ES2957635A1 - Water collection system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

System for water collection. It comprises an artificial tree (1) formed by a trunk and a crown, and a control module (2) that is configured to collect the water captured by the artificial tree (1) and to enhance the collection of water through the artificial tree. (1). The trunk of the artificial tree (1) comprises at least two tubes: an outer one (9) and an inner one (10) that is located inside the outer tube (9); where between the two tubes (9, 10) there is a coaxial space (11) filled with an absorbent material (15) to capture water in liquid and gaseous states. The crown of the artificial tree (1) comprises a set of leaves (7) and tubular branch structures (6) that converge at an upper part of the inner tube (10). The water captured by the artificial tree (1) flows downwards until it reaches the control module (2). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Water collection system

Object of the invention

The present invention refers to a system for water collection that comprises an artificial tree and a control module configured to accumulate the water captured by the artificial tree and to enhance water collection. The system of the invention achieves notable advantages in relation to other water collection systems known until now; where these advantages are achieved thanks to a simplification of the system of the invention, thus obtaining a greater production of water obtained from the humidity of the air, and a use of the water obtained from the frost and dew that permeate the entire artificial tree. .

Technical problem to be solved and background of the invention

Currently, different ways of obtaining water by mechanical, electrical or filter means are known; so that in all cases these systems are inefficient, obtaining very little water; also highlighting that they have a high cost.

Other methods of obtaining water are also known, such as reverse osmosis; where this method has considerable energy expenditure.

Description of the invention

In order to achieve the objectives and avoid the drawbacks mentioned in the previous sections, the invention proposes a system for collecting water that comprises an artificial tree formed by a trunk and a crown, and a control module that is configured to collect the water captured by the artificial tree and to enhance the water capture through the artificial tree.

The trunk of the artificial tree comprises at least two tubes: an outer one and an inner one that is located inside the outer tube; where between the two tubes there is a coaxial space filled with an absorbent material to capture water in liquid and gaseous states.

The crown of the artificial tree comprises a set of leaves and tubular branch structures that converge at an upper part of the inner tube of the trunk of the artificial tree; where the internal spaces of the tubular branch structures communicate with the internal space of the inner tube.

The tubular branch structures include holes that communicate with the interior space of said tubular branch structures, while the inner tube includes microperforations that communicate the coaxial space with the internal space of the inner tube. These micro-perforations are configured so that the water contained in the absorbent material passes into the internal space of the inner tube.

With this described arrangement, the water captured by the artificial tree, either in the form of dew, water vapor or frost, runs downwards, inside and outside through the tubular branch structures, through the inside and outside of the inner tube, and through of the absorbent material that occupies the coaxial space of the trunk of the artificial tree.

The control module comprises at least one refrigeration device configured to collect the water captured by the artificial tree through a first tubular conduit; where said refrigeration device includes an air extractor that generates a suction effect inside the trunk and also inside the tubular branch structures of the artificial tree; where the internal spaces of the tubular branch structures communicate with the internal space of the inner tube. The outer tube of the trunk of the artificial tree includes in its side wall a first opening in which a filter is attached that is configured to collect water from the air in a gaseous state due to the suction effect of the refrigeration device; where the filter communicates with the refrigeration device through a second tubular duct.

The inner tube of the artificial tree includes an upper end section projecting above an upper end of the outer tube; where the tubular branch structures converge in said upper extreme section.

The system of the invention includes a tank into which the water collected by the artificial tree drains; where said tank is located below the refrigeration device.

The system of the invention includes at least one solar panel attached to the tubular branch structures of the artificial tree; where said solar panel is configured to provide electrical energy to the control module through wiring that runs inside the coaxial space of the trunk of the artificial tree.

In one embodiment of the invention, the absorbent material is composed of sodium silicate, potassium silicate and polyacrylate.

The absorbent material with the composition described in the preceding paragraph has a percentage by weight of sodium silicate between 1.2% and 70%, potassium silicate in a percentage between 1.5% and 65% by weight. weight, and polyacrylate in a percentage between 1.4% and 55% by weight.

The system of the invention includes thermo-electric plates located within the coaxial space and more specifically they are fixed on the inner face of the outer tube of the artificial tree; where said thermo-electric plates comprise two opposing metal sheets of different materials; and where the thermo-electric plates are configured so that when an electric current is passed through them, the metal sheet that is in contact with the outer tube is at a higher temperature than the other even metal sheet that has a temperature below 0°C; thus achieving a greater degree of water condensation within the trunk of the artificial tree.

Each of the thermo-electric plates is fixed to the outer tube of the artificial tree by means of an extension embedded in a perforation of the side wall of said outer tube, so that said extension includes extreme fins that protrude outside to dissipate heat. Below, to facilitate a better understanding of this descriptive report and forming an integral part thereof, a series of figures are attached in which the object of the invention has been represented, with an illustrative and non-limiting nature.

Brief description of the figures

Figure 1.-Shows an elevation view of the system for collecting water, object of the invention. It basically comprises an artificial tree and a control module configured to enhance the collection of water through the artificial tree.

Figure 2.-Shows a profile view of the system of the invention for water collection.

Figure 3.-Represents a view of an upper part of the artificial tree; where the junction or confluence of the branches to the trunk of the artificial tree is essentially shown.

Figure 4.-Represents a section view according to section A-B of figure 3.

Description of an example of embodiment of the invention

Considering the numbering adopted in the figures, the system for collecting water comprises an artificial tree 1 and a control module 2 that is configured to be able to store the water captured by the artificial tree 1, and to increase the volume of the collection of the water; where the control module 2 is located inside a house 3; and where the artificial tree 1 is fixed to the ground by means of an anchor structure 4 embedded in a concrete block 5.

The artificial tree 1 comprises a trunk and a crown formed by several structures of tubular branches 6 and a multitude of leaves 7, so that in said structures of tubular branches 6 they are fixed to at least one solar panel 8 of high energy efficiency for general electrical energy and thus be able to supply said electrical energy to the different devices incorporated in the control module 2.

Each of the tubular branch structures 6 comprises a main branch and other secondary branches; where each main branch is attached to the trunk of artificial tree 1.

The trunk comprises an outer tube 9 of circular section and an inner tube 10 of circular section arranged coaxially with respect to the outer tube 9. Inside the inner tube 10 the main branches of the various tubular branch structures 6 flow; where in an embodiment of the invention, said mouth is located in an upper end section 10a of the inner tube 10 that protrudes with respect to an upper end of the outer tube 9 of the trunk of the artificial tree 1.

A lower part of the outer tube 9 of the trunk of the artificial tree 1 has a first opening and a second opening, both of which communicate with a coaxial space 11 delimited between the outer tube 9 and the inner tube 10; where a filter 12 for air inlet is attached to the first opening, and a registration door 13 is anchored to the second opening.

A wiring 14 runs inside the coaxial space 11 to power the different devices incorporated in the control module 2, at the same time that said wiring 14 connects with the solar panel 8, which is the element that provides the necessary electrical energy to the different devices of the control module 2. Said wiring 14 is protected within a tubular conduit.

The coaxial space 11 of the trunk of the artificial tree 1 is filled with an absorbent material 15 with a capillary structure to be able to more easily absorb water in gaseous form found in the humidity of the air, at the same time as said absorbent material 15 It can also collect the water that is on the outer surface of the tubular branch structures 6 and that runs down the slope until it reaches the outer surface of the upper end section 10a of the inner tube 10 of the trunk of the artificial tree 1.

On the other hand, water in gaseous form found in the air is also collected through holes 16 located in the tubular branch structures 6, whose main branches flow into the upper end section 10a of the inner tube 10 of the trunk. of artificial tree 1.

The water in gaseous form, frost and dew accumulated in the crown (tubular branch structures 6 and set of leaves 7) of the artificial tree 1 can also be collected through the holes 16 of the tubular branch structures 6 and by the absorbent material 15 that occupies the coaxial space 11 of the trunk of the artificial tree 1.

The tubular branch structures 6 comprise the main branches and the secondary branches that are embedded within some extreme sections of the main branches, so that at least in the areas of confluence of one branch and the other the holes 16 are located through which water passes into the interior of said tubular branch structures 6. Said holes 16 can also be located at the confluence of the tubular branch structures 6 and the inner tube 10 of the trunk of the artificial tree 1.

The holes 16 could also be located in all parts of the tubular branch structures 6, and not only at the confluence of the main and secondary branches.

On the other hand, preferably the leaves 7 are attached to some of the secondary branches furthest from the crown of the artificial tree 1, while said leaves 7 comprise a rough structure, even the leaves 7 can be made with an absorbent compound; all this to achieve greater water capture.

The water accumulated in the absorbent material 15 of the trunk of the artificial tree passes into the inner tube 10 through micro-perforations 23 located on the side wall of said inner tube 10.

The control module 2 comprises a refrigeration device 17 that collects the water accumulated inside the inner tube 10 of the artificial tree 1 through a first tubular duct 18, and also collects the water that enters a gaseous state through the filter 12 fixed to the tube. exterior 9, through a second tubular conduit 19; where in both cases the refrigeration device 17 drains the collected water to a tank 20 located below the refrigeration device 17.

The refrigeration device 17 includes among its elements a condenser 17a, a precipitator 17b to drain the water into the tank 20, and an extractor 17c to extract the hot air from the condenser 17a; where said extractor 17c generates a suction effect inside the trunk of the artificial tree 1, thus achieving greater effectiveness and greater performance in the collection and production of water.

The control module 2 also includes a battery 21 to accumulate electrical energy that can be used at night so that the system of the invention can continue to function, so that said battery 21 is obviously charged during the day with the solar panel 8 fixed. to the tubular branch structures 6 of the artificial tree 1.

As shown in Figure 1, the water collected in tank 20 can be used to irrigate a crop, without ruling out other uses.

The inner tube 10 and the tubular branch structures 6 can be made of a metallic material, such as aluminum, to achieve faster and more effective condensation of water, without ruling out other materials; while the outer tube 9 of the artificial tree 1 is preferably made of a polyester fiber material simulating the bark of a natural tree, without also ruling out other materials.

On the other hand, on the inner face of the outer tube 9 of the artificial tree 1, thermo-electric plates 22 (plates with a Peltier effect) can be fixed, which comprise two opposing metal sheets of different materials, so that when a electric current through said thermo-electric plates, the metal sheet that is in contact with the outer tube 9 is at a higher temperature than the other even metal sheet that has a temperature below 0°C. In this way, a faster and more effective condensation of the water fluid is achieved within the trunk of the artificial tree 1.

The Peltier effect consists of when a current is passed through a circuit composed of different materials whose joints are at the same temperature, an effect is produced in which heat is absorbed in one joint and released in the other.

Each of the thermo-electric plates 22 is fixed to the outer tube 9 of the artificial tree 1 by means of an extension 22a embedded in a perforation of the side wall of said outer tube 9, so that said extension includes end fins 22b that protrude from the outside to dissipate heat.

Although the inner tube 10 is metallic and the outer tube 9 is made of polyester fiber, it is also possible to manufacture both with flexible PVC material along its entire length, where the smaller diameter inner tube 10 includes the micro-perforations 23 in its entire length.

The artificial tree 1 is capable of producing and generating a considerable volume of water compared to other conventional water collection systems. Furthermore, the system of the invention is based on the absorption of water, an operation in which the refrigeration device 17 helps, which generates a suction effect, both inside the inner tube 10 and in the coaxial space 11 occupied by the material. absorbent 15; all of this as mentioned above.

It should be noted that in a preferred embodiment of the invention, an absorbent composition 15 formed by several products has been provided, such as: sodium silicate, potassium silicate and polyacrylate; where these products have the function of absorbing water, dew, frost and humidity from the air.

The percentages of said products are the following: a percentage by weight of sodium silicate between 1.2% and 70%, potassium silicate in a percentage between 1.5% and 65% by weight, polyacrylate in a percentage between 1.4% and 55% by weight; where these products are highly water absorbent.

The trunk of the artificial tree 1 along its entire length has means for suctioning hot air from the outside materialized by the extractor 17c that is part of the refrigeration device 17; where said aspiration means generate the capillary suction effect throughout the entire extension of the trunk and the tubular branch structures 6 of the artificial tree 1.

The artificial tree 1 can have solar collection cells on a flexible support.

Claims (10)

1. System for water collection, characterized by: - comprises an artificial tree (1) formed by a trunk and a crown, and a control module (2) that is configured to collect the water captured by the artificial tree (1) and to enhance the collection of water through the tree artificial (1); - the trunk of the artificial tree (1) comprises at least two tubes: an outer one (9) and an inner one (10) that is located inside the outer tube (9); where between the two tubes (9, 10) there is a coaxial space (11) filled with an absorbent material (15) configured to capture water in liquid and gaseous states; - the crown of the artificial tree (1) comprises a set of leaves (7) and tubular branch structures (6) that converge in an upper part of the inner tube (10) of the trunk of the artificial tree (1); where the internal spaces of the tubular branch structures (6) communicate with the internal space of the inner tube (10); - the tubular branch structures (6) include holes (16) that communicate with the interior space of said tubular branch structures (6), while the inner tube (10) includes micro-perforations (23) that communicate the coaxial space (11) with the internal space of the inner tube (10); where the water captured by the artificial tree (1) runs downwards, inside and outside through the tubular branch structures (6), through the inside and outside of the inner tube (10), and through the absorbent material (15) that it occupies. the coaxial space (11) of the trunk of the artificial tree (1). 2. System for collecting water, according to claim 1, characterized in that the control module (2) comprises at least one refrigeration device (17) configured to collect the water captured by the artificial tree (1) through a first tubular duct (18); where said refrigeration device (17) includes an air extractor (17c) that generates a suction effect inside the trunk and also inside the tubular structures (6) of the artificial tree (1). 3. System for collecting water, according to claim 2, characterized in that the outer tube (9) of the trunk of the artificial tree (1) includes in its side wall a first opening in which a filter (12) is attached that It is configured to collect water from the air in a gaseous state due to the suction effect of the refrigeration device (17); where the filter (12) communicates with the refrigeration device (17) through a second tubular duct (19). 4. System for collecting water, according to any one of the preceding claims, characterized in that the inner tube (10) of the artificial tree (1) includes an upper end section (10a) that protrudes above an upper end of the tube. outer (9); where the tubular branch structures converge in said upper end section (10a). 5. System for collecting water, according to any one of the preceding claims, characterized in that it includes a tank (20) into which the water collected by the artificial tree (1) drains. 6. System for collecting water, according to any one of the preceding claims, characterized in that it includes at least one solar panel (8) fixed to the tubular branch structures (6) of the artificial tree (1); where said solar panel 8 is configured to provide electrical energy to the control module (2) through wiring (14) that runs inside the coaxial space (11) of the trunk of the artificial tree (1). 7. System for capturing water, according to any one of the preceding claims, characterized in that the absorbent material (15) is composed of sodium silicate, potassium silicate and polyacrylate. 8. System for capturing water, according to claim 7, characterized in that the absorbent material (15) has a percentage by weight of sodium silicate between 1.2% and 70%, potassium silicate in a percentage between 1.5% and 65% by weight, polyacrylate in a percentage between 1.4% and 55% by weight. 9. System for collecting water, according to any one of the preceding claims, characterized in that it includes thermo-electric plates (22) fixed on the inner face of the outer tube (9) of the artificial tree 1; where said thermo-electric plates (22) comprise two opposing metal sheets of different materials; and where the thermo-electric plates (22) are configured so that when an electric current is passed through them, the sheet that is in contact with the outer tube (9) is at a higher temperature than the other sheet. even metallic having a temperature below 0°C; thus achieving a greater degree of water condensation within the trunk of the artificial tree (1). 10. System for collecting water, according to claim 9, characterized in that each of the thermo-electric plates (22) is fixed to the outer tube (9) of the artificial tree (1) by means of an extension (22a) embedded in a perforation in the side wall of said outer tube (9), so that said extension includes end fins (22b) that protrude outside to dissipate heat.