• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The dynamic pressure generator is a device that transforms a vertical weight (8) into pressure on a fluid contained between a static part or reservoir (1) and another mobile or cover (2), the contact between the two being a surface of revolution around of an axis (6). The fluid enters pressure through a system that transmits the weight exclusively to the fluid by means of lateral compressors (3). The fluid is housed in chambers (4) in which the cover (2) is divided. The cover (2) is divided by vertical ribs (5) against which the lateral compressor (3) slides without transmitting weight to the mobile cover (2). The pressure of the liquid is compensated in the vertical with the static tank (1) and the counterweight system (9), while in the horizontal the cover can rotate around the axis (6) and by decompensation of the forces on the nerves (5), which are arranged as vertical radii, a decompensated force is caused on them, which causes them angular velocity, generating a torque on the axis (6) of rotation. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2742883A1
    申请号:ES201830834
    申请日:2018-08-17
    公开日:2020-02-17
    发明作者:Merida Zacarías Calvo
    申请人:Calvo Merida Zacarias;
    IPC主号:
    专利说明:

    [0001]
    [0002]
    [0003]
    [0004] SECTOR OF THE TECHNIQUE
    [0005]
    [0006] The dynamic pressure generator is a device that belongs to all renewable energies. Therefore, it does not pollute the environment with gas emissions or consume limited resources as fuel. The system takes advantage of the pressure to which a fluid contained between a fixed part and a moving part is subjected, and which by design of the Generator provides this with an angular velocity that creates a motor torque on the shaft.
    [0007]
    [0008] BACKGROUND OF THE INVENTION
    [0009]
    [0010] The generation of a motor torque on a shaft by the movement of a liquid, has been traditionally achieved through hydraulic turbines. These are divided into action turbines, in which the speed of the fluid is used to achieve the movement of the propeller, and the reaction turbines that take advantage of the pressure difference in the blades to achieve the movement. But all of them use the potential difference for the realization of the movement. Recently, the gravitational engine, as an invention, generates movement with O-ring semi-pistons that generate movement inside an O-ring, thus presenting together in the direction of advance, which results in greater pressure losses due to fluid loss.
    [0011]
    [0012] The Dynamic Pressure Generator comes to solve the problems presented by the aforementioned devices, since it does not make a potential difference and does not present seals in the direction of advance of the angular movement. This expands the number of cycles you can perform without having to restart the system. As it is a single moving part that drags the rest of the solidarity systems with it, the generated engine torque is substantially increased and therefore increasing productivity.
    [0013]
    [0014] With respect to previous inventions, it presents a remarkable constructive facility, which makes it viable at the time of its industrial production, avoiding constructive joints that would cause significant productive losses, and that due to expansion in materials avoid considerable savings in execution and pressure losses.
    [0015]
    [0016] The hydraulic jack is another predecessor invention, which uses the same physical principles as the Dynamic Pressure Generator, since it introduces a force into a liquid-filled conduit that transforms into pressure and this force that enters the device in one direction, exits in another direction different from the initial one according to a surface placed at the other end of the device generating a movement by difference of the mobilized surfaces and therefore of the force applied and the resulting one, being the same principle of the law of Pascal the one that is applied within of the sealed chambers of the generator, for the production of movement.
    [0017]
    [0018] For the generation of the movement in a stable way, the device as an innovation is kept horizontally avoiding excessive friction, due to the counterweights that rest on the mobile cover to keep it in a flat motion. Avoiding excessive friction and unnecessary clearances due to the continuous effect of pressure. The different weights and counterweights that can be used to generate different pressure states and to balance the increases and differences in the speed and work of the roof with its mobile elements.
    [0019]
    [0020] EXPLANATION OF THE INVENTION
    [0021]
    [0022] The Dynamic Pressure Generator produces a torque on an axis, by subjecting a liquid, to pressure. The liquid transforms a vertical and constant force such as the weight caused by the gravitational field, into a horizontal force through a pressurized system. The pressure generated in the liquid is transmitted in all directions of the contour of the chamber that contains it, however the static deposit prevents most movements in certain directions of space especially in the vertical and down, thus collecting part of the force caused by pressure. However, the mobile cover allows the rotation around the main axis of the liquid contained in the chamber and the cover to which it moves in its movement. This means that the pressure exerted by the weight causes an angular movement of the moving part and therefore an angular velocity around an axis of the weight transmitting system, without generating potential difference.
    [0023]
    [0024] The Generator has a mechanism for loading and unloading the weight on the weight transmitting support. This mechanism allows you to control the amount of weight that It really exerts pressure on the device, with which the speed and the generated torque can be regulated. The weight that is really deposited on the transmitter support is what generates a vertical force on the lateral compressors. The weight transmitting support and the lateral compressors must be integral with each other in such a way that when moving the lateral compressors drag the weight transmission support with them and therefore the union of said parts must have the structural resistance to allow said joint movement . The side compressor is a piece that fits in the static tank, in the intake slots of the compressor vertically. These grooves are vertical and fit perfectly to the compressor, this is completed with sealing gaskets that prevent the loss of liquid at that point. The compressor can therefore slide vertically into the slots of the mobile cover in such a way that the weight of this at no time rests on the cover. If not only and exclusively on the liquid to which the pressure caused by the force of gravity is transmitted.
    [0025]
    [0026] The adjustment between the mobile part or cover and the static part or tank is a surface of revolution around the axis of rotation, which implies that the cover can rotate freely inside the tank without anything preventing it, while maintaining the liquid tightly between the tank and the cover thanks to the gaskets between the cover and the tank. There are sealed compartments or chambers between the cover and the tank, which are filled with an incompressible fluid and it is on this liquid that the lateral compressor rests completely. Transmitting the weight to the fluid exclusively. The system has three parts that move independently within each other. A static tank, a mobile cover and a liquid compression system.
    [0027]
    [0028] The waterproof cameras are compartments between the mobile part and the static part of the device. They are sealed compartments filled with liquid that can enter pressure under the effect of lateral compressors. Its contact surface between the mobile cover and the static tank is a surface of revolution that allows the movement around the axis of revolution 360 degrees sexagesimal and only and exclusively in this way. Since in the watertight chambers, movements of the moving part are not allowed in any other direction than that of rotation around the axis. The cameras are also defined by nerves belonging to the mobile part of the device and that divide the volume by way of spokes on a wheel. The nerves are vertical and radial according to the axis of rotation and one of the faces is in total contact with the liquid, while on the opposite side there is contact with the lateral compressor so that there is no contact with the liquid on that surface. The compressor being in intimate contact in its face opposite to the rotation and the nerve, so that the fluid cannot penetrate or exert pressure between these two components. The face of the compressor in contact with the liquid in the forward direction rests exclusively on the liquid, the bottom face from the groove is inclined towards the rib against which it slides vertically. This face of the compressor in contact with the liquid decreases its thickness until it reaches the nerve without ever resting on the static lower reservoir or the nerve, only on the liquid. This inclination must have a geometric component in the horizontal direction of advance, that is to say radial in the direction of rotation, so that if in the chamber we evaluate the pressure on the different faces of the nerve we have that on the face in contact with the compressor The nerve does not receive as much pressure from the liquid as on the free face, that is, the opposite of the friction of the compressor, where the nerve is in contact with the fluid completely. Therefore there is a greater pressure on the nerve face of the cover in said direction of rotation.
    [0029]
    [0030] The fluid is under pressure inside the chamber, which is a space between a moving part and a fixed part. According to Pascal's law, the pressure is distributed equally according to all the faces of the space it occupies and always perpendicular to the outer contour. By having an object inside this chamber that introduces pressure due to the vertical weight it supports, the face of this object or lateral compressor will exert pressure on the incoming liquid or pressure, while the rest of the faces will have an outgoing pressure or in the direction expansive of the liquid, that is to say of the liquid on the walls. As the contact face between the compressor and the vertical and fluid-free nerve does not transmit pressure from the liquid, only the other side of the compressor generates incoming pressure on the fluid and with a horizontal component according to the geometry of the solid but which in the Liquid is perpendicular to it.
    [0031]
    [0032] If we decompose the pressure by senses. According to the lower face, the tank itself compensates for the vertical force as it is a static piece and its outer contour is also counteracted by the tank itself. The upward movement of the roof is counteracted by the system of counterweights that prevent displacement by keeping it horizontal. Due to its geometry, the mobile cover can only make a movement that is not impeded by the static deposit or the counterweights and is to rotate on its axis of revolution of contact with the cover. Without unloading weight on the compressors and by way of checking that the system It works, if we apply a horizontal force on the cover in the direction of rotation, it would rotate on its own axis, so having this horizontal force generated by the weight, the mobile system rotates with respect to the static.
    [0033]
    [0034] If we evaluate the system of forces in the walls on which the liquid exerts pressure. In each sealed chamber that is filled with fluid and on the same faces of the nerves with the same direction of rotation there will be a greater pressure than on the face opposite to the rotation. The evaluation of the forces exerted by the pressure on a nerve, explains why the cover rotates. The nerve is radial to the axis of rotation and on one of the faces or face opposite to the advance, the compressor slides vertically, since the face of the nerve is vertical. On the entire contact surface therefore no pressure will be exerted on the nerve by the liquid, in fact it is an incoming pressure in the fluid on which the lateral compressor rests. However, on the opposite side the entire surface is in contact with the liquid. The applied force F on that face can be defined as F = P * S, with P being the pressure and S the surface. Therefore, the force on the contact face with the compressor Fc and the Force on the free face will be Fi and will meet the inequality Fc <Fl, since the pressure is equal but the surfaces on which the pressure is exerted are less the contact face than in the free face of the nerve.
    [0035]
    [0036] If the Bernoulli equation is applied to the fluid contained in a chamber as the fluid is incompressible and under pressure without potential difference, we will have the end of the potential difference disappear from the equation to be zero while the pressure in the direction of rotation happens to provide a speed to the liquid since it is the only thing that can counteract the pressure in the direction of rotation, if the friction losses are taken into account we find that the pressure in the nerves in the direction of rotation is transformed into speed of the fluid, and rotation of the mobile cover that drags along. As Bernoulli's equation is:
    [0037]
    [0038]
    [0039]
    [0040]
    [0041] The terms being:
    [0042] V = Speed
    [0043] P = Pressure
    [0044] Z = height (potential difference).
    [0045] hf = Friction losses.
    [0046] 7 = Specific weight
    [0047] g = acceleration of gravity
    [0048] W = external work that is extracted to the fluid.
    [0049]
    [0050] If for an initial pressure P1 decompensated on both sides of a nerve we have Z 1 = Z2 and V1 = 0. To obtain a compensated pressure P2 the fluid would have to develop a V2, compensate for friction losses and could generate a job whenever the Initial pressure was enough. The situation being similar to Bernoulli's narrowing in a tube, where greater speed is achieved at lower pressure for the same liquid stream as long as the contour is narrowed.
    [0051]
    [0052] The pressure of the fluid in the static part and its adhesion to it causes the reaction by the tank necessary for the movement according to Newton's third law. The liquid, unlike a solid, deforms on advancing and for that reason and because the adhesion generates a boundary layer in the contact between the reservoir and the liquid, it causes a movement of the pseudo-elliptical particles in the chamber. and that therefore pushes the cover. The device complies with the principle of conservation of energy, which says that in an isolated system the energy is neither created nor destroyed, only transformed, and complies with it because the system is not isolated, if it is continuously and permanently receiving a weight on the device that is transformed into pressure, and this pressure in turn does not decrease when taking speed if it is continually fed by the weight, which allows it to rotate while the pressure contribution persists.
    [0053]
    [0054] The device is not a perpetual or continuous movement, but the pressure and friction losses cause it to degrade the characteristics of the system, and therefore the tightness and pressure inside the chambers. Therefore, after a certain period of work, the system must be reassembled with the same work characteristics in order for it to work again. The sum of the cameras around the axis generates a total force that is transformed into the angular speed of rotation.
    [0055]
    [0056] The weight does not make a potential difference due to the incompressibility of the liquid but having allowed the rotation around the axis of the mobile cover acquires angular velocity around the axis of rotation and that angular velocity is what generates the torque.
    [0057] The mobile cover when dividing into sectors prevents the loss of fluid in the displacement since the differential losses of fluid will pass to the adjacent chambers and so on. Unlike the rotation caused in isolated chambers where any loss of fluid does not remain in the pressurized system.
    [0058]
    [0059] For the maintenance of the mobile system in the horizontal and allowing the rotation around the axis the system has a static tank that receives the fluid pressure down and in the centrifugal direction. It is verified that the cover receives forces according to the directions of rotation that are allowed and that it is that of the rotation of the cover around the axis and according to the vertical and upwards, for which the generator needs a system of counterweights that rest directly on the cover to counteract this vertical force and keep the rotation in the horizontal and reducing the bending and cutting moments that deform the system.
    [0060] BRIEF DESCRIPTION OF THE DRAWINGS
    [0061]
    [0062] To complement the description that is being made, and in order to help a better understanding of the characteristics of the invention, a set of drawings is attached as an integral part of said description, where, for illustrative and non-limiting purposes, represented the following:
    [0063]
    [0064] Figure 1.- Shows a front view of the dynamic pressure generator.
    [0065] Figure 2.- Shows a side view of the dynamic pressure generator.
    [0066] Figure 3.- Top view of the dynamic pressure generator.
    [0067] Figure 4.- Bottom view of the dynamic pressure generator.
    [0068] Figure 5.- Isometric view of the dynamic pressure generator.
    [0069] Figure 6.- Front view of the exploded dynamic pressure generator.
    [0070] Figure 7.- Isometric view of the exploded dynamic pressure generator.
    [0071] Figure 8.- Bottom view of the cover with the support ring.
    [0072] Figure 9.- Isometric view of the compressor, its gaskets, the weight support and the weight.
    [0073] Figure 10.- Isometric view of the counterweight system.
    [0074] Figure 11.- Front section view of the roof and tank.
    [0075] Figure 12.- Isometric view of the fluid compression system and counterweights system.
    [0076] Figure 13.- View of the front section of the compression and counterweights system.
    [0077] Figure 14.- Isometric view of the Generator with disassembled parts.
    [0078] Figure 15.-Isometric view of the Generator section.
    [0079]
    [0080] PREFERRED EMBODIMENT OF THE INVENTION
    [0081]
    [0082] In its preferred embodiment, the dynamic pressure generator will be made with a tank (1) whose inner face is straight and flat, and its inner side faces are cylindrical. Only a top ring or support ring (17) that embraces the cover will be removable, so these surfaces must be flat, favoring their constructive simplicity. The mobile cover (2), will keep its inner part cylindrical solid, in the part that coincides with the axis (6) being this axis (6) prolonged from the contact with the tank (2) to its outer exit, with the element of attachable rotation above the counterweight (9). The watertight chambers (4) will be recesses in the roof itself (2) separated from each other by the ribs (5) and in its outer part it will be solid because it will have a cylindrical mass (7) in the outermost contact according to the radius with the tank (1), in such a way that contact is generated in the horizontal parts with the tank (1), both in its upper and lower part, as well as in the outer part. On the outer part (7) of the mobile cover (2) there will be the upper ring (17) of the tank (1) which is removable and will coincide in its geometry with the solid one (7) of the cover (2). For the retention of the cover (2) in the horizontal plane.
    [0083]
    [0084] The filling ducts (10) of the chambers (4) are holes that are in the solid part (7) of the cover (2) to introduce liquid into the chambers without dismantling the system and will be covered with threaded screw (23) specific to maintain the tightness, on which the support ring (17) will exert a clamping force since it is on the closing screw (23) of the filling duct. The sealing system will be made internally with a gasket (12) of the fluid with the exterior that will be made inside embedded in the cover itself (2), executed with adaptive rubber in the form of a ring and housed in the cover itself (2). The sealing system of the fluid with the outside will be carried out in the solid part of the cover (2), executed with adaptable rubber, in the horizontal part of the massif. A rubber gasket will be placed on the flat bottom (12) of the massif of the cover as a belt alternating the metal and rubber contact, and a flat gasket between the cover and the ring (11) will also be placed with hoop shape, just under the ring (17) cover holder.
    [0085] In the cover (2) the groove (16) is executed in the form of a circular sector, leaving the inner faces of the groove (16) in contact with the compressor (3) vertically. The compressor (3) is a moving part that fits the groove (16) of the cover (2), in its lower part the piece narrows as it falls, so that each point coincides with the radius of the cylinder that It adjusts to the development of the axis of rotation. This decreasing section goes from zero to its lowest point, growing to its widest point where it coincides with the width of the groove (16) in plan. Upon reaching that height the width of the groove (16) is maintained throughout its thickness. In this thickness we find a band corresponding to the rubber seal (15). Separate two bands of the compressor metal itself (3).
    [0086]
    [0087] The width of the compressor (3) will extend until the support of the counterweight (30) is saved, above this height it joins forming a single piece with the weight support (13), this support (13) will be a plate with the part upper flat except for the notches of coupling of the weights (26). The weights (8) have coupling projections (28) in their lower part that fit in their upper part with the coupling notches (26), these will be longitudinal in the direction of the development cylinder radii around the axis (6) . The shape of the weight support (8) will be as a washer with the flat top except for the coupling notches (26) of the weights with each other.
    [0088]
    [0089] The counterweight system (9) rests directly on the cover (2) avoiding the groove area (16) and the rib of the cover (5), therefore its lower part or support of the counterweight (30) is the which rests flat with the cover. These feet or supports (30) are attached to the shaft (21) which has an annular shape and is internal to the support of the weight (13) and the weight (8) itself, without causing friction, until it saves them and joins to the counterweight support (14). The shaft of the counterweight (21) is hollow and the shaft (6) of the cover (2) moves through it. The axis (6) of the cover (2) is integral to it, vertical and crosses the weight (8), its support system (13), as well as the counterweight (9), without touching any of them.
    [0090]
    [0091] The weights (8) are placed on the support (13) by an external hydraulic loading and unloading mechanism. Weights (8) that do not rest directly on the support (13) remain high without transmitting the weight (8) to the compressor (3) held by guides for weight (18), keeping them in their position of not exercising pressure on the liquid When a weight is released, an external loading and unloading system helps you get down to your work position where you rest on the lower weights you are working on
    [0092]
    [0093]
    [0094] on the weight support (13), at that point the weights are coupled to each other by means of the coupling notches (26) of the weight that are radial cavities of the weights which, being flat cylindrical in shape, need these coupling notches (26 ) to lean on each other. By having in its lower part some highlights (28) in the direction of the radius of the axis that fit the upper notches (26) of the others, prevent the displacement of some weights (8) on the others with the movement. Having several attachable weights (8) causes the system to work in various pressure states.
    [0095]
    [0096] The weights (8) have their hollow interior due to their annular shape since the shaft of the counterweight (21) and the axle (6) of the cover (2) are through them. The weights (8) that do not exert pressure on the fluid have to be supported by an external system that is formed by a foot (20) that gives support to some pillars (24) that join together and on which some are mounted guides (19) that hold the weight (8) transmitting it as pressure to the support pillars (24). This structure retains the weight until each of the through washers are released on the lateral compressor (3).
    [0097]
    [0098] The counterweight (9) consists of similar support and load mechanism similar to weight (8). The counterweight (9) is held in its fastening guides (19) while not necessary, transmitting its weight to the support pillars of the counterweight (25). These pillars (25) are in this arrangement on the pillars of the weight (24) and rest on them. The system, when needed, can release the weight support guides (19) that drop the weight rings (9) onto the system. These hoop-shaped weights (9) are flat and cylindrical with an annular shape, allowing the shaft to pass through its interior without opposition. The counterweight (9) consists of notches and attachable projections to prevent sliding of the counterweights (9) from each other.
    权利要求:
    Claims (14)
    [1]
    1. Device that converts a vertical weight, in pressure, to a liquid contained in a sealed form between a fixed part or static tank (1) and a mobile part or mobile cover (2). The pressure is transmitted to the system by means of the lateral compressor (3) that enters each one of the sealed chambers (4) filled with liquid in which the space of 360 degrees sexagesimal revolution is divided around the axis (6) filled by the pressurized liquid The coupling between the static tank (1) and the mobile cover (2) is a surface of complete revolution around the main axis (6), the chambers (4) are hollow spaces that occupy all the hollow space between the cover (2) ) and the tank and delimit them in the vertical ribs of the cover (5) that are vertical and that separate the chambers (4) from the cover with each other. And against which the lateral compressor (3) slides vertically on its face opposite to the direction of travel, so that the lateral compressor rests solely and exclusively on the liquid under pressure (7) transmitting to this all the weight it receives by means of an inclined surface of revolution, which is zero width at its lower point and the width of the groove (16) at the top of the chamber (4) generating a decompensated pressure on the nerve face of the cover (2) contrary to the advance of the mobile cover (2). The decompensated pressure generates an angular movement of the mobile cover assembly (2), lateral compressor (3), weights (8), counterweights (8) and the main shaft. Thus generating a torque on the main shaft (6).
    [2]
    2. Device according to claim 1 formed by the static part of the generator or static tank (1) that is part together with the mobile cover (2) of the envelope of the sealed chambers (4) where the liquid in pressure is located. The liquid transmits its pressure to the tank and since this is a static component in its contact with the tank, it gives rise to the reaction that promotes the movement of the liquid in the chamber. The part in contact with the cover is a surface of revolution around the main axis (6), which allows the fixed part and the movable part to rotate 360 degrees sexagesimal, keeping the chambers (4) tight and the fluid under pressure . The static deposit (1) prevents the movement of the mobile cover in the undesired directions, mainly downwards and containing centrifugal pressure forces.
    [3]
    3. Device according to claim 1 formed by the movable part that moves on the fixed part or reservoir (1) by the pressure decompensated horizontally on the ribs of the cover (5) in the direction of rotation around the axis. The nerves receive a force from the liquid on one of the faces in the direction of advancement. While on the opposite side to the advance this force does not exist and therefore the sum of forces on the nerve walls (5) results in a net force decompensated in the direction of angular advance that rotates the cover. The mobile cover (2) is the part in contact with the static tank (1). The weight transmitter support (14) is supported on it to compensate for the vertical force caused by the pressure in the sealed chambers (4) upwards, keeping the cover horizontal.
    [4]
    4. Device according to claim 1 composed of counterweights (9), weight transmitter support (14), weight shaft (21) and support on the cover (30), which exert a vertical and downward force due to the support of the counterweights (9). This force is discharged on the mobile cover to counteract the vertical and upward force caused by the pressure in the sealed chambers (4) of the liquid, thus avoiding excessive friction and keeping the mobile system horizontal, thus facilitating the rotation of the cover (2) around the axis (6).
    [5]
    5. Device according to claim 1 formed by a liquid compression system inside the sealed chamber (4). In which the generation of pressure in the liquid will be carried out by the side compressor (3) that rests solely and exclusively on the liquid. In turn, on this rests the weight (8) that according to the needs of the rotation is deposited on the weight transmitter support (13) and this in turn, rests on the lateral compressor (3). This system of pieces is integral with each other and rests on each other respectively and when turning the cover (2) around the axis (6), the system also rotates with it, since it drags it in its turn without any impediment.
    one
    [6]
    6. Device according to claim 5 characterized by the transmission of pressure to the liquid by the lateral compressor (3). It transmits the support of the vertical weight (8) on the liquid, according to the surface of contact with the liquid, and this is inclined in such a way that the component resulting from the pressure transmitted to the liquid, compresses the liquid in the direction of advance of the moving part The part opposite the advance of the compressor (3) is straight and vertical equal to the face of the nerve (5) against which it slides vertically and in total contact not transmitting pressure to the liquid through the vertical face. Therefore, in the area of the nerve (5) in contact with the lateral compressor (3), there is no force acting on that face of the nerve (5) perpendicular to the faces since the liquid does not enter that point. While on the opposite side of the nerve (5) there is a force caused by the pressure of the liquid in the direction of advance, since both sides of the nerve (5) are equal on the surface, the force in the direction of rotation is clearly superior.
    [7]
    7. Device according to claim 5 wherein the lateral compressor (3) enters through the mobile cover (2) without any obstacle, through the intake slots (16) of the cover (2) to press on the fluid, such that the sealing gaskets of the compressor (15) prevent the pressurized fluid inside the sealed chambers from escaping outwards. The intake groove (16) and the part of the side compressor (3) where the seal of the compressor (15) is housed therefore have the same geometry in plan and fit one inside the other perfectly.
    [8]
    8. Device according to claim 1 formed by main shaft (6) integral with the mobile cover, and which serves as the axis of revolution in turn. The shaft (6) serves to transmit the rotation generated in the mobile part, causing a torque and the rotation of any device that is coupled to it. In its turning movement, no part that prevents its movement is interposed, to transmit as much torque as possible.
    [9]
    9. Device according to claim 1 comprising a mechanism for controlling, loading and unloading the weight (8) on the weight support (13). Where it is transmitted to the lateral compressor (3) through the slots (16) of the cover (2) and from there to the liquid.
    [10]
    10. Device according to claim 1 comprising a mechanism for controlling, loading and unloading the counterweight (9) on the device, through the counterweight transmitter support (14), the shaft (21) and the counterweight support (30). On the mobile cover, keeping is horizontal and avoiding excessive friction in the movement.
    [11]
    11. Device according to claim 1 formed by filling duct (10) of the fluid in the sealed chamber (4). For liquid filling with the minimum disassembly of parts, and with the least amount of liquid leaks.
    [12]
    12. Device according to claim 1 formed by seals (12) between the mobile part or cover (2) and the static part or reservoir, thus preventing the liquid contained between these two parts from losing pressure and therefore can be generate the movement of the roof (2).
    [13]
    13. Device according to claim 1 formed by gaskets (15) between the cover (2) and the side compressor (3), preventing the pressurized liquid inside the sealed chamber (4) from escaping between the cover and the system weight transmitter (8) abroad.
    [14]
    14. Device according to claim 4 wherein the support of the counterweights (30) on the cover (2) rests on the areas between the slots of the cover (16) where the lateral compressor (3) is adjusted in such a way that the support is made on the part of the cover (2) where the liquid of the chambers (4) exerts a vertical and upward force.
    one
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    PE20191440A1|2019-10-15|SYSTEM FOR THE GENERATION OF ENERGY THROUGH A BELT TURBINE FOR ROCKY SURFACE RIVERS
    MD20150061A2|2017-01-31|Engine for generating kinetic energy |
    同族专利:
    公开号 | 公开日
    ES2742883B2|2020-06-17|
    EP3839254A1|2021-06-23|
    WO2020035631A1|2020-02-20|
    BR112021002914A2|2021-06-15|
    CN112840123A|2021-05-25|
    AU2019321057A1|2021-03-18|
    CA3109749A1|2020-02-20|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP2002039052A|2000-07-22|2002-02-06|Imai Sekkei|Motor|
    JP2011085131A|2010-04-06|2011-04-28|Shigeru Ijima|Method for rotating rotor using weight|
    EP2767707A1|2013-02-18|2014-08-20|Brain Energy, S.L.|Power generating device and method based on gravitational energy|
    WO2017072555A1|2015-10-28|2017-05-04|Mainsel João Gaspar|Method for generating electrical energy through the fall of a weight upon a hydraulic fluid|
    ES2635613A1|2016-10-28|2017-10-04|Zacarias CALVO MERIDA|Gravitational engine |
    法律状态:
    2020-02-17| BA2A| Patent application published|Ref document number: 2742883 Country of ref document: ES Kind code of ref document: A1 Effective date: 20200217 |
    2020-06-17| FG2A| Definitive protection|Ref document number: 2742883 Country of ref document: ES Kind code of ref document: B2 Effective date: 20200617 |
    优先权:
    申请号 | 申请日 | 专利标题
    ES201830834A|ES2742883B2|2018-08-17|2018-08-17|Dynamic pressure generator|ES201830834A| ES2742883B2|2018-08-17|2018-08-17|Dynamic pressure generator|
    PCT/ES2019/070568| WO2020035631A1|2018-08-17|2019-08-16|Pressure-based dynamic generator|
    CN201980067779.XA| CN112840123A|2018-08-17|2019-08-16|Pressure-based dynamic generator|
    EP19849319.9A| EP3839254A1|2018-08-17|2019-08-16|Pressure-based dynamic generator|
    AU2019321057A| AU2019321057A1|2018-08-17|2019-08-16|Pressure-based dynamic generator|
    CA3109749A| CA3109749A1|2018-08-17|2019-08-16|Dynamic pressure generator|
    BR112021002914-1A| BR112021002914A2|2018-08-17|2019-08-16|dynamic pressure generator.|
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