ES1280802U - Solar energy concentrator and collector system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Solar energy concentrator and collector system, of the type that uses the reflection of the sun's rays by means of mirrors, which consists of mirrors made up of multiple sheets, bands, fabrics or sheets of large surface area arranged longitudinally and peripherally supported by cables and a frame, posts or captive balloons at their ends that give it a parabolic-cylinder, semi-parabolic cylinder or pairs of mirrors at a dihedral angle, which concentrate the sun's rays in an equally longitudinal conduit or focus, which runs over or close to the ground, a fluid circulates through said conduit, which can be water, which evaporates by operating said fluid by driving a turbine that drives an electric motor, or a mineral oil whose heat is used to heat the electrolyte in the electrolysis or storage of said heat, the heat is used to desalinate water and the steam is applied to steam turbines, axial or helical turbines, and likewise entity to drive pneumatic motors, adding a protection system against the wind. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Solar energy concentrator and capture system

Field of the invention

In alternative energies for the realization of power plants or electric power plants, heating of buildings, desalination of sea water and elevation of the temperature in electrolysis.

State of the art

At present, a large part of the energy radiated by the sun is concentrated and captured by power plants with large parabolic trough mirrors, and increasingly low-cost photovoltaic panels, however, they are still expensive. Desalination systems are expensive and expensive to maintain, most of which cease to function over time. The present system is simple, useful and inexpensive and provides a large amount of energy and drinking water at a very low cost.

Description of the invention

Object of the invention and advantages.

Obtain energy cheaply and easily.

Using a practical system can be up to several dozen times simpler and cheaper than existing systems, which provides a large amount of energy allowing large solar thermal plants for electricity production.

Contribute to a system that concentrates the sun's rays in a simple and useful economic way. The fixed East-West longitudinal arrangement, in this system is very useful since with great inclinations (in the morning and evening) the capture of the solar rays is taken advantage of because the only thing that affects is the point where it does it longitudinally in the focal canal. However, it allows the use of the constant orientation system or in two or three fixed points towards the sun.

Use an oval, rectangular or flattened focal duct that allows receiving the sun's rays regardless of the sun's height.

Allow the use of mirrors made up of multiple sheets, fabrics or sheets with a large surface area that take advantage of the sun's rays even with the largest deviations that occur during the solstices.

Obtain drinking water by desalination in large quantities and economically. Facilitate the electrolysis of water and obtain H2 using high temperatures. It protects the environment to a high degree, and prevents climate change.

Problems to solve

The still high cost of current alternative energies and their equipment and the storage problem. Especially from low temperature electrolysis. Adding the difficulties to obtain drinking water from sea water.

The solar energy concentrator and collector system of the invention, of the type that uses the reflection of the sun's rays by means of mirrors, consists of mirrors formed by multiple sheets, bands, fabrics or sheets of large surface area arranged longitudinally and peripherally supported by cables. and a frame, posts or captive balloons at their ends that give it a parabolic-cylinder, parabolic-semi-cylinder or a pair in dihedral angle, which concentrate the sun's rays in a conduit or equally longitudinal focus, preferably elliptical or oval in section, rectangular or tile-shaped, which runs on or near the ground, (not affecting the aberration of the mirrors or requiring high precision in their operation). A fluid circulates through said conduit, which can be water, which evaporates by operating said fluid by driving a turbine that drives an electric motor or a mineral oil whose heat is used to heat the electrolyte in the electrolysis or storage of said heat, the Heat is used to desalinate water and steam is applied to steam turbines, axial or helical turbines, and to drive air motors.

The sheets, bands, fabrics, etc. of the mirrors rest on a grid of vertical cords attached to the parallel cables of the upper and lower edges. And these between the curved or straight posts (or bars) that give the mirrors a curved or flat shape, and are directed towards the sun of the equinoxes at their base to allow the retraction of the sheets, bands, etc., for maintenance or for protection from the wind. They can also be retracted by winding the sheets, bands, etc., on impellers by means of electric motors. They can be placed in several sections joined longitudinally. Protection against the wind is also achieved by turning the posts which are hinged at their base.

Sheets or bands can also be released automatically. An actuator is actuated and they are retracted by the action of a spring.

The sheets or plates are preferably placed fixed, longitudinally in the east-west direction, corrected for the solar declination of the place, the angle formed by the Sun-Earth line and the plane of the celestial equator (projection of the terrestrial equator). The solar declination is equal to zero at the spring and autumn equinoxes and maximum at the solstices.

They can also be tiltable laterally depending on the time or season of the year. Even allowing an inclination of up to 23 °, with respect to the equinoctial or ecliptic plane of the area. For southern Europe the inclination is usually between 30 ° and 40 °.

You can also move the focal duct instead of the mirrors. The focal canals are placed inside the pairs of foils or V-mirrors.

Electric motors retract the plates or plates when a sensor is actuated by a flap and wind action.

The sheets or plates can also be placed in these same positions and can be rotated or tilted manually or with a sun follower servomechanism or moved laterally depending on the day of the year by means of a microprocessor. The inclination of the sun can also be followed by photoelectric cells. Another alternative is by means of actuators, two or three positions can be applied to them, corresponding to different times of the year. It would only be necessary to correct the latitude two or three times.

The ducts can be advantageously thermally insulated, especially by their lower or opposite zone to the incidence of the solar rays. For the top or side it is enough to use the glass duct. They can also run on the ground.

Filtered water is automatically introduced into the pipes from pressurized tanks fed by pumps as it evaporates. Later it is returned evaporated to the system or to the condensed tank, if there is a deficiency.

In the case of being used for desalination, the water evaporates in the focal ducts and is applied to parallel ducts where it is condensed in condensers from where it is stored or used.

The system can be placed in a channel made in the ground, in this way it does not protrude and is more protected from the winds.

In a variant, preheaters consisting of thin ducts in a flat or curved shape are used.

The sheets, bands or plates of the mirrors can be constituted by a policle of a metal of great reflection silver, aluminum, chrome, copper, reflective polymers, solgel type mirrors, etc., coated or between thin plastic films, varnish, etc. . Or a metal or plastic plate or sheet covered with a silver or aluminum film that acts as a reflector. A variant uses a metal plate or sheet polished, anodized or with a bath of a reflective metal, also aluminized plastic or nickel-plated bronze. In all cases, the silver or aluminum film, polished or anodized surface, is covered with a transparent layer of metal varnish, resin, polyester or the like that acts as a protector against environmental corrosion. The mirror can be reinforced or supported by a fabric, mesh of fine threads or flattened and equally reflective strips forming large squares, or by groups of parallel threads on one or both sides. It can also rest on a mesh, grid or independent plate. Flat mirrors can be held by rigid arms.

Energy storage can be done pneumatically with vessels on the seabed.

Brief explanation of the drawings

Figure 1 shows a schematic and cross-sectional view of a concentrating mirror formed by sheets, plate or longitudinal bands with the solar rays concentrated on a focal duct of circular section.

Figures 2 to 9c show schematic and cross-sectional views of variants of concentrating mirrors of the system of the invention.

Figure 10 shows a schematic and perspective view of an orchard of concentrators of the system of the invention used in a solar thermal power plant.

Figures 11 and 12 show two schematic and plan views of two thermal plants using the concentrator system of the invention.

Figure 13 shows a schematic view of a grid of horizontal cords or cables held between two posts, which serve as support for the mirrors.

Figures 14 and 15 show schematic and front views of mirrors supported by cables between two posts.

Figure 16 shows a side view of a pole, defeated by the effect of the wind on its mirror.

Figure 17 shows a schematic and perspective view of a parabolic semi-cylinder type mirror.

Figure 18 shows a schematic and side view of a mirror retraction system.

Figure 19 shows a schematic and perspective view of a variant of the retraction system for the sheets or bands of the mirrors.

More detailed description of an embodiment

Figure 1 shows the solar rays (3) incident on the semi-cylinder parabolic mirror (1), which reflects and concentrates them in the cylindrical focal duct (2).

Figure 2 shows the solar rays (3v, of the summer solstice) (3e, of an equinox) (and 3i, of the winter solstice, all this for the northern hemisphere, striking the mirror (1) that reflects and concentrates them in the semicylindro-parabolic focal duct (2), elliptical or oval in section. The mirror (1) is supported by the posts (4) at the ends and some cables not shown in the figure. The north (N) and the south (S ) are to determine its geographical orientation. Figure 3 shows the solar rays (3v, of the summer solstice) (3e, of an equinox) (and 3i, of the winter solstice) all this for the northern hemisphere, incident on the mirror (1) parabolic semi-cylinder that reflects and concentrates them in several circular ducts (2c). Shows separated one of the support posts (4.) The north (N) and south (S) used are to determine its geographical orientation.

Figure 4 shows the solar rays (3v, of the summer solstice) (3e, of an equinox) (and 3i, of the winter solstice) all this for the northern hemisphere, striking the semi-parabolic mirror (1) that reflects them and concentrated in the duct (2) of elliptical or oval section. It is shown alongside Figures 5 through 7 for comparison.

Figure 5 shows the mirror (1) formed by multiple subsmirrors, between the mesh or bars (4f and 4r) with the focal duct (2).

Figure 6 shows the multiple mirrors (1) of figure (5) extended by the pressure of the wind, rotating their upper edge around the cords or cables (1c) of the upper edge attached to a central mesh (1s) between the two meshes or bars (4f and 4r). Add the focal canal (2).

Figure 7 shows the multiple mirrors (1) of figure (6), more extended than in figure 6, due to the pressure of the higher intensity wind, rotating their upper edge around the cords or cables (1c) of the upper edge attached to a central mesh (1s) between the two meshes or bars (4f and 4r). Add the focal canal (2).

Figure 8 shows several mirrors (1) that are rotatable or tiltable and secured from their upper edge by means of the cables (6). The cables are held at their ends by the posts (4), with their flexible lower end, which are tiltable by means of the cable (6). The solar rays fall on the mirrors and concentrate on the focal duct (2). North (N) and South (S) are to determine your geographic orientation.

Figure 9 shows multiple mirrors (1), which determine a semi-cylindrical parabolic mirror, rotating around the cables (1s), supported by the masts (4), which concentrate the solar rays on the sides of the duct (2) of elliptical section or oval. You can use only one mirror.

Figure 9a shows multiple mirrors (1) rotating around the cables (1s), determining two V-shaped mirrors, concentrating the solar rays on the oval duct (2).

Figure 9b shows the parabolic semi-cylinder mirror (1), (it can be a parabolic semi-cylinder), of great length, attached and partially attached to the mesh or net (4m) supported on its upper edge by at least two captive balloons (61), the cords or cables (62) and the winds (63) that shape it. The sun's rays are concentrated in the focal duct (2).

Figure 9c shows the mirrors (1) in V, of great length partially attached to the meshes or nets (4m) supported their upper edges by at least two captive balloons (61), cables (62) and the winds (63). The lower edges are attached to the ground.

Balloon holding cables are not shown in Figures 9b and 9c.

Figure 10 shows an orchard of solar concentrators or mirrors (1), or partial solar thermal power plant, with the semi-cylindro-parabolic mirrors (1) and the elliptical section duct (2). North (N) and South (S) determine its geographic orientation.

Figure 11 shows a solar thermal plant formed by the filter (19a), the water pump (19) that feeds and pressurizes the chamber (14) from where the water is sent through the duct (15) to the focal ducts of multiple focal concentrators formed by the mirrors (1) and the focal ducts (2) that meet and apply the water vapor to the turbine (7) which drives the electric generator (8). The steam leaves the turbine and is fed back through the conduit (12) through the check valve (16). In the conduit (12) it can carry a condenser.

Figure 12 shows a small solar thermal plant formed by the water pump (19) or another fluid, which after passing through a filter not shown in the figure, feeds and pressurizes the chamber (14), from where it is sent through the conduit (15) to a concentrator formed by a mirror (1) and the focal conduit (2) that applies the water vapor in the chamber (31) to the water desalination conduit (30). The water vapor is fed back to the inlet of the focal conduit through the check valve (16). Heat can also be used to facilitate the reaction in electrolysis.

Figure 13 shows the posts (4) of a solar concentrator, between which multiple cords or cables (6h) are arranged between them, which serve as support and shape the mirrors together with the posts.

Figure 14 shows a mirror (1) secured by means of the upper and lower cables (6) to the posts (4), which can be extended and retracted by means of the cables or ropes (20) and the pulleys (23). The posts have their lower end rotatable on a support around the axis (29).

Figure 15 shows the mirrors (1) secured by the cables (6) to the posts (4). The mirror is extended and retracted by means of cables or ropes (20) and pulleys (23).

Figure 16 shows the post (4) supporting the mirror (1) which is flexed by the action of the wind as its lower end (4f) is flexible.

Figure 17 shows a parabolic semi-cylindrical mirror (1) supported at its ends by posts (4). In the lower area it carries the focal duct (2).

Figure 18 shows the post (4) that supports from its ends the horizontal cables (6h) which in turn support the semi-parabolic mirror (1), which is retracted for protection from the wind by means of the cable or strap (20) that It runs between the winch pulley (21) and the pulley (23) at the upper end of the mast, thereby moving the junction point (24) between the cable (20) and the mirror (1). During its collection the mirror is shown with the dashed line. It shows the focal ducts (2c) and the geographic points (N and S).

Figure 19 shows two posts (4) between which the horizontal cables (6h and 6) that support the mirror (1) and give it shape are arranged. When the roller formed by some discs (25a) and the cables (22) rotates between their peripheries, the mirror (1) is wound with the help of the pulley (23) and the cable (20a), which by means of a motor or a spring it keeps him taut. Shows geographic points (N and S).

In all cases, the systems can be placed in the so-called south orientation, that is, placed longitudinally in the E-W direction. Vehicles are added to the pictures showing the relative size of the mirrors.

Claims (24)

1. Concentrated system and solar energy collector of the type that uses the reflection of the sun's rays by means of mirrors, which consists of mirrors formed by multiple sheets, bands, fabrics or sheets of a large surface arranged longitudinally and peripherally supported by cables and a frame, posts or captive globes at their ends that give it a parabolic-cylinder, semi-parabolic cylinder or pairs of mirrors at a dihedral angle, which concentrate the sun's rays in a conduit or equally longitudinal focus, which runs on or near the ground , a fluid circulates through said conduit, which can be water, which evaporates by operating said fluid by driving a turbine that drives an electric motor, or a mineral oil whose heat is used to heat the electrolyte in the electrolysis or storage of said heat , the heat is used to desalinate water and the steam is applied to steam turbines, axial or helical turbines, and also to drive pneumatic motors, adding a protection system against the wind. 2. System according to claim 1, characterized by the mirrors: sheets, bands or fabrics are supported by a grid of vertical cords attached to the parallel cables of the upper and lower edges, and these between the curved or straight posts (or bars) that they give a curved or flat shape to the mirrors, and they are directed towards the sun of the equinoxes when they are fixed (or inclined in the plane of the ecliptic). 3. System according to claim 1, characterized in that the posts have an articulated base, allowing the retraction of the sheets, bands or fabrics. 4. System according to claim 1, characterized in that the posts have a flexible lower end allowing the retraction of the sheets, bands or fabrics. 5. System according to claim 1, characterized in that the mirrors are retracted by winding themselves into wheels by means of electric motors. 6. System according to claim 1, characterized in that the protection against the wind is carried out by automatically releasing the mirrors, sheets or bands. 7. System according to claim 1, characterized by the mirrors: sheets, bands or fabrics are preferably placed fixed, longitudinally in the east-west direction, corrected in the solar declination of the place, angle formed by the Sun-Earth line and the plane of the equator celestial (projection of the terrestrial equator). 8. System according to claim 1, characterized in that the mirrors: sheets, bands or fabrics follow the position of the sun by means of photoelectric cells. 9. System according to claim 1, characterized in that the mirrors: sheets, bands or fabrics are laterally tiltable depending on the time or season of the year by means of a processor, microprocessor or photoelectric cell and a servo system. 10. System according to claim 1, characterized in that instead of moving the mirrors, the focal ducts move. 11. System according to claim 1, characterized in that the mirrors: sheets, bands or fabrics are rotated or tilted manually. 12. System according to claim 1, characterized in that by means of actuators two or three positions are applied to the mirrors, corresponding to different times of the year. 13. System according to claim 1, characterized in that the electric motors retract the mirrors, sheets or bands when a sensor is actuated by a fin and the action of the wind. 14. System according to claim 1, characterized in that the focal conductors take the shape of an elliptical or oval section, rectangular, tile-shaped, cylindrical or of several aligned parallel cylinders. 15. System according to claim 1, characterized in that the focal ducts are thermally insulated, especially by their lower or opposite zone to that of incidence of solar rays. 16. System according to claim 1, characterized in that the focal ducts run through the ground. 17. System according to claim 1, characterized in that the water is filtered and automatically introduced into the focal ducts from pressurized tanks fed with pumps as it evaporates, subsequently the evaporated water is fed back to the system or a condensed tank. 18. System according to claim 1, characterized in that the water from the focal ducts is applied to parallel ducts for the evaporation of the salty water, the vapor of which is subsequently condensed. 19. System according to claim 1, characterized in that the system is placed in a channel made in the ground, being protected from the winds. 20. System according to claim 1, characterized in that preheaters consisting of thin ducts of flat or curved shape are used. 21. System according to claim 1, characterized in that the mirrors: sheets, bands or fabrics are made up of a film of a highly reflective metal: silver, aluminum, chrome, copper, reflective polymers, sol-gel type mirrors, coated or between end plastic films, varnish, or a metal or plastic plate or sheet covered with a silver or aluminum film that acts as a reflector. 22. System according to claim 1, characterized in that as mirrors it uses a polished, anodized metal plate or sheet or with a reflector metal ball, also aluminized plastic or nickel-plated bronze. 23. System according to claims 21 and 22, characterized in that in all cases the silver or aluminum film, polished or anodized surface, is covered with a transparent layer of metal varnish, resin, polyester or the like that acts as a protective against environmental corrosion . 24. System according to claim 1, characterized in that the mirrors are reinforced or supported by a fabric, mesh of fine threads or flattened and equally reflective strips, or by groups of parallel threads on one or both sides.