adopted in the figures and especially in relation to figures 1 and 2, we can see that the system to induce rotating movement in a axis, which the invention proposes, consists of a lever (1) with a tray (2) at the end and that when filled with the liquid contained in the upper tank (3) by opening its lower tap or discharge valve (4), rotates by gravity around the point where is the axis of articulation (5) to which in its case, We want to provide turning movement in only one direction. To the fill the tray (2) and the hydraulic pump is lowered (6) or hydraulic piston whose piston (7) was in position high. Its rod (8) is connected articulately at the point (9) of the lever (1). Water (or other liquid) from the tray (2) is discharged into the lower tank (10) in which it is located Partially submerged pump (6).

Reference (11) designates the conduit of water lift driven by the plunger (7) and pumped to the upper tank (3) by the unidirectional valve correspondent.

At the end of the lever (1) (the tray 2) at its lowest point (by inclination) the emptying of the tray (2) in the lower tank (10), so the force exerted by the weight of the water ceases. Right now and thanks to the counterweight (12) of the other end of the lever (1), this returns to its initial position while admitting water in the pump (6) by the corresponding unidirectional valve of admission. This repeats the cycle.

The water received in the tray (2) is regulated by means of the tap (4), the volume of water pumped being greater upper tank (3) by the hydraulic pump (6) than the one removed of the same with the tray (2). The surplus returns to the deposit bottom (10) by the overflow tube (13).

Referring now to figures 3 and 4 where the second system is schematically represented water lift from the lower tank (10) to the upper one (2), we see that there is the hydraulic wheel (14) of buckets (15), whose rotation is done by the oscillating lever (16) that rotates in clockwise when filling the tray (17) that hangs from its end, with the water coming out of the upper tank (3) to be raised the plug (18) of the drain valve (19) that was suspended by a rope (20) or similar, of the lever itself (16). When filling, the tray (17) descends and with this movement also lower the cap (18) and the discharge hole is closed.

As in the previous case, when the tray (17) reaches the end of its descent path, the rod (21) in solidarity with her trips on the edge or other fixed element of the lower tank (10) and tilts causing emptying righ now. During this movement the hydraulic wheel rotation (14) by the connecting rod mechanism (22) -Crank (23) connected to the lever (16) in the point (24).

For the hydraulic wheel (14) to rotate only in one direction, is connected to the axis of rotation (25) by means of a pinion of bicycle or unidirectional device known. Buckets (15) that are filled during the lever work run oscillating (16) unload a total volume in the upper tank (3) greater than the one receiving the tray (17) on the power arm of the lever. The connecting rod (22) works in this example by tension but you could also work under compression if you connect in another point of the oscillating lever and the crank (23) is in another favorable position and specifically on the other side regarding the line that joins the center (25) of the hydraulic wheel with the point (24) connecting rod connecting rod (22) to oscillating lever (16).

Finally, in the third embodiment corresponding to figures 5 to 7, to raise the water of the lower tank (10) to the upper one (3) only the carrier levers (26) and (27) respectively of the tray filling (28) to produce gravity movement, and of the container (29) for lifting the liquid from the lower tank (10) to the superior (3).

The lever (26) is oscillating at its end in the shaft (30) and the lever (27) is for a paracentral point or intermediate (31). Its shorter arm is connected to a Paracentral point (32) of the lever (26) by the connecting rod (33).

Reference (34) designates the float set to the base of the tray (28) so that when you lower the lever (26), the  tray (28) is placed on the liquid of the lower tank (10) and It is emptied by the tilt effect. There could also be a pop-up tray rod (28) that tripped over the edge of the lower tank (10) and will lean to immediately empty your content, as we have seen previously in the other form of realization.

With this arrangement, starting from the position intermediate stand of figure 5, when the tray (28) rises empty you get to push the valve plug directly discharge (35) of the upper tank (3) and it is filled. This makes the downhill movement per action automatically starts gravitational At the same time the container (29) that it was submerged (see figure 6) in the lower tank (10) and by both full of liquid, pouring all of its contents, by inclination, upon reaching the edge of the upper tank (3). When the tray (28) lands on the liquid (figure 7) it is unloaded and rises while the container (9) descends and returns to start the process.

With this arrangement, we get movement of rotation in the fixed axles (31) and / or (30) of articulation of the levers (27) and (26) respectively, and in them, as in the hydraulic wheel (14) of the previous embodiment or on the axle (5)  where the lever (16) of the same oscillates, pinions are mounted unidirectional.

As you can see, the essence of the invention or principle of operation thereof, is based on raise more liquid (or an aggregate as we have said above) from the lower to the upper tank, than the one it is necessary to fill the trays of the tank above the bottom using a lever system, which can lead to out in different ways, such as those mentioned or others Similar.

Also contemplated in the invention is the fact that if the upper tank (3) of any embodiment contains water and was fed by an outside source such as by a diversion of the current of a river or similar, the liquid can be raise to a greater height and can thus be raised or pumped if necessary to be applied to direct uses such as irrigation, etc. Alone a lower tank (10) would have to be built and the Gravitational intermediate functional device.

Similarly, if it were the lower deposit (10) (of any embodiment) the one that was fed directly from an outside source, only the upper tank (3) and water pumped or raised too much to higher height, applies to other uses as it is not necessary to supply to the lower tank (10).

In these cases of elevation of the liquid to greater height, it would not be necessary to have shafts with devices transmission and use of free energy that would reduce the irrigation efficiency at higher altitude. It is also contemplated that it is selective use of this generated free energy.

Claims (10)

1. System to induce rotational movement on an axis, causing rotation in the same direction and by means of the weight of a fluid that fills one or more containers or trays that are subsequently discharged, through a lever system, characterized in that it consists of disposing two tanks (3, 10) at a different level, the upper one of which (3) includes a dosed discharge valve of the fluid (liquid, grain or aggregate) contained in it and that produces the movement of a lever (1, 16 , 26) oscillating carrier at its end of the aforementioned tray (2, 17, 28), the fluid being discharged when it reaches the lower tank (10) while another dose of the latter fluid is simultaneously raised and discharged into the upper tank (3 ), the amount of fluid raised to the upper tank (3) being equal to or greater than that which descends or is discharged into the lower tank (10); there is an overflow conduit (13) of the upper tank (3) that discharges into the lower tank (10). 2. System for inducing rotational movement on an axis, according to claim 1, characterized in that the elevation of the fluid is achieved by means of a hydraulic pump (6) or hydraulic piston actuated by a lever (1) articulated at an intermediate fixed point that coincides with the axis of rotation (5) referred to and having oscillating or alternative movements, said lever (1) being carrier at the end of its arm of greater length or power, of the tray (2) or container that is loaded with the fluid of the upper tank (3) by means of a tap or discharge valve (4), while at the end of its minor or resistance arm it includes a counterweight (12). 3. System for inducing rotating movement on an axis, according to claim 2, characterized in that the pump (6) or hydraulic piston has the rod (8) connected to a point (9) of the lever (1) close to the axis of rotation ( 5) of the same, pumping or raising the fluid during the work stroke and admitting it in the return stroke, through corresponding non-return valves. 4. System for inducing rotational movement in an axis, according to claim 1, characterized in that the lifting of the fluid is carried out by means of a hydraulic wheel (14) of horizontal axis (25) and partially submerged in the fluid of the lower tank (10), which rotates to raise it in its buckets (15) to the upper tank (3) by means of a crank-crank mechanism (22-23) connected to an articulated lever (16) at a fixed point (5) and animated oscillating movement to be carrier at the end of its power arm, of a tray (17) or container suspended so that a portion thereof is located under a discharge valve (19) of the upper tank (3), filling with the fluid and descending until discharge occurs in the lower tank (10); recovering the elevated position of the tray (17) by means of a counterweight (12) mounted on the other end of the oscillating lever (16). 5. System for inducing rotational movement on an axis, according to claim 4, characterized in that the discharge valve (19) is sealed by a plug (18) suspended from the end of the oscillating lever (16), the tray being allowed to load the elevated position of the latter and while lowering also lowers the plug (18) and closes the valve (19). 6. System for inducing rotational movement on an axis, according to claim 1, characterized in that the elevation of the fluid is carried out by means of the combined action of two levers (26, 27) articulated at two fixed points, one of which (27) it does so by an offset point (31) and at the near end it is connected by means of a tie rod or connecting rod (33), the other lever (26) and attached to an intermediate point (32) thereof, being oscillating by one of its ends at the second fixed point or axis of rotation (30); having provided that the first lever (27) has at its free end a container (29) capable of filling with liquid when submerged in the lower tank (10), rising to discharge this liquid into the upper tank (3) when there is a tray (28) at the free end of the second lever (26), which is filled with the liquid discharged from the upper tank (3) and which descends to the level of the lower tank (10) where it is emptied to start the cycle. 7. System for inducing rotational movement in an axis, according to claim 6, characterized in that the discharge valve (35) is operated directly by the second lever (26), opening when pressed in the lifting position and closing when it is moved away for the descent. 8. System for inducing rotational movement on an axis, according to claims 4 to 7, characterized in that the tray (17, 34) includes means for evacuating the fluid it carries when the discharge position is reached by having an extension or rod (21) that affects a fixed element or the edge of the lower tank (10) causing the tipping. 9. System for inducing rotating movement on an axis, according to claims 4 to 7, characterized in that the tray (17, 34) inferiorly includes an eccentric element (34) of floating support on the fluid-free surface of the lower reservoir (10) for cause the fluid to carry over. 10. System for inducing rotational movement in an axis, according to previous claims, characterized in that the selected rotation or articulation axes have unidirectional sprockets to obtain one-way movement and have free energy usable at their exit.