ES1243820U - System for obtaining water and vegetation in arid or desert areas (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

System for obtaining water and vegetation in arid or desert areas, using condensation of atmospheric water vapor, which consists of covering the ground with one or more sail surfaces or sheets, which are placed semi-overlapping, overlapping or with openings longitudinal, so that they allow the passage or fall of condensed dew and frost, and prevent the passage of solar radiation, adding a complementary condensation system. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

System for obtaining water and vegetation in arid or desert areas.

Field of the Invention

In systems for obtaining water and vegetation.

State of the art

There are systems for obtaining water from fog or the atmosphere, generally in high areas, which are expensive, limited or impractical. This system uses the high cold that occurs in desert areas at night and with it the condensation of atmospheric water vapor, dew or frost. Temperatures usually range from 10 ° C to about -5 ° C, but dew drops and frost occur at higher altitudes, so even at positive temperatures frost falls and settles on the ground. The system is also very useful in low and flat areas.

Description of the Invention

Object of the invention and advantages

Provide a simple, economic, large surface area and useful system for obtaining water from the air. By condensing atmospheric water vapor.

Add a complementary system that uses the evaporation of sea water.

Avoid evaporation of the water obtained and accumulated.

Use automatic aeration or ventilation systems and rejection of solar radiation. Retraction or tilt also protects in the event of sandstorms.

Recover large desert areas.

Produce a greater quantity of plant products and thereby avoid animal sacrifice.

Vegetation production facilitates, creates and maintains humid areas, increases rainfall and prevents climate change.

Problem to solve

The desertification of the planet and the lack of green areas.

The system for obtaining water and vegetation in arid or desert areas of the invention, using the condensation of atmospheric water vapor, consists of covering the ground with one or more sail surfaces or sheets, the sail surfaces are placed semi-overlapping, overlapping or with longitudinal openings, so that they allow the passage or fall of dew and frost and prevent the passage of solar radiation. To avoid its loss by evaporation. Condensed water is repelled and deposited on the ground or collected in channels, pipes or deposits on the ground or underground, for later use.

The sail surfaces are supported by their corners and edges with cables supported in turn by posts. They can be tilted manually or automatically depending on of the direction and intensity of the wind, the time of day and the intensity and incidence of the sun, if it is daytime. The latter is done using a winch or pulley, a motor and a microprocessor that processes the applied data.

In a variant, the sail surfaces have longitudinal openings that allow unloading. Another variant presents the sail surfaces in the form of a broken line section, with an opening in the lower area so that it also allows the passage and descent of the condensed water. All sail surfaces can have an edge on the ground or run at a certain height, a few meters above the ground.

Stainless steel is used for cables and posts and for sail surfaces, sheets, fabrics and meshes, polypropylene or polyethylene with or without graphene mixtures, and synthetic fibers in general.

The sail surfaces will have a light color to reflect the solar rays. And the meshes can have alternating channels with ribs or protruding points.

The meshes are generally somewhat bushy. In general, sail surfaces are opaque to light and light tones to produce the reflection of solar radiation.

A complementary condensation system can be added, evaporating the sea water, and also using sail surfaces and posts.

Operation: During the night the cold causes the dew or frost to be deposited on the sail surfaces, where once condensed it is collected and stored or applied to the vegetation. During the day the sail surfaces prevent the sun from evaporating the condensed water, making it easier for it to accumulate and increase on successive days.

Brief description of the drawings

Figure 1 shows a schematic and perspective view of a group of sail surfaces, sheets or meshes of the invention.

Figure 2 shows a schematic and perspective view of a group variant of sail surfaces, sheets or meshes.

Figure 3 shows a schematic and perspective view of a variant of a group of sail surfaces, sheets or meshes.

Figure 4 shows a schematic and perspective view of a group variant of sail surfaces, sheets or meshes.

Figures 5 and 6 show schematic and perspective views of variants of sail surfaces, sheets or meshes with longitudinal slits or openings.

Figure 7 shows a schematic and partially sectioned view of a long length complementary condenser, using the evaporation of sea water.

Figure 8 shows a schematic and elevational view of a group of sail surfaces arranged parallel to each other and with a slight inclination with respect to the vertical.

Figure 9 shows a schematic and elevation view of a sail, sheet or mesh surface arranged as a broken line section.

Figure 10 shows a schematic and plan view of portions of sail surfaces with different types of relief on their surfaces.

Figure 11 shows a schematic and plan view of mesh portions with different types of meshes.

Figure 12 shows a block diagram with a possible form of operation.

More detailed description of an embodiment

Figure 1 shows an embodiment of the system of the invention, with the overlapping and inclined sail surfaces, sheets or meshes (1), with some cables (2) in their contour and other support cables (20) of the corners of the sails and supported in turn by the posts (3) and tiltable by the cables (2a) and some winches (5) powered by electric motors or actuators and controlled by a microprocessor. The lower cable (20) runs at ground level. The posts (3) rotate through the ball joints (4). The sun indicates its relative position and the arrow indicates the direction of the wind. The inclination of the sails will depend on the intensity and direction of the wind and the time or position of the sun.

Figure 2 shows the overlapping and inclined sail surfaces (1), with some cables (2) in their outline and other support cables (20) from the corners of the sails and supported by the posts (3) and tiltable by means of the cables (2a) and some lathes (5) powered by electric motors and controlled by a microprocessor. Both cables (20) and therefore the sail surfaces run high. The posts rotate through the ball joints (4). The sun indicates its relative position and the arrow indicates the direction of the wind. The inclination of the sails will depend on the intensity and direction of the wind and the time or position of the sun.

Figure 3 shows the overlapping and inclined sail surfaces (1), with some cables (2) in their outline and other support cables (20) from the corners of the sails and supported by the posts (3) and tiltable by means of the cables. (2a) and some lathes (5) powered by electric motors and controlled by a microprocessor. The posts (3) rotate through the ball joints (4) Add a gutter on the lower edge of the sail surfaces, to collect the water.

Figure 4, similar to the group in Figure 2, shows the overlapping and inclined sail surfaces (1), with some cables (2) in their outline and other support cables (20) from the corners of the sails and supported by the posts (3) and tiltable by means of cables (2a) and lathes (5) powered by electric motors and controlled by a microprocessor. Both cables (20) and the sail surfaces run high. The posts rotate through the ball joints (4). Vegetation is shown under the set of sail surfaces.

Figure 5 shows a sail surface (1) with longitudinal openings (7) that are created between a tense and a loose edge (2s), and where condensed water is deposited. The cables (2) of its outline are fastened and supported by the posts (3).

This system can be tiltable. The edge cable (2s) is heavier to allow a greater opening.

Figure 6, similar to that of figure 5, shows a sail surface (1) with longitudinal openings (7) that are created between a tense and a loose edge (2s), and where condensed water is deposited. The cables (2) of its outline are fastened and supported with the posts (3). Under the set of sail surfaces the vegetation or crop is shown. Figure 7 shows a device of great lateral length, with an angled post (44) supporting an opaque cloth or sail surface (40), attached to a transparent sheet (41) to solar radiation and attached to the ground from its lower edge ( 46). The light heats and evaporates the sea water from the channels (42), which ascends through the lower area of the transparent sheet (41) and the sail surface (40), which are heat insulating, cooling and condensing in the area adjacent to the post and depositing in the container or channel (43) . The post (44) can rotate on the ball joint (45) and with an electric motor or in a similar way to that shown for the other posts. It can be rotated both laterally and frontally. The sail surface (40) also runs alongside the post (44). The candles and sheets carry cables in their outline, which are not shown in the figure.

Figure 8 shows a group of sail surfaces (1) arranged parallel to each other and with a small inclination with respect to the vertical. Supported by cables (20) and posts (3).

Figure 9 shows a sail surface (1) arranged as a broken line section. At the lower corners it has longitudinal openings (7a) for the discharge of condensed water. It is supported by cables (20) and posts (3).

Figure 10 shows: a) a surface with multiple studs, b) a surface with relief undulations, surfaces c) and f) with broken line reliefs, d) with multiple parallel and relief ribs, and e) formed with a tangle or skein of threads.

Figure 11 shows in: g) a mesh, in h and k) a mesh simulating weaving, e) a very dense mesh, in m and n) hexagonal meshes and p) a mesh with wavy cords between two ribs or straight and parallel cords.

Figure 12 shows the microprocessor (30) which receives signals or data on the speed and direction of the wind (31), position of the sun (32), and sends signals or cables (33) that activate the motors or actuators through the conductors or cables (33). (5 and 34), in groups of four to rotate the sail surfaces, for protection from the sun or to control aeration.

The lifting systems in the rear area are not shown in the figures.

Claims (16)

1. System for obtaining water and vegetation in arid or desert areas, using condensation of atmospheric water vapor, which consists of covering the ground with one or more sail surfaces or sheets, which are placed semi-overlapping, overlapping or with openings longitudinal, so that they allow the passage or fall of condensed dew and frost, and prevent the passage of solar radiation, adding a complementary condensation system. 2. System according to claim 1, characterized in that the condensed water is deposited on the ground. 3. System according to claim 1, characterized in that the condensed water is deposited in channels or pipes placed on the lower edge of the sail surfaces or in deposits on or buried in the ground. 4. System according to claim 1, characterized in that the sail surfaces are supported by their corners and edges with cables supported in turn by posts. 5. System according to claim 1, characterized in that the sail surfaces are tilted manually or automatically depending on the direction and intensity of the wind, the time of day and the intensity and incidence of the sun. 6. System according to claim 5, characterized in that the inclination is carried out by means of a winch or pulley, a motor, a microprocessor controls the operation. 7. System according to claim 1, characterized in that the sail surfaces have openings that allow the condensed water to discharge. 8. System according to claim 1, characterized in that the sail surfaces, with a relief in the form of a broken section, have an opening in the lower area where the condensed water is collected and discharged. 9. System according to claim 1, characterized in that the sail or mesh surfaces run with the lower edge at ground level or elevated a few meters above the ground. 10. System according to claim 1, characterized in that the materials for the cables and posts are stainless steel and for the sail surfaces, sheets, fabrics and meshes, polypropylene or polyethylene with or without mixtures of graphene and synthetic fibers. 11. System according to claim 1, characterized in that the sail surfaces are given a light color to reflect the sun's rays. 12. System according to claim 1, characterized in that the sheet-like sail surfaces have multiple lugs on their surface. 13. System according to claim 1, characterized in that the mesh-like sail surfaces have alternate channels with ribs or protruding points. 14. System according to claim 1, characterized in that the sail surfaces have longitudinal openings, through which the condensed water enters and is deposited. 15. System according to claim 1, characterized in that the sail surfaces are opaque to light and light tones to produce the reflection of solar radiation. 16. System according to claim 1, characterized in that the complementary condensation system consists of a laterally elongated device, consisting of an angled post (44) that supports an opaque fabric or sail surface (40), attached to a transparent sheet (41) in sunlight and attached to the ground from its lower edge (46), the light heats and evaporates seawater from channels (42), and ascends through the lower area of the transparent sheet (41) and a sail surface ( 40), which are heat insulating, cooling and condensing in the area adjacent to the pole and depositing in a container or channel (43), the pole (44) rotates by means of a ball joint and an electric motor, the rotation does it frontally or laterally .