ES1287020U - Improvements in energy collector systems of maritime, fluvial and wind currents (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Improvements in energy collector systems of maritime, river and wind currents, of the type using helical turbines, characterized in that the turbines are helically and the turns or threads have an inclination close to 45º, and fastened from one end by a cable between the two edges of a river, or in a narrowing thereof, or fastened to a pole, shaft or a chain, fixed to the soil or bottom of the sea, attached to the axes of the generators that are Covered by a housing or aerodynamic gondola front or on the other side of the clamping mast, the turbines drive a generator and electrical conduction cables and a safety installation and warnings are added, the generator is placed between the shaft or end of the turbine and The element or fastening means, or behind the pole, on the opposite side of the turbine. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Improvements in the energy capture systems of maritime, fluvial and wind currents

field of invention

In energy collectors from maritime, river and wind currents, which generate electricity for homes, agriculture, desalination of sea water, elevation of water, feedback of the current to the electrical network, obtaining hydrogen by electrolysis of water, etc.

State of the art

Today's dams need special locations, large structures, and high costs to achieve high yields. The water currents are used with bladed turbines, which are not useful because they damage the fauna, adhere to them all the plant elements, algae, garbage, nets, plastics, etc., existing in them. On the other hand, the helical type, or endless screw, are used partially and only enclosed inside ducts, which is why they are not efficient. The invention uses simple, useful and economical, axial and helical turbines, protected according to patents P201600696, P201700136 and the utility model U202100176, which allow harnessing the energy of wind currents, sea currents and that available in rivers and streams from its highest point until it reaches the sea, lake or other river. Generally taking advantage of these, horizontal currents or with little unevenness.

Description of the invention

Purpose of the invention and advantages

Obtain energy mainly from sea and river currents, which, unlike solar and wind energy, can or usually are constant and do not have long periods of calm. Water is about 832 times denser than air. Being this proportion higher when it comes to high places where the air is more rarefied.

To be able to use simple turbines, low cost, high power, high performance, minimum cost per kW/h, minimum number of parts, one-piece, without shaft, without bearings, or their supports or supports, anchored to the ground, do not need masts, nailed , anchored or ballasted may be sufficient, they are clean (they are not affected or accumulate dirt), they do not need a cover or casing, they admit large and small dimensions, great lengths or several in series, they can be flexible, inflatable and extensible, they work in line with the current or inclined with respect to it, they do not kill fish or birds, they protect the ozone layer and the environment, they are self-directing with the current without the use of electrical mechanisms and by using constant currents they eliminate the need to have to store the Energy. The most useful and simple are those that do not have a shaft, twisted metal or plastic beams or planks, and the quarter or half-round helicoidal ones without a shaft. In all cases, it is important that they have a conical or frustoconical external shape with the lower end towards the point of origin of the current.

Provide different fastening systems between the turbines and the generators, and making the masts more aerodynamic.

In 2020, production in Spain was distributed as follows: nuclear (22.2%), wind (21.9%), combined cycle (17.5%), hydraulic (12.2%), cogeneration (10.7 %), solar (7.9%) and others (7.8%). With these improvements it is intended to promote mainly the hydraulic, fluvial or maritime ones.

Problem to solve

Renewable energy is not yet productive enough to be used in large quantities, it is not constant, it produces visual pollution, and due to its discontinuity it needs to be stored. On the other hand, the turbines used in water currents use blades or, when they are helical, they only use the lateral half of the turbine since they are always used enclosed within a cylindrical or semi-cylindrical conduit. With the present system, a lot of constant energy is obtained, its storage not being necessary, and it can be placed where it does not harm or pollute electrically, audible or visually and in most of the rivers whose currents are underused.

Improvements in systems for capturing energy from sea, river and wind currents, using simple and efficient turbines and a more aerodynamic arrangement of poles and generators or their cover, in rivers, at sea and in wind systems , are characterized in that the turbines are helical in shape and the coils or threads have an inclination close to 45°, with a quarter of a cane or quarter of a circle section and are placed attached to the generator shafts that are covered by a streamlined casing or nacelle in front of or on the other side of the support mast. The upper area of the mast can rotate with the generator and have an aerodynamic profile. They can be installed subject to one end by means of a cable between the two banks of a river, or in a narrowing of the same, or they can be subject to elements or means of fastening consisting of a post, tree, or with a chain, fixed to the ground. at the bottom of the sea or river. The turbines drive a generator and power cables and a security and warning installation are added. The generator is placed between the shaft or end of the turbine and the element or means of support, or behind the pole, on the opposite side of the turbine. In this case, it has a ball joint at the upper end of the post.

The helicoidal turbine of the type of turn or thread of quarter cane, or quarter of a circle, has the outermost edge directed towards the current, channeling it and exiting through the opposite edge in the perpendicular direction towards the interior of the turbine.

The turbines are fastened to the mast with a ball joint, ring or collar on or around the mast and their connection to the axis of the electric generator can be with a universal or cardan joint.

Turbines may be shaftless, consisting of only one or two fins or helical coils. The shaft can act as a float.

The turbines adopt a cylindrical external shape, and preferably conical or frustoconical.

On the banks of the rivers, artificial narrowings are made with rocks or concrete blocks and posts in the form of hooking bollards as fastening elements.

When a support cable or chain is used, the upper end of the cable or chain carries a buoy or balloon and the other end is fixed to the ground or bottom of the sea or lake by means of a ballast or concrete block.

Two or more turbines can be attached to the chain or cable.

The turbines can have a density equal to or close to that of water, or they can have different densities, with which they can adopt a certain inclination with respect to the fluidic current.

The turbines, their shafts, fins or coils, in addition to being hollow and filled with air, can be made of plastic polymer foam such as PVC, polyurethane, polyethylene, etc., with a resistant and protective cover, and can act as weather vanes. The hollow ones can be metal, rubber or plastic, unreliable and flexible. In general, due to being in contact with water and with elements that can be abrasive, resistant and low-density materials, polymers, carbon fibers or glass with resins must be used. And in case of using metallic materials, such as steel, they must have a protective layer of zinc. Plastic can be reinforced with graphene and highly resistant synthetic fibres, Kevlar, glass, carbon, etc.

The turbine can be fixed to the rotating collar, cardan joint, ball joint, etc., and the generator can be placed in front of or behind the clamping shaft. In this case the shaft of the generator or mechanical device is connected to the rotating end of the turbine directly or through an rpm multiplier.

The helical turbines, fins, beams or planks have a performance proportional to their transversal or frontal section, to the angle that they form with the axis of rotation at each point and to their length. Angles between 25° and 55° can be used. Unlike turbines of this kind that move inside a conduit, these can greatly increase their power by increasing their length. The fins can have two types of inclination: a) Inclination of a section of the fin with respect to the axis of rotation and b) Inclination of a section of the fin with respect to a plane perpendicular to the axis of rotation. Maximum yields occur at approximately 42° incline angles.

Turbines, when they do not have a shaft, consist exclusively of helical fins or coils, of helical wire or coil springs, preferably quarter or half-round or flat, or of helically twisted metal or plastic beams or planks. In the helical fin or helical loop with a quarter round or quarter round section, the air or water, upon hitting it, is launched centripetally, generating a reaction with maximum use, for which the efficiency is much greater.

You can use turbines formed by sail surfaces which have slits through which the air comes out laterally and at an angle.

Turbines in series can be used.

Electric generators can be synchronous and totally permanent magnets, especially rare earth samarium-cobalt or neodymium-iron-boron.

As mechanical elements, motor pumps are used to raise water or drive electric generators.

The turbines should preferably be axial, receiving the flow of water parallel to their axes and directing themselves automatically as vanes, but they can have an inclination with respect to the horizontal, which depends on the difference between the weight of the turbines, including the adjoining installation , generator, and the weight of the water it displaces. When both factors are equal, they remain horizontal in the fluidic current. Any type of turbine can be used, with or without a shaft, especially those that are longitudinally extended and with blades or blades that are inclined, twisted or arranged helically. To increase their stability, their aerodynamic profiles are made to have the dimensions of the turbines, their shafts and/or their blades are divergent or larger towards the free end.

With the turbines inclined with respect to the fluid current, the performance can be even greater since the section of the affected surface is much greater than with the frontal current. However, when the turbines receive the current parallel to the axis, since they are not covered by a tube, the efficiency is very high, the power is multiplied with the length of it. Since downstream the turbine absorbs or captures the energy of the current laterally.

The turbines can have the free end attached to a buoy or a float.

The turbines can partially act as floats. In all cases, the turbines, cables, chains, generators or support bars can have a density equal to or similar to that of water. They can have a density between 70% and 130% of that of water, although it is not limiting.

The turbines can be arranged in an orderly manner, in rows and columns, so that they can use common electrical or water installations and a large area.

The fins, blades or turbines can be rigid or flexible. Inclining the flexible fins and reducing their impact surface with increasing water speed.

Small turbines tend to go higher revolutions and do not need revolution multipliers.

The generator is attached to a support point by means of a bar and a joint and a collar that allows it to tilt slightly vertically and horizontally but not rotate around its axis. This is also achieved with a pair of links or a cardan joint. The generator can also be placed on the other side of the pole from the turbine.

Radial fins help prevent oscillations due to turbulence.

A control, warning and safety system reports the status of each of the devices. Brief description of the drawings

Figure 1 shows a schematic, partial and side view of a quarter-rod type turbine, or quarter-circle section, helical, shaftless, frustoconical in shape, a generator and a method of fastening by means of a mast, of the system of the invention.

Figures 2 and 3 show plan views of two types of turbine blades of figure 1. Figure 4 shows a schematic view and longitudinal section of the helical turbine of figure 1.

Figures 5 to 9 show schematic and side views of variants of helical turbines.

Figure 10 shows a schematic and plan view of the turbine of figure 9.

Figure 11 shows a schematic view of a twisted metal or plastic beam or plank-type turbine.

Figures 12 and 13 show schematic and plan views of variants of turbines placed by means of cables between the two banks of a river.

Figure 14 shows a schematic side view of a row of turbines formed by sail surfaces.

Figure 15 shows a schematic view of a sail of the collector of figure 14.

More detailed description of an embodiment of the invention

Figure 1 shows an embodiment of a helical turbine (1), of the quarter-rod or quarter-circle type, without a shaft, of a frustoconical shape, with its lower end (6) attached to the shaft (5) of the electric generator (7) and its cover or gondola (8) and this in turn forms part of the aerodynamic support element (2) rotating on the mast (4) by means of the stem (3). Allowing the rotation of the turbine and generator axis and the orientation and inclination of the turbine and generator. The generator shaft is attached to the support element (2) by one or two bearings. The mast is fixed to the ground at the bottom of the river or the sea.

Figure 2 shows a frustoconical, shaftless, helical-type turbine (1).

Figure 3 shows a turbine similar to that of figure 2 but with different dimensions.

Figure 4 shows the quarter-round or quarter-round helical turbine (1), where the small arrows show the centripetal deflection of water or air, generating a reaction and rotation of the turbine.

Figure 5 shows the helical turbine (1), of the quarter-round or circular type, without a shaft, in a frustoconical shape, the electric generator (7) and its cover or gondola (8) held by the chain (9) the which is subject to the bottom of the sea or river by means of the concrete block (10).

Figure 6 shows the helical turbine (1), of the quarter-round or quarter-round type, without a shaft, in a frustoconical shape, the electric generator (7) and its cover or gondola (8) attached by means of the chain ( 9) which is attached to the bottom of the sea or river by means of the concrete block (10). It can be anchored to the ground or bottom.

Figure 7 shows the helical turbine (1), with shaft (6), quarter-round type, or quarter-circle, with shaft (6), frustoconical in shape, the electric generator (7) and its cover or gondola (8) and the mast (4).

Figure 8 shows the helical turbine (1) with a twisted metal or plastic beam or board, in a frustoconical shape, the electric generator (7) and its cover or gondola (8) and the mast (4). Figure 9 shows a variant of the turbine (1) with the shaft (6) and with the cardan joint (15) attached to the shaft of the electric generator (7) and its cover or nacelle (8) and this in turn forms part of the rotating support element (2) on the mast (4) by means of the stem (3). It allows the rotation of the turbine and generator axis and the orientation and inclination of the turbine and generator. The generator shaft (5) is fastened to the support element (2) with one or two bearings. Add the deflector plates (18) and (18a), the latter attached to the collar (19), which increase the flow of fluid towards the turbine. The mast is fixed to the ground, bottom of the river or the sea. Figure 10 shows a variant of the turbine (1) with shaft (6) attached to the shaft of the electric generator (7) and its cover or gondola (8) and this in turn forms part of the support element (2) rotating on the mast (4). The generator shaft is attached to the support element (2) by one or two bearings. Add the deflector plates (18) that increase the flow of fluid towards the turbine. The mast is fixed to the ground, bottom of the river or the sea.

Figure 11 shows a variant of the turbine (1), without a shaft, of the type of twisted metal or plastic beam or plank, whose end is joined with the cardan joint (15) to the shaft of the electric generator (7) and its cover or gondola (8) and is in turn forming part of the rotating support element (2) on the mast (4) by means of the rod (3). Allowing the rotation of the turbine and generator axis and the orientation and inclination of the turbine and generator. The generator shaft is attached to the support element (2) by one or two bearings. The mast is fixed to the ground, bottom of the river or the sea. Shows the optional extension (2a) of the support (2), with a warning light.

Figure 12 shows a helical-type turbine (1), attached at its end to the cover or nacelle of the generator (7) and this in turn to the cable or chain (11) attached at its ends to the posts in the form of bollards. (12) on the banks of a river.

Figure 13 shows two cables (11) attached to both sides of a river, each of them holding rows of generators and their turbines (1). Fastened between posts (12).

Figure 14 shows a row of oval-shaped sail elements or surfaces (21) that act as turbines (1) in series, traversed by the cable (20) which are attached to their periphery by cords or cables (22). Being the end of the cable attached to the axis of the generator (7) and covered with the casing (8) attached to the support element which are rotatable with respect to the vertical axis of the mast (4).

Figure 15 shows the sail element (21), oval in shape with notches (23) on two sides of its ends, its fastening cords (22) to the central cable (20), which transmits the energy captured to the electric generator. .

Claims (22)

1. Improvements in the systems for capturing energy from maritime, fluvial and wind currents, of the type that uses helical turbines, characterized in that the turbines are helical in shape and the coils or threads have an inclination close to 45°, and are fastened from one end by means of a cable between the two banks of a river, or in a narrowing of the same, or are attached to a post, tree or a chain, fixed to the ground or to the bottom of the sea, attached to the shafts of the generators that are covered by a streamlined casing or nacelle in front of or to the other side of the support mast, the turbines drive a generator and electrical conduction cables and a safety and warning facility are added, the generator is placed between the shaft or end of the turbine and the element or means of fastening, or behind the post, to the opposite side of the turbine. 2. Improvements according to claim 1, characterized in that the upper end of the mast bears a support element for the generator, which has an aerodynamic profile and rotates with respect to the mast by means of a stem that is inserted into said mast. 3. Improvements according to claim 1, characterized in that the turbines are fastened with a ball joint, ring or collar around the mast and their connection to the axis of the electric generator is made with a universal or cardan joint. 4. Improvements according to claim 1, characterized in that the turbines have no axis, consisting only of one or two fins or helical coils. 5. Improvements according to claim 4, characterized in that the helical turbines of the type of spiral or thread of quarter cane, or quarter of a circle, have the outermost edge directed towards the current, channeling the fluid towards the opposite edge in the direction perpendicular, towards the inside of the turbine. 6. Improvements according to claim 1, characterized in that the turbines adopt a cylindrical, conical or frustoconical external shape. 7. Improvements according to claim 1, characterized in that artificial narrowings are made on the banks of the rivers with rocks or concrete blocks and posts in the form of hooking bollards as fastening elements. 8. Improvements according to claim 1, characterized in that when a fastening cable or chain is used, the upper end of the cable or chain carries a buoy or balloon and the other is fixed to the ground or bottom of the sea or river by means of a ballast anchor or block of concrete. 9. Improvements according to claim 1, characterized in that the turbines have a density equal to or different from but close to that of water or air. 10. Improvements according to claim 1, characterized in that the turbines, their shafts, fins or coils, in addition to being hollow, are filled with air or with plastic polymer foam such as PVC, polyurethane and polyethylene, with a resistant and protective cover. 11. Improvements according to claim 10, characterized in that the turbines, in addition to being hollow, are metallic, rubber or plastic, unreliable or flexible and resistant and low-density materials are used, polymers, carbon fibers or glass with resins, and when they are made of Steel has a protective layer of zinc and the plastic is reinforced with graphene and resistant synthetic fibres, Kevlar, glass or carbon. 12. Improvements according to claim 1, characterized in that the turbines are fixed to the rotating collar, cardan joint or ball joint, and the generator is placed in front or behind the support mast, in which case the axis of the generator or mechanical device is connected to the rotating end of the turbine directly or through an rpm multiplier. 13. Improvements according to claim 1, characterized in that the turbines, when they do not have a shaft, consist exclusively of helical fins or coils, of helical wire or coil springs, preferably quarter or half-round or flat, or of metal or flat beams or planks. helically twisted plastic. 14. Improvements according to claim 1, characterized in that the turbines are made up of sail surfaces which have notches through which the air exits laterally and at an angle. 15. Improvements according to claim 1, characterized in that turbines are used in series. 16. Improvements according to claim 1, characterized in that the electric generators are synchronous, and totally permanent magnets, samarium-cobalt or neodymium-ironboron. 17. Improvements according to claim 1, characterized in that the turbines have the free end attached to a buoy, float or balloon. 18. Improvements according to claim 1, characterized in that the turbines, cables, chains, generators or support bars have a density equal to or similar to that of water or air, between 70% and 130% of that of water or air. air. 19. Improvements according to claim 1, characterized in that the fins, blades or turbines are flexible, the flexible fins inclining and reducing their impact surface with the increase in water speed. 20. Improvements according to claim 1, characterized in that the turbines use a revolution multiplier between them and the generator. 21. Improvements according to claim 1, characterized in that a control, warning and security system reports the status of each of the devices. 22. Improvements according to claim 1, characterized in that the mast carries deflector plates that direct and increase the flow of water or air towards the turbine.