ES2962184A1 - GRAVITY ENERGY STORAGE AND GENERATION SYSTEM IN DIFFERENT FLUIDS (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Gravity energy storage and generation system in different fluids. Constituted from an environment composed of three bodies with three different densities: medium A (1), for ascent; medium B (2), for descent; and element C, load (3) that ascends and descends; with a relationship between their different densities such that: d A > d c > d B , where fluid A (1) can be water belonging to an artificial water storage in the form of a hydraulic dam with a height h; medium B (2) can be the air itself in the atmosphere; and element C (3) will be a drum full of oil whose density is between that of water and air, and said cylindrical drum has a morphology that allows it to move vertically through medium A (1) and take advantage of the potential energy gravitational energy that it acquires when rising in the form of kinetic energy when descending through medium B (2). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

GRAVITY ENERGY STORAGE AND GENERATION SYSTEM IN

DIFFERENT FLUIDS

OBJECT OF THE INVENTION

The present invention refers to a system for storing gravitational potential energy, and its subsequent transformation into kinetic energy to produce electrical energy, which presents important technical advantages over other similar systems, and also refers to the procedure and the different phases to achieve it.

It proposes an improvement in the optimization of energy and resource use when lifting a load to store its gravitational potential energy.

Starting from the base gravity storage model, where the premises are:

- Need to store energy.

- Store said energy as gravitational power energy.

- Raise a load to a certain height.

- To produce energy, let said load descend and take advantage of its kinetic energy.

Therefore, the present invention proposes a procedure to raise the load, from a series of different fluids with specific relative density conditions between them, which minimizes to the maximum the resources and energy used to raise said load.

Therefore, the proposed system has advantages in that it is capable of producing clean energy without the need to consume energy from external sources.

The industrial application of this invention is found within systems for the use and storage of clean energy, and more specifically, systems for the storage and generation of energy by gravity in different fluids.

BACKGROUND OF THE INVENTION

Although no invention identical to the one described has been found, we present below the documents found that reflect the state of the art related to it.

Thus document MXMX/A/2007/007292 refers to a system for generating electricity that includes an operable pump to convert the wave movement derived from a body of water into mechanical energy. The pump includes an inlet body through which an operating fluid can enter the pump and an outlet port through which the operating fluid can exit the pump. A first outlet line and a second outlet line are fluidly coupled to the outlet port of the pump. A first reservoir is fluidly connected to the first outlet line, and a second reservoir is fluidly connected to the second outlet line, both reservoirs being selectively capable of receiving operating fluid conducted through the outlet port.

ES2365074 proposes a renewable energy source for the production of mechanical or electrical energy, which comprises a conduit, submerged in a fluid or water, whose exit section is at the level of the water surface, and the entrance at a lower level. Which includes a system that introduces a fluid or air inside the duct. Ascending a flow, due to the push of Archimedes, whose energy we take advantage of through a turbine and an electric generator. The flow of water that comes out of the section is directed to the water area outside the conduit to repeat the cycle. It may include a structure of air ducts, with a fixed or adjustable intake, to produce a depression at the outlet by taking advantage of the speed of mobile phones or the wind. Sources with a fluid and thermal exchange.

MXPA/A/2001/009085 describes a system for generating energy from the difference in osmotic potential between a source of water of relatively low salinity and a source of water of relatively high salinity, the system is characterized in that it comprises: a first tube having one end connected to a water source of relatively low salinity; a second tube having an inlet and an outlet, both disposed within and in fluid communication with the relatively high salinity water source; the other end of the first tube is arranged inside the second tube at a lower point of the outlet, allowing the water from the first tube to mix with the water from the second tube, causing a rise in the water level inside the second tube; a turbine unit arranged to convert the kinetic energy of the water moving in the second tube into mechanical and/or electrical energy.

ES8202892 refers to the use of wave energy using displacements caused in a float. Various mechanisms are described that take advantage of the movement of the float in one direction that prevent the effect achieved from being canceled when the float moves in the opposite direction. These mechanisms consist mainly of maintaining the displacement of the float in a vertical direction and of valves or ratchets that prevent the action from canceling out the reaction. The valves are used to raise seawater through pipes and the ratchets are used to rotate the shafts in one direction.

ES8300950 describes a procedure and apparatus for raising water in order to generate energy. The process consists of creating an environment made up of air and water droplets, in which drag forces act on the droplets, lifting them from a lower level to a higher one, and collecting said droplets at the upper level. The device consists of a lifting tower that has an open upper end and a duct-shaped lower end for the vertical movement of the air mass; a device to inject hot water droplets into the bottom of the tower, mixing with the air mass; and a turbine device that responds to the movement of air in the tower, generating energy.

Conclusions: As can be seen from the research carried out, none of the documents found solve the problems raised as the proposed invention does.

DESCRIPTION OF THE INVENTION

The system for storing and generating energy by gravity in different fluids that is the object of the present invention is constituted from the principle of thrust in fluids of different densities, where a body ascends or descends depending on whether the density is lower or higher than that of the body. fluid, respectively.

For this, three bodies with three different densities are presented:

- Fluid A, for ascent.

- Fluid B, for descent.

- Element C, load that ascends and descends.

And the relationship between their different densities is the following:

dA > de > dB

In this way, when you want to store gravitational power energy of element C, it is introduced into fluid A, and the difference in densities will cause element C to rise.

Once it has reached the highest point within A, it is retained and stored in fluid B, until the moment when its potential energy is required to be used to generate electrical energy, where it is released and will descend by the same principle of fluid difference. , this time the densities are inverted. Once element C is at the lower point of fluid B, where it coincides with the lower point of fluid A, the cycle can be repeated as many times as desired.

On the other hand, it is important to emphasize that in the complete cycle of injecting energy and extracting it from the system, energy is lost, and 100% efficiency cannot be produced; whether they are losses due to friction, due to causes peripheral to the system, or due to the energy that must be used in the transfer of element C between fluids A and B.

However, the energy loss is much less than when carried out in conventional gravity energy storage systems, where the lifting and lowering of the load is always carried out under the same environment.

The choice of bodies A, B and C will depend on the use that the installation is going to have, since the theoretical relationship between them must be simple, but their practical choice must take into account different factors, such as:

- Installation size. Each material can have its advantages and disadvantages depending on the scale at which the solution is implemented, since the cost of the material itself or its good properties for its purpose can be magnified or reduced if we talk about m3 mm3, etc.

- Phase change energy. The choice of materials directly influences the energy necessary to make the change from one environment to another of element C.

- Generation method. This entire process focuses on being able to generate electricity when element C decreases, so the choice of materials and scale of the project will directly depend on which performance in this generation is better, taking all factors into account. We can talk about encapsulations that allow a physical grip for production by traction in the descent to a pulley, or by generation of the descending element (with electromagnetic couplings) explaining a winding in its descent, etc.

- In the event that speed control must be carried out in the lifting system so that it is not a free ascent determined only by buoyancy, the possibility of energy extraction is offered by slowing down the ascent.

- The bodies defined as A, B and C can belong to different states of matter, given that the difference in density is the key to realizing the system. The materials and their state of aggregation will be selected based on their characteristics for optimal system performance.

Unless otherwise indicated, all technical and scientific elements used herein have the meaning normally understood by a person skilled in the art to which this invention belongs. Procedures and materials similar or equivalent to those described herein may be used in the practice of the present invention.

Throughout the description and claims the word "comprises" and its variants are not intended to exclude other technical characteristics, additives, components or steps. For those skilled in the art, other objects, advantages and characteristics of the invention will emerge in part of the description and part of the practice of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present description, some drawings are attached that represent a non-limiting preferred embodiment of the present invention:

Figure 1: Schematic view of a model of gravity energy storage and generation system in different fluids object of the present invention.

Figure 2: Schematic view of the main moments within the gravity energy storage and generation cycle in different fluids object of the present invention.

The numerical references that appear in said figures correspond to the following constituent elements of the invention: 1234567

1. Fluid/medium A (water)

2. Fluid/medium B (air)

3. Loading (oil drum)

4. Flood subsystem

5. Extraction subsystem

6. Storage subsystem

7. Electricity generation subsystem

DESCRIPTION OF A PREFERRED EMBODIMENT

A preferred embodiment of the gravity energy storage and generation system in different fluids object of the present invention, with reference to the numerical references, can be based on an environment composed of three bodies with three different densities:

- Fluid/medium A (1), for ascent.

- Fluid/medium B (2), for descent.

- Element C, load (3) that ascends and descends.

And the relationship between their different densities is the following:

dA > de > dB

Where fluid A (1) will be water belonging to an artificial water storage in the form of a hydraulic dam with a height h; medium B (2) will be the atmosphere's own air; and element C (3) will be a drum full of oil whose density is between that of water and air. Said cylindrical drum has a morphology that allows it to move vertically through medium A (1) and allows it to interact with the other elements of the system described below:

- Flood subsystem (4). Which allows the drum to be introduced through the lower part of medium A (1).

- Extraction subsystem (5). Which allows the drum to be removed from the upper part of environment A (1) to transfer it to environment B (2).

- Storage subsystem (6). Which allows storing drums of element C (3) in the upper part of the system, to be used when required in the energy generation process on its descent.

- Electricity generation subsystem (7). Which allows electricity to be generated in the descent of element C (3) when descending through medium B (2).

The flooding subsystem (4) is made up of a chamber located at the lower point of the hydraulic dam, and includes two gates: one for the access of the drum of element C (3) from the middle B (2) and emptying of the camera; and another, upper one, for filling and flooding the chamber, through which the drum of element C (3) exits to the surface of medium A (1).

The extraction subsystem (5) is made up of a crane structure that collects the drum of element C (3) from the surface of medium A (1) and takes it to the storage subsystem (6) where it will wait until it is required to generate energy. .

At the time of generating energy, the same extraction subsystem (5) collects the

drum of element C (3) in question, and the same cable that supports it is coiled in the

shaft of an electric generator, which, when released, drops the load, unwinding the cable

and turning the generator, producing electrical energy, which can be stored or derived to a network.

The number of drums of element C (3) may be greater than one, being stored

as many as you want or several of them being in different phases of the system cycle.

In a different embodiment, and given that the storage of the drums on the surface

can be quite limited, the intention is to use the volume of the dam itself as storage. To do this, there is an anchoring system at different depth levels of the dam, where the drums can be anchored. In this way, the drum

remains at a certain depth waiting to be necessary, when it will be released and due to buoyancy

It will rise to the surface, where it can be used with its gravitational potential.

Following said scheme, an example of a procedure to carry out the storage and/or generation of electrical energy from the described system would consist of the following stages or phases:

i.- The flooding subsystem chamber (4) is empty of fluid A (1).

ii. - The drum of element C (3) is introduced into said chamber.

iii. - The flooding subsystem chamber (4) is filled with fluid A (1).

iv. - The drum of element C (3) rises through medium A (1) to its surface.

v. The extraction subsystem (5) collects it and takes it to the storage subsystem (6), waiting to be used to generate electricity.

saw. - The generation of electrical energy is required, and the extraction subsystem picks up the drum of element C (3) from the storage subsystem (6) and drops it through

medium B (2), generating electricity from the generator installed in the crane structure of the extraction system (5).

vii.- The drum of element C (3) is at the lowest point of the system, ready to start the cycle again from the initial stage i, where the chamber of the flooding subsystem (4) has been previously emptied.

Claims (4)

1. - Energy storage and generation system by gravity in different fluids, consisting of an environment composed of three bodies with three different densities: - Fluid/medium A (1), for ascent. - Fluid/medium B (2), for descent. - Element C, load (3) that ascends and descends. characterized because the relationship between its different densities is the following: d<A>> d<e>> d<B> Where element C (3) has a morphology that allows it to move vertically through medium A (1) and allows it to interact with the other elements that the system also includes, these being: - Flood subsystem (4). Which allows the drum to be introduced through the lower part of medium A (1), and is composed of a chamber located at the lower point of medium A (1) and includes two gates: one for access to element C (3) from the medium B (2) and emptying the chamber; and another, upper one, for filling and flooding the chamber, through which element C (3) exits to the surface of medium A (1). - Extraction subsystem (5). Which allows the drum to be removed from the upper part of environment A (1) to transfer it to environment B (2), and includes a crane structure that picks up element C (3) from the surface of environment A (1) and takes it to a storage subsystem (6) where it will wait until it is required to generate energy. - Storage subsystem (6). That allows element C (3) to be stored at the top of the system, to be used when required in the energy generation process on its way down. - Electricity generation subsystem (7). Which allows electricity to be generated in the descent of element C (3) when descending through medium B (2), where the same extraction subsystem (5) collects element C (3), and the same cable that supports it is coiled in the shaft of an electric generator, which, when released, drops the load, unwinding the cable and making the generator rotate, producing electrical energy, which can be stored or derived to a network. 2. - Energy storage and generation system by gravity in different fluids, according to claim 1, where the number of elements C (3) is greater than one, storing as many as desired or several of them being found in different phases of the energy cycle. system. 3. - Gravity energy storage and generation system in different fluids, according to claims 1 and 2, where an anchoring system is available at different depth levels of the dam, where the drums can be anchored. 4. - Procedure for storing and generating energy by gravity in different fluids from the previously claimed system, characterized by being developed in the following technical stages: Yo. - The flooding subsystem chamber (4) is empty of fluid A (1). ii. - Element C (3) is introduced into said chamber. iii. - The flooding subsystem chamber (4) is filled with fluid A (1). iv. - Element C (3) rises through medium A (1) to its surface. v. - The extraction subsystem (5) collects it and takes it to the storage subsystem (6), waiting to be used to generate electricity. saw. - The generation of electrical energy is required, and the extraction subsystem collects element C (3) from the storage subsystem (6) and drops it through medium B (2), generating electricity from the generator installed in the crane structure of the extraction system (5). vii. - Element C (3) is located at the lowest point of the system, ready to start the cycle again from the initial stage i, where the flooding subsystem chamber (4) has been previously emptied.