BE1013125A5 - System alternately applying the force of gravity and then the Archimedesprinciple to a floating object to produce quasi-perpetual motion andtherefore energy - Google Patents

Abstract

A system alternately causing the circulation from an air environment to aliquid column of one or more bodies of mass "M" and of the smallest possibleweight per unit volume (making them floating) so that they may be subjectfirstly to the force of gravity then to an upthrust equal to the volume ofliquid displaced (Archimedes principle), bringing them back to the startpoint. This quasi-spontaneous and perpetual motion generates a resultingforce transmitted by any means to generators and intended to produceelectrical power. Use of two non-polluting and immutable natural forces so asto produce energy.<IMAGE>

Description

       

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  SYSTEM THAT ALTERNATIVELY IMPOSES THE FORCE OF GRAVITY THEN. THE PRINCIPLE OF AN ARCHIMEDE WITH A FLOATING OBJECT IN ORDER TO
PRODUCING A QUASI-PERPETUAL MOVEMENT, SO A
ENERGY.



  1. General description of the principles used:
In nature, there are two permanent physical forces, immutable and in opposite directions, which are the gravity and the thrust suffered by any body immersed in a liquid according to the Archimedes Principle. If we manage to couple them, that is to say to impose on the same body of mass M, first one, that is to say the force G. causing the said body released from a height
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   H down, then the other, that is Archimedes' push, bringing the same body back to its initial point, we therefore generate a movement of the mass from top to bottom, then from bottom to top, with return to the point of departure and application of force G again. On the body and so on.



   This almost perpetual and spontaneous movement can therefore result, by any suitable transmission (belt, chain, gear, ... or any other system, ...) a driving force or other intended to produce energy (mechanical , electrical, etc.) one of the basic principles of the invention is therefore to use one or more objects 0 ", of mass M and density P making this body as floating as possible in a fluid FL (water (water also favoring their buoyancy as much as possible, therefore the push that the object 0 "will undergo upwards, when it passes from an aerial compartment Cl, where it undergoes the force F towards that (liquid C2) where it will undergo the thrust according to the Archimedes Principle.

   Object 0)), released from a height "H", undergoes the force G and after a uniformly accelerated movement, over a certain height after a time T "depending on the height at which it will be released and its surface area. resistance to air but not to its mass, on the other hand, any body immersed in a liquid undergoes a thrust from bottom to top directly proportional to the volume of liquid displaced.



   The more the object has a low density and lower than that of the liquid in which it is immersed, the more the upward thrust will be important. It is the principle of buoyancy which allows, among other things, to see steel ships floating in the hundreds of thousands of tonnes or even to bring up to the surface, sunken boats by wrapping them in sheaths connected to large balloons inflated with gas. .



   The invention therefore uses an object of mass M, which dropped into a first compartment Cl, will undergo the terrestrial attraction but of density such that it will be floating, unsinkable and that, when it is passed through a compartment C2 filled with salt water (or other fluid favoring buoyancy as much as possible) it will undergo a thrust from bottom to top, sending it back into the air compartment Cl from where it comes initially in order to undergo again the terrestrial attraction and the force G which will bring it back down, then into compartment C2, and so on.



   The movement generates a force F resulting from the couple of the two opposite forces. If we connect the object or objects concerned by a transmission system (belt, chain,) to for example a generator

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 electric, the resulting force F will cause the rotation of the axis of this electric generator (the armature in the inductor) therefore a production of electricity.



   In one of the exemplary embodiments described below, two masses M1 and M2 are used,) similar connected together by a transmission strap; the movement of the two masses causes the rotation of one or more axis (s) of dynamo or electric generator. Several prototypes are possible: - with a mass, two masses connected to each other or independent.



     . The transmission of the force resulting from the movement of the mass or masses can take place towards one or more rotary axis (s) producing the desired energy as a result. This or these axes can be separated, at the center of the system or at the periphery. The object of the invention is therefore to produce an energy inducing force from existing natural, permanent and non-polluting physical forces.



  He. Description of non-exhaustive examples of implementation:
A) Two masses linked together by a belt:
Let us take for example two round masses of density lower than that of the water or the fluid used in the system, connected between them by the belt which will transmit the force resulting from the movement of these two masses to one or more electric generators.



   1) Let us recall some definitions:
The mass of a body is the constant ratio of the force acting on this body to the acceleration that this force communicates to it. M = Fla.



   The intensity of a force is the product of the measurement of the mass on which it acts and the measurement of the acceleration that it communicates to it.



  Force unit: Newton = 1 kg x 1 mis2.



   The weight of a body is the measure of the force exerted by the Earth on the mass of this body.



   The study of the free fall of bodies shows that a falling body takes a uniformly accelerated movement whose acceleration of gravity is represented by G. (p = mg.)
A body withdrawn from the action of gravity therefore has zero weight, while its mass remains invariable, ie M = F / a; she can therefore continue to be subjected to force. However, in the invention, the passage of the mass of density as small as possible in a liquid compartment subtracts it almost completely from gravity and subjects it to a new force of opposite direction thanks to its buoyancy. These two opposite forces provide a work numerically equal to the product of the intensity of the force by the length of the displacement. T = F x dist. And whose unit is the Joule, that is to say 1 Joule = 1 Newton x 1 meter.

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   The total power of the system will be expressed in Watt, that is to say, the total work in Newton provided by the system in one second, from which it will eventually be necessary to deduct any work to be provided for the proper functioning of the system. (Possibly, pumping of recovery water, operation of the valves, ...) in order to obtain the actual final power and the percentage efficiency of the system.



   Concept of density p: p = ratio of the mass of a body and its volume p = MN = Kg / m3 p of water 103 Kg / m3 sea water = 1166 Kg / m3.



   The lower the density of the masses concerned by the movement of the invention, and the higher the liquid density, the greater the force undergone by the mass or masses. Therefore, the greater the thrust bringing the mass (es) back into the aerial behavior
2) Examples of description of the masses and their mobilization system.



   The masses can be aerodynamically shaped in order to reduce the friction of the air in the compartment C1 and to increase the force G.



   In the example taken in diagram A, the masses will be round, made of wood or hollow metal filled with air, gas or any material making their buoyancy as large as possible.
They are connected by two rods T1, T2 to small ball bearings, balls R1, R2 themselves anchored in rigid sheaths G1, G2 included in a fixed frame intended to support the whole system.



   In compartment C1 (V General diagram), the frame is limited to the gutters and their support therefore, not closed in order to reduce as much as possible the compression of the air generated by the movement of the mass during its descent, therefore the resistance opposite to the movement thereof.



  On the other hand, C2, liquid compartment, is closed and hermetic.



   On the lower face of the upper sheath (Gs) and the upper face of the lower sheath (Gi), are anchored balls or bearings in contact with the ball bearings R1 and R2 of the rods carrying the masses M1 and M2.



   This allows a movement almost free of friction, therefore with a minimum loss of force
The ball bearings R1 and R2 are extended outwards by other transmission rods (T3, T4, as thin as possible + or-the same thickness as the belt) on which the belt, chain or any another system ... which will transmit the forces of mass movement to an electric generator

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3) General description of the system: (diagram B)
1 Description of a type of path imposed on M1 and M2 in the system used as an example (two masses connected by the transmission belt). The masses M1 and M2 move therefore thanks to the ball bearings to which they are connected.

   Their course is first located in a first compartment in the open air CI, then in an intermediate compartment Ci limited by two hermetic valves V1 and V2 and finally ends in a column of liquid C2, ie different successive phases: phase 1 by force of gravity at the start M1 is in D; the liquid column, therefore C2 and Ci are drowned; M1 is selected, M2 is at A.



  We start the movement; M1 arrives in zone A, given the slope 1 and the pawl 2, it undergoes the force G. And will move downwards on the ball bearings, at this moment, M2 has already undergone the force G and is in position zone C.



   The vertical fall having caused a significant acceleration, the force developed by M2 is substantial; there is therefore a risk of having a significant impact between the bearings and the curved angle of the gutter at point C.



  To reduce the shock, we can consider a curved gutter path at the points where the masses change direction, ie A, B, C, D. To reduce the impact and not damage the moving parts, it is therefore necessary that a large part of the force developed by the MRUA undergone by M2 is recovered by its transformation into motive energy transmitted by the belt. We can therefore consider, for example, that this transmission is made to the dynamo axis by the belt coupled to a kind of automatic car gearbox or bicycle derailleur. Similarly, the recovery of the force produced by the mass is almost zero at point A, the start of the race in order to allow easy movement, while it will be greater in C in order to reduce the impact due to the mass drop.

   An exact study of the forces, masses, heights and resistance of the materials will make it possible to precisely calculate the transmission logic to be applied. In C, M2 therefore has a speed and a force transmitted to the axis of the dynamo, but also to M1 since the two masses are connected by the transmission belt, although M1 already has its own upward propelling force (Principle Archimedes), it will also be pulled by the belts to exit the fluid compartment. A ratchet placed on or in the internal wall of the ducts G1 and G2 and will allow the passage of T1 T2 upwards, but not its return back. The pawl will be placed at a height which will prevent M1 and M2 from going back down and will force them to start their race in the gutter of the path concerned and to undergo either the force G or the Archimedes push.



   When M1 arrives in zone B, M2 is then in zone D, the valve N01 closes, isolating the intermediate compartment, that is to say the one created between valve 1 and valve 2, while at the same time, valve 2 opens, allowing water to enter the intermediate compartment, which thus becomes part

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 integral with the fluid compartment C2, the Ci is therefore alternating in the air, then fluid.



   Water is immediately replaced by a system of communicating vessels connecting C2 at a point Y, located in the most adequate way to avoid backwash, with a water reserve placed above its level.



   M2 with its speed acquired in phase 1, arrives at D, or exceeds it.



  A ratchet placed on the T1 or T2 and the sheaths (See above) prevents it from falling back down, It then undergoes:
Phase 2:
Its low density makes it undergo an upward push, it thus exceeds the valve 2 which closes and again ensures the tightness of the fluid compartment C2 while the valve 1 opens to let pass M1 while the valve 3 also opens to drain the water from the intermediate compartment, which becomes aerial again. M2 thus arrives at A, the pawl 2 prevents it from coming back down, M1 returns to C, the movement continues so on ...



   However, when M1 travels 1 + 2, M2 travels 3 and goes to A.



   When M1 goes to D, M2 goes to B, then travels 2 + 1 while M1 goes back 3 to go to A, it will only be there when M1 has traveled 2 + 1 'and will be in D. Now, for To get there, V1 must be open. The valves must therefore operate in such a way that as soon as the mass passes through V2, it closes and causes the opening of V1 to allow the twin mass to reach zone D. On the other hand, the closure of V1 can only be done when it is certain that the mass having undergone Archimedes' push in compartment C2 has arrived at A in order to allow the opening of V2, without this, the fluid compartment would flood the intermediate compartment whereas the mass therein would not yet have started its journey on slope 1, so would come back down at the same time as the upper level of the liquid in the C2.

   The two masses would also be together in the new fluid compartment Ci + C2 thus created. The opening of V2 and the closing of V1, will therefore only be done when the mass having undergone the force G is in D. In order to be sure that the second mass having undergone Archimedes' push is in A., blocked by its pawl and ready to start its path 1 under the action of the force G. The contact of this pawl can possibly serve as signal for opening pulse for V2, closing for V1.



   Notes on pawl 2:
Any other system preventing mass from descending and forcing it to start its course on slope N01 can also be used. For example :
A retractable system for the passage of T1 put back in place (pushed back by a spring) after the passage of the latter.



   (See diagram A) We can consider providing this mechanical part with an ascent system, which pushes T1 to the starting point of slope 1 where the mass will again undergo the force G.

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  Electric fin system that will support and propel M to its starting point on slope 1.



    '' Small valve system in the inner wall of the compartment
C2 (V. Diagram B), the valve rises, raises the level of
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 water in C2, so the height of the mass travel to
A, then, as soon as the mass is engaged in slope 1, retraction of said valve while the mass freely begins its movement from A to B.



   We can also consider that the mass propelled by the Archimedes Principle rises slightly above A, a ratchet prevents it from falling and forces it to engage in an inverse curve bringing it back on slope 1 at J (V diagram B).



   The heights and distances 1,2, 3 as well as the sizes of the masses and compartments will be studied so that the filling and emptying of the intermediate compartment as well as the movements of the hermetic valves and the replacement of the water by the communicating vessel have the time to get done. When the masses are subjected to the force G, only their air resistance surfaces and the height of the fall will influence the MRUA and not the mass itself. The two masses having the same exposure surface, the density will therefore be established so that the speed of ascent into the water is as much as possible the speed of descent into the air compartment.

   In addition, in this example, the two masses being connected in a closed circuit by the transmission belt, the movement of one is synchronized by the other; or, at least, are they interdependent; for example, that arriving at C will exert traction on the second favoring its engagement in the slope 1. This aspect is also found in the example of transmission distributed in separate compartments envisaged below; Indeed, (see Diagram H) the fact of connecting two axes between them (for example: axes 9 and 10) automatically results in the influence of the movement of one mass on the movement of the other through transmission chains where the said masses cling.



   20 Second type of journey:
The two compartments are distributed in a circle (see Diagram A ").



   At point A, the mass undergoes terrestrial attraction, it descends, passes valve 1 which closes; V2 opens, the mass rises in C2. The reasoning is always the same, except for the facts that in this case: the impact, during the fall of the mass in C1, is nonexistent. the mass M1, if it is floating in its entirety, will go back up in the liquid column Until its center is in Ax.



   The pull exerted by M2, after having undergone G combined with the push that M1 underwent in C2, should be enough for the latter to exceed A to undergo in turn the force G, if not, a simple additional push caused by any which propulsion system will generate this movement.

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   30Single mass system:
The reasoning applied to the system with two masses is the same without the problems of synchronism: the mass enters the Ci, the valve closes, V2 opens and the mass undergoes Archimedes' push.



   40 One column system: Diagram K: m = mass of the object.



   M = mass of water
In this system, the mass is suspended at point A by a ratchet above the column filled with water. The column is emptied outside after opening a valve which is either mobile (V1 ') or fixed (V1) through which the water flows. This flow turns a turbine TU1, which will produce an energy E1 coming from the force F = at MgH developed by the fall of the volume of water whose level passes successively from points 1 to 2 to 3 etc ... with the height fall decreasing over time.

   The empty column, the ratchet releases the mass which goes to B and develops a force equal to F1 = m1 gH transmitted to a generator; similarly a turbine or better a rotary paddle (P) mounted on a bearing like the mass and equipped with floats F. located under its supporting structure descends at B, developing the same force F2 = m2gH m2 being the mass of the paddle or turbine system. M1 is retained at B by a ratchet. The water which has flowed from the column has been collected in a low height tank (B *), it is pumped back into the column, the energy (E1) produced by the flow of water in the first phase, will be reused completely to pump water back into another low-rise tank B 'closed by a valve V2.

   Indeed, the force produced by the flow of the mass of water located in 1, will be used to pump it back in 1 ', that located in 2 to pump the same in 2' and so on until X.



   The result is therefore almost zero. M1 remains in B attached to its pawl, on the other hand, as the column is filled, the water which flows is channeled on the paddle (or turbine) P which will develop an energy Ep, its rotation being transmitted by belt or chain to a generator, moreover, this paddle (or turbine) is placed on a float. The rising water level will lift everything up and develop a force according to the Archimedes Principle. This movement transmitted by belt or other means to a generator will produce a force (Fp) transformed into
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 energy: when the water level reaches point 0, the column is filled, the pawl B opens, releases the mass M1 with a density lower than that of the fluid M1 rises and will catch on the pawl at the end of the strokes Who is holding it back.

   Developing a force (FM1) = (M-m1) gH recovered by transmission to a generator, then the movement begins again. To avoid the impact of the mass M and the paddle with the bottom of the column, either all the energy developed by their fall will have been transmitted, or the mass and the paddle may not arrive on a dry bottom, but penetrate into water maintained at an N1 level; in this case, the water flow will only be done up to this level in C. The results and principle remain the same, but on different heights. In conclusion, the force produced by the emptying of the

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 column is reused to fill it then, but the following forces and energies are recovered: F1 + F2 + Ep + FP + FM1.



   Several columns will be coupled in parallel and synchronized so that the energy efficiency is maximum and smoothly.



   4) Hermeticity of the intermediate and fluid compartments:
The compartment C2, must, when the valve 2 is closed, be completely hermetic and retain the water or the chosen fluid so that the mass which is located there can undergo Archimedes' push and rise towards the surface in its gutters. circulation to point A. Similarly, when V2 is opened with V1 closed, the intermediate compartment becomes liquid and must be sealed in order to keep the fluid coming from C2 there. It is therefore necessary for the mass to continue its journey without the fluid leaving the new compartment Ci + C2 created. The various possibilities envisaged will influence the type of valves at least their surfaces, their structure and their configuration.

   In all cases, unlike C1, Ci and C2 consist of complete walls closed in a box in which G1 and G2 are included and allowing only the moving valves to pass.



   Examples of solutions: (any solution already existing on the market can be used) a) The simplest is to seal the internal walls of the compartments from the level of valve 1, while allowing the movement of the masses on their bearing at balls R1 and R2 in the sheaths G1 and G2, The internal wall of G1 and G2 can be closed by valves cut in angle and retractable at the time of the passage of T1 and T2. These pieces can be completed by another smaller and hermetic one fixed on T1 and covering on the outside (outside always seen in relation to the center of the mass M) the space opened by T1 in G1, during its passage through the wall internal this part preventing the flow of water-Diagram A '.



   These retractable parts can be incorporated in the ducts G1 and G2 and carry the balls of the gutters. On passing R1, they will open just enough to let T1 and T2 or T3 T4 pass and then close (diagram C). b) A fixed gallery is created, external to G1 G2, extending their upper and lower walls as far as against the fixed frame; over their entire length in the intermediate compartment and the fluid compartment from V1.



   In this case, V1 and V2 extend to the outer edge of the outer wall of G1 and G2. (V. Diagram A and diagram D).



   If a transmission belt is used, it will be fixed on T3-T4 which will be steel strips (or other), the thinnest possible.



   In the compartment described above, which therefore extends outside the sheaths, from V1 to the top of C2, we hang in the fixed wall and the external wall of G1 and G2, at V1 and V2, two rolls

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 extending into said walls by ball bearings allowing them to turn on themselves, letting the belt pass and ensuring the tightness of the new external compartment created.

   (diagram A and D-top view). c) In the same context of new external compartmentalisation, the transmission can be done by a link chain; in this case, the communication surface created by the passage of the chain between C 1 and Ci and Ci and C2 at the level of the external compartment at G1 and G2 (and / or T3 and T4 entails the chain) is weaker and made hermetic by the small box stuffed with grease in which the chain passes between two gears: an upper, a lower. (Diagram D).



   In the case where the two masses are not directly connected to each other, there is no need for continuity of the belt or of the transmission chain between the three compartments, the hermeticity problem therefore no longer arises, since the valves V1 and V2 will suffice to ensure this at each passage of the masses in the compartments to be isolated independently of each other; no room should be simultaneously in both.



   5) Examples of valve types:
The valves should be made of as light a material as possible to reduce the work required for their mobilization. They can be activated electrically or mechanically. In the first case, an IR beam, cut by the passage of the mass at D where a switch connected to the pawl 1 will trigger the closing of V1 and the opening of V2. The passage of the mass after V2 will do the opposite. Closing of V2 + opening of V3 + V1 and emptying of the intermediate compartment. The principle remains the same with mechanical opening and closing. In particular for the N'l valve, it can be closed by force G., thanks to its own weight For example, one can imagine a pulley on a ratchet, winding a cable intended to raise the V1.

   At the time of the passage of the mass (M1 or M2), the end of the rod T1 or T 4 releases the ratchet, or any other locking system releasing the pulley which, under the weight of V1, will rotate and let V1 go down. If V1 is connected to V2 by two cables on a pulley, closing V1 causes or facilitates opening V2. If we manage to seal the inner wall of G1 and G2 (V. before 4a) in Ci and C2, the valves will obstruct all the light going from the upper wall to the lower wall of the fixed frame, in the thickness of the internal walls of G & and G2 (diagram F for example).



   If, on the other hand, we cannot seal the internal wall of G1 and G2 over the entire height corresponding to Ci + C2 and we use solutions 4 b and c, the valves will occupy a lateral area ranging from outer edge of the outer wall of G1 to the outer edge of the outer wall of G2 in front of the hermeticity systems 4b or 4c. In this case, when they are removed, the valves will leave a void of beads in the wall

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 upper and lower of G1 and G2. They will therefore be extended by rods supporting sections of ball sheaths (type G1-Gé) which will fit into the void to fill the absence of rolling allowing progression without friction or snag of R1 and R2 (V.

   Diagram F)
One can also consider a rotary and alternative valve; two axes of rotation external to the fixed frame and located more or less on either side of point D, rotate a drum or half drum; much like a paddle wheel or a washing machine drum; The wall of the drum is alternately full (valve) then empty so that the reciprocating or rotational movement imparted to the solid part, allows the latter to act as a closing valve when it is fitted between the walls of 'a compartment while the vacuum following it will act as an open valve.



  Thus, V2 (full part in place in C2) is closed. The drum turns, the solid part (currently V2) also turns; fit into C1 acting as closed V1, and leaving the empty part in its place, ie open V2.



   B. Other examples of construction with two independent masses. a) Example of embodiment especially envisaged in the case where it would be impossible to seal the ducts G1, G2) of circulation in the intermediate and fluid compartments because of the continuity of the belt between the two masses and through the three compartments; in this case, the transmission belt is not fixed on the outer support rod T3 and / or T4, but tensioned between the small transmission axes of the generators themselves. These axes may however not directly induce the production of electric current, but be free. In this case, they will only be used for the transmission of the force produced by the movement of the masses to a central axis, the rotation of which will be directly inductive of an electrical production.

   The belt or the transmission chain has an anchor point where a hook included in the external rods T3 T4 will be hooked (or any other attachment or drive system)
For example, (See Diagram A 3), retractable hook system: (clothespin type). At point A, the hook secures the transmission belt thanks to the anchoring ring provided for this purpose on its upper face and causes its movement. Arrived at the level of valve 1, an angled stopper opens the clamp, therefore lifts the retractable hooking lug inserted in T3 and T4 and releases the belt which circulates outside the intermediate and fluid compartments (diagram H), around of its own axes 1,2, 3 4.



   After this course, the latching system, under the action of pressure exerted by a compressed return spring during the previous phase or any other pressure / counter pressure system, takes its place again to re-secure the belt located in the Ci around the axes 5,6, 7,8 and independent of the previous belt, at least inside Ci. The axes 5,6, 7,8 of the intermediate compartment will be driven by the movement of this belt .

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   Arriving at valve 2, same re-release operation with angled stopper, then past this valve, the hook resumes its stowage of the belt thus driving the axes 9, 10, 11, 12 according to the same principle as above.



   Arrived at the point corresponding to the axis 10 new stopper so that the hook is again tied to the transmission circuit of the axes 1,2, 3,4.



  The axes and the belt circuits can be made interdependent thanks to a possible coupling by an entirely external belt connecting for example two axes, the 1 and the 9.



   Consequently, when M1 unhooks the belt at the level of valve 1, M2 takes over as regards the movement imposed on the axes 1,2, 3,4.



   In the case considered above, three separate and independent transmission zones are therefore created, each corresponding to a compartment C1, Ci, or C2, thus avoiding the problems of hermetic insulation of the compartments Ci and C2, since each compartment has its own transmission system without any passage from one to the other affecting its tightness by letting pass the fluid intended to allow the application of the Archimedes Principle, therefore to do reassemble the mass concerned towards point A.



     Q1 In the case of the two independent balls with belt not crossing the three compartments. Another yet simpler system is possible. (Diagram i) The transmission system can be eliminated in one or two compartments.



   Indeed, one can realize according to diagram H, a simplified system where only the axes 1,2, 3,4 and 9,10, 11,12 would be connected by transmission belt leaving the path of the masses M1 and M2 in the compartment completely free intermediary. Even simpler, we could even use only the force G. To produce electrical energy, thanks to the rotation of the axes 1,2, 3,4 The Archimedes Principle and its thrust only serving to bring back the mass at point A. In this case (see diagram i),
The mass M1 hooks the belt at point A. Throughout its course in C1, M1 will therefore drive the transmission belt and produce energy.

   M1 arrived at C, M2 is at A, at axis 4, that is before V1, M1 releases the belt and enters Ci then C2; M2 has already taken over the transmission, is between axes 1 and 2, therefore transmits the force of its movement in order to produce electricity, and so on ...



   C. Another example of realization with Ci permanently submerged (diagram J)
In this case, we make the following prototype:
C1 remains an air compartment where the mass will undergo the force of gravity
F = MGH, on the other hand, the intermediate compartment Ci is already filled with liquid.



   This compartment is limited by two hermetic valves V1 and V2 located at the same level with respect to the ground so that according to the Principle of

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 communicating vessels, the liquid level is the same in the portions of the left and right circulation columns corresponding to the intermediate compartment.



   When V2 is closed, it thus retains the volume of liquid located above it in the right circulation column, which corresponds to compartment C2.



   The intermediate compartment is therefore completely submerged between V1 and V2. To do this, we close V1, we fill Ci + C2 to the upper level required to re-engage the movement of mass M1 in the air compartment C1 (ie point A); then we close V2. We can then open V1 without the liquid level exceeding its level in the left circulation column (corresponding to C1) since the levels of V1 and V2 are identical. The liquid will therefore remain in balance between these two limits even if V1 is open.



   The mass M1 released from point A will undergo the force G and travel the path of length and height a + b to point B. V1 being open, it will penetrate into the liquid contained in Ci and continue its race over an equivalent depth at H2 + H3 to be calculated and dependent on H1, on the weight of M1, and on the residual force (after transmission to the generator) of the mass M1 after its fall in C1.



   By the way, this mass mounted on ball bearings, will meet at point C a ratchet where any other referral system (ex: railway rails, ...) allowing its passage down but preventing it from resuming the path C of the intermediate compartment when it undergoes Archimedes' push, and obliging it to follow the path d in Ci towards V2 and C2.



   After having gone through C1, the mass enters Ci where it displaces a volume of liquid equal to its own which will overflow above the level of V1, in C1 and will be collected in a tank (BAC), V2 being at this moment closed.



  M1 will continue its race up to the lower limit H3 before climbing under the action of Archimedes' push which will return it on the path d from compartment Ci towards V2 and C2 since the ratchet or any other referral system will prevent its race to path c; V1 closes, V2 opens and M 1 begins its ascent to A.



   V2 will not close until after the passage of M1 beyond point D, the water level in the intermediate compartment will find a new equilibrium between V2 closed and V1 open.



   The two valves can also form only one prefabricated so that V2 closed, V1 is open and vice versa if however such a structure does not increase the handling, the closing time and the consumption of energy required for the operation. M1 arrived at A, he resumes his race in C1, the communicating vessel (VC) having filled C2 with the volume of liquid necessary to bring M1 back to this position (volume corresponding to the volume of M1)
In A, M1 will again undergo G thanks to the slope a and, if necessary, to a small impulse provided by a piston P.

  <Desc / Clms Page number 13>

 



   Along its course, the mass, as in the previous examples, is connected to straps or to any other transmission system allowing the transfer of the force deployed to electric generators.



   The advantages of this model compared to the previous ones are: 10 it avoids the problems of resistance of materials inherent to the impact of the mass and its ball bearings, at the end of stroke C1, with the angle of the gutter d 'access to Ci. Indeed, in this case, M1 continues its journey perpendicular to the ground, without any change of direction, and in a less brutal liquid medium up to the lower limit of H3. There is therefore no longer any shock between the bearings (R1 R2) made of solid materials and the angle of the gutter giving access to Ci also constructed of hard and resistant materials.



   20 The path traveled by the mass, therefore the work provided and transformable into electrical energy is done over a longer path which is equivalent to: a + b + c + d + H1 while the force required to re-pump the volume of water lost in the BAC and equal to the volume of the mass, towards VC and in order to fill C2 will only be that necessary to bring the equivalent in volume of water of M1 to a height equal to H1.



   30 Two valves are sufficient.



   40 Another possibility can also be envisaged to reinsert in the liquid compartments the volume of water corresponding to the volume of M1, and expelled when the mass enters the liquid intermediate compartment - a hydraulic piston can be placed below the level of V1 or V2 and connected to the intermediate compartment. (Or any other more suitable place)
This piston will push back the volume of liquid collected in the BAC, towards Ci. A complete study of the pressures to be overcome during the realization of this operation will make it possible to check IF the force necessary to carry out it is equal, superior or inferior to that necessary to re-pump the same volume of water over a height H1 to point A.

   Likewise, the position and the most advantageous possible connection of the piston will also be determined.



   Another remark:
In this example, M1 should have a shape that minimizes its resistance to water penetration and therefore the impact shock it will undergo at this time.



   50 Even simpler, the expelled water flows over a height H2 + H3 and actuates an external turbine as for a normal dam, in this case, the result of recoverable forces. If m = mass of M1, M mass of water = F = mgH1 + Mg (H2 + H3) + Mg (H1 + H2 + H3) -mg (H1 + H2 + H3) or Mg (H1 + H2 + H3) + (Mm) (H2 + H3) or M = Mass of water; the density of water in water being twice that of wood; for example, we therefore have an additional force compared to the normal barrage or certain elementary tests with a non-acro dynamic floating body shows that H2 + H3 = sometimes 2 times H 1


    

Claims (2)

Claims. The invention is a process which is characterized by the use or even the coupling of two natural and opposite forces (Lforce of Gravity (FG) and Principe d'Archimède) in order to obtain a resulting force and a work intended to produce energy. For example, electrical energy. The invention is also characterized, among other things, for this, by the use of one or two objects or bodies of mass M1 = M2, and of density as small as possible, interconnected or independent of one another. , made mobile by any system that minimizes frictional forces during said movement. For example: the ball bearing. These objects circulate in a fixed frame serving as support and in which succeed two environments C1 and C2 of different physical character; the first, in the open air will subject the said mass (s) to a force of attraction G. The second, fluid and hermetic, will make it possible to apply to the objects a thrust according to the Principle of Archimedes. Its nature will be such that it will maximize the buoyancy of the objects you dive into. (E.g. salt water). In order to avoid the pressure of the weight of the water during the passage from the first medium to the second, an intermediate compartment can be created. This will be alternately filled with air and water to allow the passage of masses from one medium to another. Another possible embodiment is to drown this intermediate compartment between the valves V1 and V2 (diagram J) so that when V2 closed and V1 open, the liquid remains in equilibrium between these two levels by the principle of communicating vessels. In this case, the mass M1, after having undergone the force G in the compartment C1 penetrates vertically, at the level of open V1, inside Ci filled with liquid where it will continue its race along the conductive gutters to a depth directly influenced by its physical characteristics and the height of its fall. At the end of this race, the mass will undergo Archimedes' push and will therefore begin the opposite path. However, a ratchet or a referral system will prevent it from going up along the initial gutter and divert it towards the gutter giving access to C2. At this moment, V1 closes in order to retain the volume of liquid contained in C2 + Ci and V2 opens allowing the passage of M1 in C2 and its return to point A. In the perspective where Ci becomes alternately air then liquid ( 1 st example envisaged above), a system of synchronous hermetic valves will allow filling and emptying of the intermediate compartment and of the C2 according to the needs of the free circulation of the masses in movement from an air compartment C1 to the fluid compartment C2. The bodies, (or objects) in movement have a mass M which, in a first phase, (displacement in the air compartment C1), will make them <Desc / Clms Page number 15> to undergo the terrestrial attraction, therefore a force G., which will involve them towards the ground. They are characterized by the fact that their density will be such that they will be as floating as possible, so that, during a second phase (passage through the liquid compartment), they undergo a maximum upward thrust (Principle of Archimedes) bringing them back to their starting point. This (or these) objects will thus be able to follow a course from top to bottom (force G) THEN from bottom to top (Archimedes) bringing them back to their initial starting point following a perpetual almost spontaneous movement. According to the physical criteria of the system; masses, weight, density, height of fall and ascent, this movement will generate a force and a work which can be transmitted by any means (belt, chain, ...) in order to be recovered and used for various needs. In the examples chosen, the transmission takes place at dynamo axes of rotation and the resulting force thus transmitted will be used to produce new energy: electrical energy. During the fall in an aerial medium (compartment C1) the body of mass M will evolve according to a uniformly accelerated rectilinear movement depending on the height of fall and develop an increasing force up to its point of impact on the ground where it will be maximum. This risks damaging the mechanical parts (R1, R2, G1, G2) used for the mobility of the body. This is why the angles of the sheaths drawing the course of the masses will preferably be as rounded as possible, moreover, it is necessary that at this point, a maximum of the force developed by the MRUA has been transmitted to the system intended for produce energy to reduce the impact at the end of the movement. On the other hand, a minimum of recovery will be done at the initial point, that of the start of the fall at point A., in order to allow the body to move with the least resistance possible. This can be made possible by adding to the energy transmission system a system similar to the automatic gearboxes of motor cars, or bicycle derailleurs, or any other system. The compartments can also follow one another in a closed circle, which facilitates the circulation of masses and the general movement (see diagram A "). In a fixed frame, we therefore create a circulation duct in the open air (compartment C1) where one (or more) mass (s) mounted on ball bearings or possibly rolling on themselves (round masses) undergo (s) t FG and circulates from top to bottom - A sealed C2 compartment filled with liquid where the mass or masses (with the lowest possible density) will pass and undergo an upward thrust, intended to bring them back to their initial point; and to avoid the pressure of the mass of water contained in C2 on the moving mass during the passage from C1 to C2; an intermediate compartment separated from C2 by a valve V2 closed when the mass passes from C1 to Ci and separated from C1 by a valve V1, making it airtight during filling, at the opening of V2. When the valve V2 closes to allow put the drain of Ci, a valve V3 located in its floor opens and allows Ci to become aerial again in order to accommodate the mass having undergone FG A maximum of liquid is maintained in C2 with V2 closed At the opening of V2 , V1 closes, the intermediate compartment fills with water, reducing the height of the <Desc / Clms Page number 16> column of liquid contained in C2. So the height of the ascent that the mass will undergo in C2. A system of communicating vessels between C2 and a water reserve placed above the maximum level reached by the fluid, will assume the filling and replacement of the volume of liquid lost in C2 during the previous operation. The flow must be studied to ensure the ascent of the mass at point A in synchronism with the movement of the mass evolving in C1. In reality, the volume missing in C2 corresponds to the volume of the intermediate compartment. The point Y corresponds to the point of entry of water into the C2 and will be placed so that the filling operation causes the least possible eddies. The intermediate compartment is therefore alternately filled with air, then with liquid. In short, when the mass arrives at D (diagram A), V1 closes V2 opens drowning Ci, the mass rises under the thrust suffered (Archimedes), as soon as it has passed V2, the latter closes making C2 hermetic, V3 opens to empty Ci of its liquid and V1 opens to let pass the new mass which arrives in the intermediate compartment again become full of air ... and so on .... Two pawls (or any other system intended to prevent the masses from falling again), are placed, one at the upper level of C2, the other a little above the lower curved angle of the course followed by the mass in Ci (above D). this in order to force the mass to continue its journey without being able to go back both in the Ci and in the C2. More particularly, with regard to the movement of the mass in the liquid column, the thrust will project it slightly above the upper level of the liquid, the ratchet will prevent it from going down and engage it after point A on slope 1 ( V. Diagram B + possibly system with return to J) to undergo the FG again and start a new fall downwards. This transition from the upper level of C2 to path 1 will also be facilitated by the traction operated by the second mass. The latter undergoing terrestrial attraction, and being connected directly to its twin by a belt or indirectly (V. Second type of transmission envisaged in the description) thanks to the hooking on the interdependent transmission chains and coupled thanks to axes 9 and 10 connected together outside the system, will therefore provide a tensile force facilitating the passage of the second mass from the liquid medium to the aerial medium. If, however, these combined forces were not enough to move the said mass from the upper level of C2 to the slope 1 of C 1 after point A, we can envisage a small complementary propulsion system taking charge of the operation. More particularly in the example cited, the upper pawl can be motorized and arranged with arms long enough to propel the mass to the origin of the slope 1 so that it again undergoes the force G. In diagram B , the portions 1 + 2 and l + 2 of the air path are equal to the portion 3 of the path in the liquid column in order to promote the synchronism of the movement of the two possible masses connected together. The lengths and volumes of the different compartments influencing the speed of mass movements will be studied to favor the <Desc / Clms Page number 17> same synchronism and give time for Ci to fill, to empty, as well as for valves V1, V2, V3 to perform their opening, closing, sealing, draining functions, etc. ..., without the movement of the masses being hampered and in order to optimize the performance of the system as a whole. The opening and closing of the valves can be mechanical, electrical, possibly controlled by breaking infrared beams arranged in the appropriate places. We will make the most of natural forces to open and close the valves. For example, V1 can close by taking advantage of its own weight, held by a cable connected to a pulley and fixed on a pawl. The passage of the mass can release the pawl (drawbridge type) and V1 will close by itself. even under the action of its own weight. If it is connected to V2 by two cables on a pulley, it will cause or greatly facilitate the opening of V2. Another example, the insertion of floats or ballasts filled with air in V1 will facilitate its opening when the intermediate compartment drowns. Indeed, the floats will facilitate the ascent of V1 which, connected thanks to the pulleys and cables to V2, will open under the traction of V2 which closes. If the force developed is not sufficient, it will however reduce the work to be provided. This reasoning is valid for any system of opening or closing of the chosen valves. Another system envisaged, an alternative valve system included in the description, therefore in the claims below. As of the opening of V1, a system of communicating vessels at the previously studied flow rate will allow filling C2 to maintain the fluid at a maximum level necessary to bring the mass currently located in C2 to its starting point in the air compartment C1 to undergo again the terrestrial attraction The connection of the expansion vessel with C2 will be in Y at the most appropriate place to avoid swirls The liquid lost during the emptying of Ci will be evacuated or re-pumped in the vessel in using part of the energy supplied by the system. Said liquid will have physical properties making its density as large as possible relative to the density of the masses M1 and M2 which circulate there (salt water, etc.). The force resulting from the movement of the masses as well as the work developed will be transmitted by belt, chain, ... connected directly or indirectly to the masses, or any other transmission system in order to be used for the production of new energy, in the occurrence of electrical energy through the rotary movement of the axes of electric generators. Also claimed are any improvements, modifications, ease of execution made to the invention or to its exemplary embodiments described in the claims in a non-exhaustive manner, whether thanks to the current state of technology or to future improvement thereof 1. General description of the principles used: There are in nature two permanent physical forces, immutable and in opposite directions, which are the gravity and the thrust suffered by <Desc / Clms Page number 18> any body immersed in a liquid according to the Archimedes Principle. If we manage to couple them, that is to say to impose on the same body of mass M, first one, that is to say the force G. causing the said body released from a height H " down, then the other, the Archimedes' push, bringing the same body back to its initial point, so we generate a movement of the mass from top to bottom, then from bottom to top, with return to the starting point and again application of the force G. On the body and so on. From this almost perpetual and spontaneous movement, can therefore result, by any adequate transmission (belt, chain, gear, ... or any other system ,. ..) a driving force or other intended to produce energy (mechanical, electrical, ...) one of the basic principles of the invention is therefore to use one or more objects 0, of mass M "and of density P making this body as floating as possible in a FL "fluid (salt water, ...) also promoting maximum buoyancy therefore the thrust that the object (0 "will undergo upwards, when it passes from an aerial C1 compartment, where it undergoes the force F towards that (liquid C2) where it will undergo the thrust according to the Archimedes Principle. The object (0 ", dropped from a height H, undergoes the force Guet after a uniformly accelerated movement, will touch the ground after a time T depending on the height at which it will be released and its surface of resistance to air but not of its mass. On the other hand, any body immersed in a liquid undergoes a push from the bottom upwards directly proportional to the volume of liquid displaced. the more the upward thrust will be important. It is the principle of buoyancy which allows, among other things, to see steel ships floating of hundreds of thousands of tonnes or even to bring to the surface, sunken ships by wrapping them in sheaths connected to large inflated gas balloons. The invention therefore uses a mass object, which released in a first compartment C1, will undergo the terrestrial attraction but of density such that it will be floating, unsinkable and that, during that it will be passed in a compartment C2 filled with salt water (or other fluid favoring buoyancy to the maximum) it will undergo a push from the bottom up, returning it to the air compartment C1 from which it comes initially in order to to undergo there again the terrestrial attraction and the force G which will bring it back towards the ground, then in compartment C2, and so on. The movement generates a force F resulting from the couple of the two opposite forces. If the object or objects concerned by a transmission system (belt, chain, etc.) are connected to, for example, an electric generator, the resulting force F "will cause the axis of this electric generator to rotate (the armature in the inductor) therefore producing electricity. In one of the exemplary embodiments described below, two similar masses M1 and M2 are used which are connected together by a transmission strap; the movement of the two masses causes the rotation of a or <Desc / Clms Page number 19> several axis (s) of dynamo or electric generator. Several prototypes are possible:. with a mass, two masses connected to each other or independent. . The transmission of the force resulting from the movement of the mass or masses can take place towards one or more rotary axis (s) producing the desired energy as a result. This or these axes can be separated, at the center of the system or at the periphery. The object of the invention is therefore to produce an energy inducing force from existing natural, permanent and non-polluting physical forces. He. Description of non-exhaustive exemplary embodiments: A) Two masses connected together by a belt: Let us take for example two round masses with the smallest density possible, connected together by the belt which will transmit the force resulting from the movement of these two earths to one or more electric generators. 1) Let us recall some definitions: The mass of a body is the constant ratio of the force acting on this body to the acceleration that this force communicates to it. M = F / a. The intensity of a force is the product of the measurement of the mass on which it acts and the measurement of the acceleration that it communicates to it. Force unit: Newton = 1 kg x 1 m / s2. The weight of a body is the measure of the force exerted by the Earth on the mass of this body. The study of the free fall of bodies shows that a falling body takes a uniformly accelerated movement whose acceleration of gravity is represented by G. (P = mg.) A body withdrawn from the action of gravity a therefore a zero weight, while its mass remains invariable is M = F / a; she can therefore continue to be subjected to force. However, in the invention, the passage of the mass of density as small as possible in a liquid compartment subtracts it almost completely from gravity and subjects it to a new force of opposite direction thanks to its buoyancy. These two opposite forces provide a work numerically equal to the product of the intensity of the force by the length of the displacement. T = F x dist. And whose unit is the Joule, that is to say 1 Joule = 1 Newton x 1 meter. The total power of the system will be expressed in Watt, that is to say, the total work in Newton provided by the system in one second, from which it will eventually be necessary to deduct any work to be provided for the proper functioning of the system. (Possibly, pumping of recovery water, operation of the valves, etc.) in order to obtain the actual final power and the percentage efficiency of the system. Concept of density p: <Desc / Clms Page number 20> p = ratio of the mass of a body and its volume p = MN = Kg! m3 p of water 103 Kg! m3 seawater = 1166 Kg! m3. The lower the density of the masses concerned by the movement of the invention, and the higher the liquid density, the greater the force undergone by the mass or masses. Therefore, the greater the thrust bringing the mass (es) back into the aerial behavior. 2) Examples of description of the masses and their mobilization system. The masses can be of aerodynamic shape in order to decrease the friction of the air in the compartment C1 and to increase the force G. In the example taken diagram A, the masses will be round, out of wood or out of hollow metal filled with air, gas, or any material that makes it as buoyant as possible. They are connected by two rods T1, T2 to small ball bearings, balls R1, R2 themselves anchored in rigid sheaths G1, G2 included in a fixed frame intended to support the whole system. In compartment C1 (see general diagram), the frame is limited to gutters and their supports, therefore, not closed in order to minimize the compression of the air generated by the movement of the mass during its descent, therefore the resistance opposed to the movement thereof. On the other hand, C2, liquid compartment, is closed and hermetic. On the lower face of the upper sheath (Gs) and the upper face of the lower sheath (Gi), are anchored balls or bearings in contact with the ball bearings R1 and R2 of the rods carrying the masses M1 and M2. This allows a movement almost free of friction, therefore with a minimum loss of force. The ball bearings R1 and R2 are extended outwards by other rods (T3, T4, as thin as possible + or-the same thickness that the belt) of transmission on which are fixed the belt, chain, or any other system ... which will transmit the forces of the movement of the masses to an electric generator. 3) General description of the system: (diagram B) 10 Description of a type of path imposed on M1 and M2 in the system serving as an example (two masses connected by the transmission belt). The masses M1 and M2 move therefore thanks to the ball bearings to which they are connected. Their course is located first in a first compartment in the open air Cl, then in an intermediate compartment Ci limited by two hermetic valves V1 and V2 and finally ends in a column of liquid C2, ie different successive phases: <Desc / Clms Page number 21> phase 1 by gravity force at the start M1 is at D; the liquid column, therefore C2 and Ci are drowned; M1 is retained, M2 is at A. The movement is launched; M1 arrives in zone A, given the slope 1 and the pawl 2, it undergoes the force G. And will move downwards on the ball bearings, at this moment, M2 has already undergone the force G and is in position zone C. The vertical fall having caused a significant acceleration, the force developed by M2 is substantial; there is therefore a risk of there being a significant impact between the bearings and the curved angle of the gutter at point C. To reduce the impact, we can envisage a curved gutter path at the points where the masses change direction, ie A , B, C, D. To reduce the impact and not damage the moving parts, it is therefore necessary that a large part of the force developed by the MRUA undergone by M2 is recovered by its transformation into motive energy transmitted by the belt. . We can therefore consider, for example, that this transmission is made to the dynamo axis by the belt coupled to a kind of automatic car gearbox or bicycle derailleur. Similarly, the recovery of the force produced by the mass is almost zero at point A, the start of the race in order to allow easy movement, while it will be greater in C in order to reduce the impact due to the mass drop. An exact study of the forces, masses, heights and resistance of the materials will make it possible to precisely calculate the transmission logic to be applied. In C, M2 therefore has a speed and a force transmitted to the axis of the dynamo, but also to M1 since the two masses are connected by the transmission belt, although M1 already has its own upward propelling force (Principle Archimedes), it will also be pulled by the belts to exit the fluid compartment. A ratchet placed on or in the internal wall of the ducts G1 and G2 and will allow the passage of T1 T2 upwards, but not its return back. The pawl will be placed at a height which will prevent M1 and M2 from going back down and will force them to start their race in the gutter of the path concerned and to undergo either the force G or the Archimedes push. When M1 arrives in zone B, M2 is then in zone D, the valve N01 closes, isolating the intermediate compartment, that is to say the one created between valve 1 and valve 2, while at the same time, the valve 2 opens, letting the water enter the intermediate compartment, which thus becomes an integral part of the fluid compartment C2, the Ci is therefore in the air, then fluid. Water is immediately replaced by a system of communicating vessels connecting C2 at a point Y, located in the most adequate way to avoid backwash, with a water reserve placed above its level. M2 with its speed acquired in phase 1, arrives at D, or exceeds it. A ratchet placed on the T1 or T2 and the sheaths (see above) prevents it from falling, it then undergoes: Phase 2: <Desc / Clms Page number 22> good low density makes it undergo a thrust towards the naut, it thus exceeds the valve 2 which closes and again ensures the tightness of the fluid compartment C2 while the valve 1 opens for allow M1 to pass while the valve 3 also opens to evacuate the water from the intermediate compartment which again becomes aerial. M2 thus arrives at A, the pawl 2 prevents it from going down again, M1 returns to C, the movement continues thus immediately ... However, when M1 travels 1 + 2, M2 travels 3 and goes to A. When M1, goes in D, M2 goes to B, then travels 2 + 1 while M1 goes back 3 to go to A, it will only be there when M1 has traveled 2 + 1 'and will be in D. However, to get there, it V1 must be open. The valves must therefore operate in such a way that as soon as the mass passes through V2, it closes and causes the opening of V1 to allow the twin mass to reach zone D. On the other hand, the closure of V1 can only be done when it is certain that the mass having undergone Archimedes' push in compartment C2 has arrived at A in order to allow the opening of V2, without this, the fluid compartment would flood the intermediate compartment whereas the mass therein would not yet have started its journey on slope 1, so would come back down at the same time as the upper level of the liquid in the C2. The two masses would also be together in the new fluid compartment Ci + C2 thus created. The opening of V2 and the closing of V1, will therefore only be done when the mass having undergone the force G is in D. In order to be sure that the second mass having undergone Archimedes' push is in A., blocked by its pawl and ready to start its path 1 under the action of the force G. The contact of this pawl can possibly serve as signal for opening pulse for V2, closing for V1. Remarks on pawl 2: Any other system preventing the mass from going down and forcing it to start its race on slope N01 can also be used. For example: 'A retractable system for the passage of T1 put back in place (pushed back by a spring) after the passage of the latter. (See diagram A) We can consider providing this mechanical part with an ascent system, which pushes T1 to the starting point of slope 1 where the mass will again undergo the force G.. Electric fin system which will support and propel M to its starting point on slope 1. 'Small valve system in the inner wall of compartment C2 (see Diagram 8), the valve rises, raises the level of the water in C2, therefore the height of the travel of the mass towards A, then, as soon as the mass is engaged in slope 1, retraction of said valve while the mass freely begins its movement from A to B. We can also consider that the mass propelled by the Archimedes Principle rises slightly above A, a ratchet <Desc / Clms Page number 23> prevents it from falling again and forces it to engage in an inverse curve bringing it back on slope 1 in J (see diagram B). The heights and distances 1,2, 3 as well as the sizes of the masses and compartments will be studied so that the filling and emptying of the intermediate compartment as well as the movements of the hermetic valves and the replacement of the water by the communicating vessel have the time to get done. When the masses are subjected to the force G, only their air resistance surfaces and the height of the fall will influence the MRUA and not the mass itself. The two masses having the same exposure surface, the density will therefore be established so that the speed of ascent into the water is as much as possible the speed of descent into the air compartment. In addition, in this example, the two masses being connected in a closed circuit by the transmission belt, the movement of one is synchronized by the other; or, at least, are they interdependent; for example, that arriving at C will exert traction on the second favoring its engagement in the slope 1. This aspect is also found in the example of transmission distributed in separate compartments envisaged below; Indeed, (see Diagram H) the fact of connecting two axes between them (for example: axes 9 and 10) automatically results in the influence of the movement of one mass on the movement of the other through transmission chains where the said masses cling. 2 "Second type of journey: The two compartments are distributed in a circle (see Diagram A"). At point A, the mass undergoes terrestrial attraction, it descends, passes valve 1 which closes; V2 opens, the mass rises in C2. The reasoning is always the same, except for the facts that in this case: the impact, during the fall of the mass in C1, is nonexistent. the mass M1, if it is floating in its entirety, will go up in the liquid column until its center is in Ax. The pull exerted by M2, after having undergone G combined with the push that M1 underwent in C2, should be enough for the latter to exceed A to undergo in turn the force G, if not, a simple additional push caused by any which propulsion system will generate this movement. <Desc / Clms Page number 24> 30System with a mass: the reasoning applied to the system with two mass can be the same without the synchronism problems: the mass enters the Ci, the valve V1 closes, V2 opens and the mass underwent Archimedes' push. We can further develop and improve the system in the following way (or ways) see diagram L 1-in order to increase the yield, the mass M can fill with water in column C2, thanks to the opening of a valve which it will contain, before falling back into the air compartment Cl. In this case, when the mass falls it develops a force, or a work expressed by: M, being the mass of the sphere or of any object used MV " "" of the volume of water corresponding to the volume of the sphere Fl = g (M + MV) Tl = g. efficiency coefficient. (M + MV) (H + H ') efficiency coefficient = 0.89 2-La mass filled with water is in Ci, Vl closes, the valve contained in the mass opens, letting the water it contains flow in Ci, up to half its volume, thanks to gravity, the other half being expelled by compressed air (Rq: the mass is then perhaps already floating) This operation requires work equal to: T2 = g. MV / 2. H '/ 2. 100/89 Ce job perhaps recovered later, either by reinjecting the volume of compressed air into the mass which will follow, or by releasing the compressed air on the surface, or in any other way. Ci is then completely drowned. 3-V2 opens slowly, the mass slowly engages in an "airlock" created between, a wall which rises in C2 parallel to its right side wall and at a distance equal to the diameter of the mass, and the right side wall of C2, so when the mass rises it does not let the water which flows into it (to take the place of the volume of the mass) into the opening of a second "airlock" fitted with a turbine, or, of any other energy recovery system, airlock extended by a conduit bounded on one side by the left side wall of C2, and on the other by the left side wall of the first airlock (wall N03) The water that s flow on this turbine therefore produces a recoverable T3 work, in fact, the hydrostatic pressure is transmitted in all directions with the same intensity and remains constant, the water which will occupy EMI24.1 the volume of M will therefore develop an equal workT3 to: T3 = g. MV. (H H I '). 0.89 4 Rq: Ci = V1 + MV and V1 = MV V1 being the volume of water surrounding the mass in Ci. 4-The mass rises in the liquid column C2, up to a height H + H '/ 2 AND develops a job T4 = 0.89. G. CMV. (H + H '/ 2) -M. (H + H '/ 2)) V2 closes leaving Ci completely drowned. 5-The water of Ci must be pumped back to the upper level of C2, or the current level of the water column is at a height = H + HI / 2 The work to be produced for this operation, ie for that 2 X MV is pumped back and brings the level of C2 to a height H + H '/ 2 will be T5 = 2. MV (H + H '/ 2). 100/89. ace <Desc / Clms Page number 25> Delta Tsera is therefore equal to: Tl + T3 + T4-T2-T5 EMI25.1 EITHER: DELTA T = 0.89g (M + MV). (H + H ') + MV (H + H' / 4) + MV. (H + H '/ 2) - M (H + H' / 2)) 100/89. g. (MVH '/ 4 + 2 MV. H + 2MV. Hie DeltaT = 0.89 g. (MH + MH' + MVH + MVH '+ MVH + MVH' / 4 + MVH + MVH '/ 2-MH-MH' / 2) - 1.12 (MVH '/ 4 + 2. MVH + MVH') DELTA T = g. (0.89MH + 0.89MH '+ 0.89MVH + 0.89MVH' + 0.89MVH + 0.89MVH '/ 4 +0. 89MVH 0. 89MVH '/ 2-0. 89MH-0. 89MH' / 2-0. 28MVH'- 2. 24MVH-1. 12MVH ') DELTA T = 0.444MM' + 0.43MVH +0. 1575MVH "If we use a floating mass of office, (wood etc ...) F1 becomes: M (H + H ') but F5 is reduced to MV once to pump and plus two. This considering the yield at 0. 89 The result will, of course, be more substantial if the efficiency coefficient is higher. It is also obvious that this system, combined with a traditional dam, will see its efficiency increase due to the fact that pumping is no longer necessary. adds to the system described above, an independent system intended to return the water 'corresponding to 2MV towards f2, the latter can be used in closed circuit, which reduces F5 to produce: example of description: (diagram L and M) : parallel to the tube C2, where the mass rises, a tube T3 filled with water is placed over a height H + H '+ H' / 2 calculated from the zero level which will be hers (therefore its lower wall) and corresponding to the lower wall of Ci. Ci being connected to the lower or latero-lower wall of T3 by one or more connections, provided with valves (V4) allowing water to pass from Ci to T3 but closing on the return-from T3 towards Ci. At the free level of T3 (upper level of the water column) there is a hermetic and floating piston above which there is a compression chamber or the piston compresses the air, the gas being there. This compression chamber is subjected to the pressure of the piston P which rises under the pressure exerted by the water column of T3 when the latter is raised. This compression chamber is in connection with T4 thanks to a V5 valve. T4 is a duct or box filled with compressed air itself connected to Ci on its upper wall. or the upper superior, through a valve V6 which closes on the return but lets the compressed air penetrate 'Ci from T4. Different stages of the system: 10-Ci filled with water after the passage of the mass and the closing of V2 is emptied in T3 under the pressure supplied by the comp air. released by T4 through V6. This operation therefore requires a workAl necessary to produce the pressure PI which will eject 2. MV volume of water contained in Ci vres T3 is the work necessary to raise the free level of water from T3 to a height = at H + H '+ H '/ 2 + H' is a work equal to 2. MV (H '+ H + H' / 2 + H '/ 2). G or (2MV + Mass of T3). G. H '. Under this pressure the water of Ci moves inside T3, when Ci is empty V4 closes <Desc / Clms Page number 26> 2 -The pressure = F / S exerted on a liquid is transmitted in all directions with the same intensity the piston located above the water column filling T3, will therefore also undergo the pressure exerted on said column by compressed air which expels water from Ci and increases and, The volume, and Lq height of column T3. P will therefore exert a pressure PI on a height H 'and on a volume = 2MV of gas or air located in the compression chamber. The piston therefore pushes back in T4 the compressed air which it lost by emptying into Ci under pressure PI. 3-the water level has therefore increased by a height H 'in T3, the latter is also connected to C2 by a valve which then opens allowing the volume of water corresponding to 2MV to flow in order to bring the two columns at the same level, ie H + H '/ 2, their connection valve RV7 then closes. This flow produces a recoverable energy corresponding to T = 2. MV. G. H '.. In the same way the piston which falls produces a., Work recoverable when it falls equal to: its mass. G. H 'If we apply DALTON's law, the compression chamber being the pump body, T4 being the cylinder where the air is compressed, P = the pressure in the cylinder initially, ie the residual pressure after that the compressed air has passed through Ci P '= the pressure exerted in the pump body by the piston, or the pressure that it receives during the rise of the water column, corresponding to that exerted in ci for drive out 2. MV V = volume of T4 v = volume of the compression chamber The resulting pressure in the cylinder, either T4 = PV / V + P'v / V or PR in T4 = P + P '. v / V = P residual of T4 + (Pinitial of Ci + P supplied by T4 to eject the column from a height H '). v / V Now the residual pressure of T4 = initial pressure of T4 - lost pressures either initial pressure to overcome in Ci + pressure necessary to raise T3 + Ci from a height H 'either: PR = Pinitial of T4. v / V. If the volume of T4 = vol. of Ci = vol. from the initial PR = P compression chamber of T4 and the cycle continues. The compressed air in Ci to eject 2MV of Ci-can: - either: be brought back into the compression chamber to undergo the pressure of it after the latter is lowered to its initial position therefore after the water has passed from T3 to T2. This transfer n can be total or partial, part of the compressed air or all of it can be reinjected directly into T4. If the whole is not reinjected into T4 the rest can flow into the compression chamber and be subjected to pin'on pressure. - either be injected in a second. Ci of another Tl-T2 circulation system created in parallel to the first, the second Ci receiving compressed air (when full of water) from Ci N01, then returning the same EMI26.1 compressed air to CiN l when it is in turn flooded. Synchronization is of course necessary. - any other recovery system is of course possible so <Desc / Clms Page number 27> to recover the work provided to pump the 2. MV back into T3 and to reuse it for the same purpose. Indeed, the compressed air in Ci-to eject the volume = at 2MV in T3, is partitioned in Ci after this operation, it therefore constitutes in itself a power, a work, a recoverable energy which will replenish the system used to produce the compressed air intended to manufacture the said compressed air (compressor etc .; there are many systems allowing this energy recovery) A piston system lifting the mass of water T3 + 2MV can possibly replace the compressed air system , the work provided by the latter is transmitted to the piston located at the top of the column T3 and can be recovered in order to be re-injected, reused for the initial work provided by the first piston ANOTHER SYSTEM OF REALIZATION AT A MASS MAY BE THE FOLLOWING : (see next page) <Desc / Clms Page number 28> EMI28.1 ----------- The system consists of a basin, container, or any other volume filled with water, in which an object of mass M and of form F sinks from a height H by the fact that the said object is filled with water its mass therefore drives it from the bottom. The force developed by this operation provides work that can be recovered by any transmission system, among other things to an electric generator. CE work = Tl = MGH M being the mass of the object. Arrived at the bottom, the mass is connected by a valve, any other system, to a source injecting it with compressed air, which could have the effect of making the said mass floating, by the principle of Archimedes, it will therefore go back up on the surface, which generates a force and work equal to: MV. g. H-M. g. H, this force and this work are recoverable by any transmission system among other things to an electric generator, MV being the mass of the volume of water displaced during the ascent of the object. arrived at the free surface of the water, the mass fills up again with water, as soon as the conditioned air has been ejected, and the circuit begins again The efficiency can be improved in the following way: Arrived at the surface, a connection somebody, makes pass from the above object to be considered (object N l) towards an object N02 all the compressed air which it contains; a valve opens in the Roll'air conditioned object escapes from it (letting the pool water enter the said object) through a conduit which brings it into a second mass flooded at the bottom, as was the previous, in order to make this N02 object floating in turn and start an ascent whose work can be recovered as it was for the NGI object, and so on, each object alternately playing the role of compressed air cylinder so as to allow the other to become floating again and perform its ascent, therefore to produce energy. If the compressed air pressure should be insufficient, additional pressure could be provided by any additional system (pump, etc.). You can couple as many systems as you want. EMI28.2 This two mass system makes it possible to reduce the work to be developed by the compressor necessary to provide compressed air which will make floating the mass (object) flooded at the bottom of the tank, in order to make it rise. This increases the yield therefore the energy supplied and recoverable Several masses (objects) can be put in parallel or coupled and synchronized Any other system intended to make the mass of the bottom, floating, can be used (balloon, etc ... mass (object) can also descend, filled with water, or not in an overhead compartment, then pass into an intermediate compartment, alternately filled with air and then water, before entering the water basin or they will begin their lifts as a floating object. This intermediate compartment can also be emptied <Desc / Clms Page number 29> by compressed air according to the above reasoning, or more simply Any more favorable technique can be used to increase the efficiency of the EMI system29.1 1 4 One column system (diagram K) m = mass of the object (see next page) <Desc / Clms Page number 30> M = body of water. In this system, the mass is suspended at point A by a ratchet above the column filled with water. The column is emptied outside after opening a valve which is either mobile (V1 ') or fixed (V1) through which the water flows. This flow turns a turbine TU1, which will produce an energy E1 coming from the force F = at MgH developed by the fall of the volume of water whose level passes successively from points 1 to 2 to 3 etc ... with the height fall decreasing over time. The empty column, the ratchet releases the mass which goes to B and develops a force equal to F1 = m1 gH transmitted to a generator; similarly a turbine or better a rotary paddle (P) mounted on a bearing like the mass and equipped with floats F. located under its supporting structure descends at B, developing the same force F2 = m2gH m2 being the mass of the paddle or turbine system. M1 is retained at B by a ratchet. The water which has flowed from the column has been collected in a low height tank (B *), it is pumped back into the column, the energy (E1) produced by the flow of water in the first phase, will be reused completely to pump water back into another low-rise tank B 'closed by a valve V2. Indeed, the force produced by the flow of the mass of water located in 1, will be used to pump it back in 1 ', that located in 2 to pump the same in 2' and so on until X. The result is therefore almost zero. M1 remains in B attached to its pawl, on the other hand, as the column is filled, the water which flows is channeled on the paddle (or turbine) P which will develop an energy Ep, its rotation being transmitted by belt or chain to a generator, moreover, this paddle (or turbine) is placed on a float. The rising water level will lift everything up and develop a force according to the Archimedes Principle This movement transmitted by belt or other means to a generator will produce a force (Fp) transformed into energy: when the water level reaches point 0, the column is filled, the pawl B opens, releases the mass M1 with a density lower than that of the fluid. M1 goes back up and goes to catch at the end of the ratchet A which retains it. Developing a force (FM1) = (M-m1) gH recovered by transmission to a generator, then the movement begins again. To avoid the impact of the mass M and the paddle with the bottom of the column, either all the energy developed by their fall will have been transmitted, or the mass and the paddle may not arrive on a dry bottom, but penetrate into water maintained at an N1 level; in this case, the water flow will only be done up to this level in C. The results and principle remain the same, but on different heights. In conclusion, the force produced by the emptying of the column is reused to fill it then, but the following forces and energies are recovered: F1 + F2 + Ep + FP + FM1. Several columns will be coupled in parallel and synchronized so that the energy efficiency is maximum and smoothly. <Desc / Clms Page number 31> 50 System associating a mass and a turbine (palla) mounted on float (diagram N) EMI31.1 We consider a basin filled with water in which the mass evolves and a turbine "P" mounted on float, which receives the water intended to fill the basin which, in this case acts as Cl and C2. The turbine therefore rises as the basin is filled. This basin is emptied on a Tl turbine in a very long and shallow tank, in order to reduce the pumping height. The water flows to the upper part of the basin through another upper level basin, or through a traditional dam. m = mass of water in the basin Ml = mass of MI (the floating mass) M2 = mass of water displaced by Ml during its ascent into the basin M3 = mass of the float supporting the turbine + mass of the turbine M4 = mass d water displaced by M3 R = efficiency or 89% 1st phase: VI (valve letting the water flow from the basin to the flat pient tale) opens allowing the water to flow on the turbine T1, which causes a recoverable work and an energy equal to El, this energy is the same as that which would be produced by the flow of the same volume of water, directly by the dam which supplies the basin with water, divided by aewc er gale at E1 = R . m. g. H / 2 2nd phase: the basin is empty, the mass Ml, retained until then by a ratchet or any other system falls and develops an energy E2 which it transmits for recovery by any suitable system (belt, various transmission, etc. .) E2 = R. Ml. g. H 3rd phase: the float and the paddle "P" fall and develop an energy- EMI31.2 gie like Ml, so-E3 = R. M3. g. H 4th phase: the water flows from the upper basin, or from the dam, towards the basin, to do this, it flows on the floating turbine "P" and produces an energy E5 = m. g. H / 2. R 5th phase: pumping back the water contained in the flat basin under the basin vres the upper basin or dam, this consumes an energy E4 = m. g. H / R 6th phase: "p" and its float rises at the same time as the basin is filled, this produces energy by the fact that "P" receives the water flowing from the spu tank. or dam on the paddles of "P" which touch and transmit the energy produced which is equal to E6 = (M4-M3). g. H. R 7th phase: M1 is released by the ratchet (or any other system keeping it at the bottom of the water), it therefore rises to the surface and develops a recoverable energy equal to E7 = (M2-Ml). g. H. R <Desc / Clms Page number 32> The resulting force of the system will be Delta E: 1st hypothesis; with pumping of water from the flat basin to the upper basin which supplies the water to the central basin where Ml and "P" are located: Delta E = E1 + E2 + E3-E4 + E5 + E6 + E7 = 0.89M4 . g. H + 0.89. M2. G. H-0. 23. mgH Or, if M2 + M4 = 0. 5.m, delta E = 0.215. m. g. H 2nd hypothesis without pumping back, the water of the central basin flows quite simply as in a normal dam, if one uses, moreover, a dam as upper container supplier of the central basin, the water therefore only transit in the latter, in this case the energy E4 lost for the pumping no longer exists and must therefore no longer be supplied, Delta E therefore becomes equal to: El + E2 + E3 + E5 + E6 + E7 EITHER ultimately Delta E = R. g. H. (m + M2 + M4) SiM4 + M2 = 0.5. m, Delta E = 1.5. m Or 50% of yield in addition to a normal dam which is m. g. h. R In order to increase the value of M4 + M2 we can reduce M4 to the maximum in order to allow "P" to receive all of the water flowing from the upper basin over a maximum height, we can for example place several mass of type Ml which, they will continue to undergo the archimedes push as long as the water level rises even if the said masses have already arrived in the open air at the upper level of the water in the basin, ie its free level. In this case it is even possible to make M4 + M2 greater than 50% of m and thus increase the efficiency of the system, whether with, or without pumping back <Desc / Clms Page number 33> 4) Hermeticity of the intermediate and fluid compartments: The compartment C2, must, when the valve 2 is closed, be completely hermetic and retain the water or the chosen fluid so that the mass which is there situ may be subjected to Archimedes' push and rise towards the surface in its circulation gutters to point A. Likewise, when V2 is opened with V1 closed, the intermediate compartment becomes liquid and must be hermetic in order to '' keep the fluid coming from C2. It is therefore necessary for the mass to continue its journey without the fluid leaving the new compartment Ci + C2 created. The various possibilities envisaged will influence the type of valves at least their surfaces, their structure and their configuration. In all cases, unlike C1, Ci and C2 consist of complete walls closed in a box in which G1 and G2 are included and allowing only the moving valves to pass. Examples of solutions: (any solution already existing on the market can be used) a) The simplest is to seal the internal walls of the compartments from the level of valve 1, while allowing the movement of the masses on their bearing at balls R1 and R2 in the sheaths G1 and G2, The internal wall of G1 and G2 can be closed by valves cut in angle and retractable at the time of the passage of T1 and T2. These pieces can be completed by another smaller and hermetic one fixed on T1 and covering on the outside (outside always seen in relation to the center of the mass M) the space opened by T1 in G1, during its passage through the wall internal this part preventing the flow of water-Diagram A '. These retractable parts can be incorporated in the ducts G1 and G2 and carry the balls of the gutters. On passing R1, they will open just enough to let T1 and T2 or T3 T4 pass and then close (diagram C). b) A fixed gallery is created, external to G1 G2, extending their upper and lower walls as far as against the fixed frame; over their entire length in the intermediate compartment and the fluid compartment from V1. In this case, V1 and V2 extend to the outer edge of the outer wall of G1 and G2. (V. Diagram A and diagram D). If a transmission belt is used, it will be fixed on T3-T4 which will be steel strips (or other), the thinnest possible. In the compartment described above, which therefore extends outside the sheaths, from V1 to the top of C2, we hang in the fixed wall and the external wall of G1 and G2, at V1 and V2, two rollers extending into said walls by ball bearings allowing them to turn on themselves, letting the belt pass and ensuring the tightness of the new external compartment created. (diagram A and D - top view) c) In the same context of new external compartmentalisation, the transmission can be done by a link chain; in this case the surface <Desc / Clms Page number 34> of communication created by the passage of the chain between C1 and Ci and Ci and C2 at the level of the external compartment at G1 and G2 (and / or T3 and T4 cause the chain) is weaker and rendered hermetic by the small box stuffed with grease in which the chain passes between two gears: an upper, a lower. (Diagram D). In the case where the two masses are not directly connected together, there is no need for continuity of the belt or of the transmission chain between the three compartments, the problem of hermeticity no longer arises, since the valves V1 and V2 will suffice to ensure this at each passage of the masses in the compartments to be isolated independently of each other; no room should be simultaneously in both. 5) Examples of valve types: The valves should be made of as light a material as possible to reduce the work required for their mobilization. They can be activated electrically or mechanically. In the first case, an IR beam, cut by the passage of the mass at D where a switch connected to the pawl 1 will trigger the closing of V1 and the opening of V2. The passage of the mass after V2 will do the opposite. Closing of V2 + opening of V3 + V1 and emptying of the intermediate compartment. The principle remains the same with mechanical opening and closing. In particular for the N'l valve, it can be closed by force G., thanks to its own weight. For example, one can imagine a pulley on ratchet, winding a cable intended to raise the V1. At the time of the passage of the mass (M1 or M2), the end of the rod T1 or T4 releases the ratchet, or any other locking system releasing the pulley which, under the weight of V1, will turn and leave go down V1. If V1 is connected to V2 by two cables on a pulley, the V1 closure causes or facilitates the V2 opening. If we manage to seal the inner wall of G1 and G2 (V. before 4a) in Ci and C2, the valves will obstruct all the light going from the upper wall to the lower wall of the fixed frame, in the thickness of the internal walls of G & and G2 (diagram F for example). If, on the other hand, we cannot seal the internal wall of G1 and G2 over the entire height corresponding to Ci + C2 and we use solutions 4 b and c, the valves will occupy a lateral area ranging from outer edge of the outer wall of G1 to the outer edge of the outer wall of G2 in front of the hermeticity systems 4b or 4c. In this case, when they are removed, the valves will leave a void of beads in the upper and lower wall of G1 and G2. They will therefore be extended by rods supporting sections of ball sheaths (type G1-Gé) which will fit into the void to fill the absence of rolling allowing progression without friction or snag of R1 and R2 (see Diagram F ) One can also consider a rotary and alternative valve; two axes of rotation external to the fixed frame and located more or less on either side of point D, rotate a drum or half drum; a little like <Desc / Clms Page number 35> a paddle wheel or a washing machine drum; The wall of the drum is alternately full (valve) then empty so that the reciprocating or rotational movement imparted to the solid part, allows the latter to act as a closing valve when it is fitted between the walls of 'a compartment while the vacuum following it will act as an open valve. Thus, V2 (full part in place in C2) is closed. The drum turns, the solid part (currently V2) also turns; fit into C1 acting as closed V1, and leaving the empty part in its place, ie open V2. B. Other examples of construction with two independent masses. la) Example of embodiment especially envisaged in the case where it would be impossible to seal the ducts G1, G2) of circulation in the intermediate and fluid compartments because of the continuity of the belt between the two masses and through the three compartments; in this case, the transmission belt is not fixed on the outer support rod T3 and / or T4, but tensioned between the small transmission axes of the generators themselves. These axes may however not directly induce the production of electric current, but be free. In this EMI35.1 case, they will only be used to transmit the force produced by the movement of the masses to a central axis, the rotation of which will be directly inductive of electrical production. The belt or the transmission chain has an anchor point where a hook will be hooked Included in the external rods T3 T4 (or any other attachment or drive system) For example, (See Diagram A 3), retractable hooks: (clothespin type) At point A, the hook secures the transmission belt thanks to the anchoring ring provided for this purpose on its upper face and causes its movement. Arrived at the level of valve 1, an angled stopper opens the clamp, therefore lifts the retractable hooking lug inserted in T3 and T4 and releases the belt which circulates outside the intermediate and fluid compartments (diagram H), around of its own axes 1,2, 3 4. Passed this course, the attachment system, under the action of a pressure exerted by a compressed return spring during the previous phase or any other pressure / counter system pressure, resumes its place to again secure the belt located in the Ci around the axes 5,6, 7,8 and independent of the previous belt, at least inside Ci. The axes 5,6, 7,8 of the intermediate compartment will be driven by the movement of this belt Arriving at valve 2, same release operation with angle stopper, then past this valve, the hook resumes its stowage of the belt thus driving the axes 9,10, 11,12 following the same principle as before. Arrived at the point corresponding to the axis 10 new stopper so that the hook is again tied to the transmission circuit of the axes 1,2, 3,4. Belt axes and circuits can be made interdependent <Desc / Clms Page number 36> thanks to a possible coupling by an entirely external belt connecting for example two axes, the 1 and the 9. Consequently, when M1 unhooks the belt at the level of valve 1, M2 takes over when to the movement imposed on axes 1,2, 3,4. In the case considered above, three separate and independent transmission zones are therefore created, each corresponding to a compartment C1, Ci, or C2, thus avoiding the problems of hermetic insulation of the compartments Ci and C2, since each compartment has its own transmission system without any passage from one to the other affecting its tightness by letting pass the fluid intended to allow the application of the Archimedes Principle, therefore to do reassemble the mass concerned towards point A. b) In the case of the two independent balls with belt not crossing the three compartments. Another yet simpler system is possible. (Diagram i) The transmission system can be eliminated in one or two compartments. Indeed, one can realize according to diagram H, a simplified system where only the axes 1,2, 3,4 and 9,10, 11, 12 would be connected by transmission belt leaving the path of the masses M 1 and M2 in the completely free intermediate compartment. Even simpler, we could even use only the force G. To produce electrical energy, thanks to the rotation of the axes 1,2, 3,4 The Archimedes Principle and its thrust only serving to bring back the mass at point A. In this case (see diagram i), mass M1 hooks the belt at point A. Throughout its course in C1, M1 will therefore drive the transmission belt and produce energy. M1 arrived at C, M2 is at A, at axis 4, that is before V1, M1 releases the belt and enters Ci then C2; M2 has already taken over the transmission relay, is between axes 1 and 2, therefore transmits the force of its movement in order to produce electricity, and so on ... C. Another example of realization with Ci embedded in permanence (diagram J) In this case, we make the following prototype: C 1 remains an aerial compartment where the mass will undergo the force of gravity F = MGH, on the other hand, the intermediate compartment Ci is already filled with liquid. This compartment is limited by two hermetic valves V1 and V2 located at the same level with the ground so that according to the principle of communicating vessels, the level of the liquid is the same in the portions of the left and right circulation columns corresponding to the intermediate compartment. . When V2 is closed, it thus retains the volume of liquid located above it in the right circulation column, which corresponds to compartment C2. <Desc / Clms Page number 37> The intermediate compartment is therefore completely submerged between V1 and V2. To do this, we close V1, we fill Ci + C2 to the upper level required to re-engage the movement of the mass M1 in the air compartment Cl (ie point A); then we close V2. We can then open V1 without the liquid level exceeding the level located on the same horizontal as V2 in the left circulation column (corresponding to C1) since the levels of V1 and V2 are identical. The liquid will therefore remain in balance between these two limits even if V1 is open. The mass M1 released from point A will undergo the force G and travel the path of length and height a + b, that is H1 to point B. V1 being open, it will penetrate into the liquid contained in Ci and continue its course on a depth equivalent to H2 + H3 to be calculated and dependent on H1, on the weight of M1, and on the residual force (after transmission to the generator) of the mass M1 after its fall in C1. In passing, this mass mounted on ball bearings, will meet at point C a pawl where any other referral system (eg railroad tracks, etc.) allowing its passage down but preventing it from resuming path C of the intermediate compartment when it undergoes Archimedes' push, and obliging it to follow path d in Ci towards V2 and C2. After having traversed Cl, the mass enters Ci where it displaces a volume of liquid equal to its which will overflow above the level of V1, in Cl and will be collected in a tank (B *), V2 being at this moment closed. M1 will continue its race up to the Lower limit H3 before climbing under the action of Archimedes' push which will return it on the path d of compartment Ci towards V2 and C2 since the ratchet or any other referral system will prevent its race to path c; V1 closes, V2 opens and M1 begins its ascent to A. V2 will not close until after the passage of M1 beyond point D, the water level in the intermediate compartment will find a new balance between closed V2 and V1 open. The two valves can also form only one prefabricated so that V2 closed, V1 is open and vice versa if however such a structure does not increase the handling, the closing time and the consumption of energy required for the operation. M1 arrived in A, it resumes its course in Cl, the communicating vessel (VC) having filled C2 with the volume of liquid necessary to bring M1 back to this position (volume corresponding to the volume of M1) In A, M1 will again undergo G thanks to the slope a and, if necessary, to a small impulse provided by a piston P. Along its course, the mass, as in the previous examples, is connected to straps or to any other transmission system allowing the transfer of the force deployed to electric generators. The advantages of this model compared to the previous ones are: <Desc / Clms Page number 38> 10 It avoids the problems of resistance of materials inherent in the impact of the mass and its ball bearings, at the end of stroke C1, with the angle of the gutter to access Ci Indeed, in this case, M1 continues its path perpendicular to the ground, without any change of direction, and in a less brutal liquid medium until the lower limit of H3. There is therefore no longer any impact between the bearings (R1 R2) made of solid materials and the angle of the gutter giving access to Ci also constructed of hard and resistant materials in the other models. 20 The path traveled by the mass, therefore the work provided and transformable into electrical energy is done over a longer path which EMI38.1 is equivalent to: (H1 + H2 + H3) X 2 when the force necessary to re-pump the volume of water lost in the BAC and equal to the volume of the mass, towards VC and in order to fill C2 will only be that necessary to bring the equivalent in volume of water of M1 to a height equal to H1. 30 Two valves are sufficient. 4 another possibility can also be envisaged for re-inserting into the liquid compartments the volume of water corresponding to the volume of M1, and expelled when the mass enters the liquid intermediate compartment: a hydraulic piston can be placed below the level of V1 or V2 and connected to the intermediate compartment. (Or any other more favorable place) This piston will push the volume of liquid collected in the BAC, towards Ci. A complete study of the pressures to be overcome during the performance of this operation will allow to check if the force necessary to carry it out is equal, greater or less than that necessary to re-pump the same volume of water over a height H1 to point A. Likewise, the position and the most advantageous possible connection of the piston will also be determined. Another remark: In this example, M1 should have a shape that minimizes its resistance to water penetration and therefore the impact shock it will undergo at this time. D. ONE-COLUMN SYSTEM In the most profitable one-column system, several columns will be synchronized on the same generators so that they do not stop producing electricity and do not work in spurts. E. MISCELLANEOUS COUPLINGS Whatever the system (s) used, we can couple them in parallel, or better yet, arrange them in cascades so that during the passage of M1 in the Ci of the first module at the head of the cascade, the water evacuated from the latter comes to compensate for the same volume of water to be replaced in the C2 of the underlying module following the loss of water undergone in the Ci of the latter after the same passage of the mass corresponding to its unit of work. This loss of water will itself replace the necessary volume <Desc / Clms Page number 39> to bring the liquid level to C2 of the module itself underlying the previous one to the correct height. And so on, up to the top floor where the water evacuated from the Ci is no longer recovered. In this way, only the water lost by Ci from the first element of the cascade must be re-pumped over a height H2 or H2 '(depending on the model) while 5 or X systems will operate at full efficiency without losing the force of re -pumping of the water evacuated by Ci, since this is replaced in the C2 of the lower modules by the water evacuated from Ci of the directly upper module. Only the loss of additional forces necessary for handling the valves should be taken into account, whereas (for example, consider six stages in cascade), the gain will be five times the weight of the volume of liquid displaced multiplied by H2 or H2 ' . Profitability must therefore be multiplied (which is particularly advantageous in the context of operation in a vacuum), but nevertheless, calculated very precisely. F. RESIDUAL FORCE CALCULATION For the two types of realization that seem the most profitable at the end of the electric producer If m = the mass, solid, M the weight of the volume of water corresponding to the volume of the mass.  1. Ci is drowned permanently (diagram J).  System with external water supply filling C2.  F resid. = MG (H1 + H2 + H3) + f '+ Mg (H2 + H3) -mg (H1 + H2 + H3) -mg (H1).  For example, the F res developed by the fall of the same equivalent of water as that supplied to the system but in the case of a free fall of a dam over a height H2 '=> or F res. = flight weight. of water = on flight M1 X H2 ', i.e. for the system an additional residual force = (M-m) g (H2 + H3) 2. One column system (diagram K) Total forces developed by the system. m = mass M1 m1 = mass of the paddle or turbine on float.  M = M of the water displaced or used in each phase.  F = Mg (H1, H2, ... Hx) + mgH + m1 gH-Mg (Hx .. H3, H2, H1) + Mg (H, H1, ... Hx) + m1gH + M1gH. or F = mgH + m1 gH + Mg (H, H, Hx) + m1 gH + MgH (weight of the volume of water displaced during the ascent of the mass in the water column.)