ES1311946U - Wind energy collection system - Google Patents

Abstract

Wind energy capturing system, using turbines consisting of sails and cables, characterized in that it consists of a turbine or rows of turbines formed by one or more sail surfaces made of canvas, fabric or plastic sheet in the shape of a spherical cap, cone, cap or bell-shaped, attached to one or two masts by means of cables and peripheral cords at their ends, to the axis of the electric generator or mechanical element to be moved, and whose sail surfaces carry lateral openings through which the air exits in an inclined manner, creating a constant torque, a microprocessor controls the operation by providing luminous and audible warnings and its safe operation by means of sensors, motors and actuators. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Wind energy collection system

Technical sector

In wind energy systems, which generate electricity for homes, agriculture, seawater desalination, water elevation, feedback of current to the electrical grid, obtaining hydrogen by electrolysis of water and storing pressurized air in ponds at great depth in the sea.

Objective of the invention and advantages.

Providing a large, cost-effective source of energy independent of optimal wind conditions, it does not require an optimal or elevated location.

Using collectors, which use sails or canvas to achieve very large dimensions, providing a large amount of energy at a low cost. Without taking into account the generator, these turbines can have a cost between one-tenth and one-hundredth of that of a typical wind turbine.

They can be applied without a pole or mast using existing poles or elevated areas, buildings, etc.

In some cases, inflatable tubes can be used as masts, which simultaneously facilitate their retraction.

Use low and high intensity winds, obtaining a reduced cost per Kw/h.

Being able to use electric generators, synchronous, with multiple pairs of poles, with rpm multipliers, or installations with air compressors or hydraulic pumps driven directly by the turbine shafts.

Provide a simple and high-performance system that does not pollute, does not kill birds, does not produce noise, vibrations, radioelectric interference and does not need electrical devices to direct it towards the wind.

Being able to obtain electricity, hydrogen, desalination of sea water, and pneumatic storage at the bottom of the sea.

Background of the invention

Current wind energy systems require high technology, high costs, high altitude placement or high winds to achieve high performance, depending on wind conditions that are difficult to find. They are difficult to control and complex. They produce electrical interference and are not widely accepted by the general public. Energy is therefore more expensive than with conventional systems. The present invention eliminates these drawbacks by providing a simple, useful and economical system, using turbines with cables and sail surfaces, spherical caps or parachutes made of canvas, fabric or plastic.

Explanation of the invention

Problem to solve.

There is a great need for renewable energy at low cost. Current systems have made costs much lower, but they still require a lot of subsidy that has to be paid for somehow. The present invention solves most of these problems.

The wind energy capturing system of the invention consists of a turbine or rows of turbines formed by one or more sail surfaces made of canvas, fabric or plastic sheet in the shape of a spherical cap, cone, cap or bell-shaped, attached to one or two masts by means of cables or cords on their periphery and ends, to the axis of the electric generator or mechanical element to be moved, and whose sail surfaces carry lateral openings through which the air exits in an inclined manner, creating a constant torque. A microprocessor controls the operation by providing light and audible warnings and its safe operation by means of sensors, motors and actuators.

For rows of turbines between two poles, spherical caps or caps with tether cords on both sides and a central hole can be used so that they can move along the cable and be set up in winds from both directions. Pairs of conical elements or caps connected at their vertices are also used for this. Groups of rows of turbines between two poles can be turned towards the wind by moving one end using a cable and a winding drum driven by an electric motor. The other ends can be fixed using poles or poles and a cable.

The electric generators can be placed between the turbines and the poles or on the opposite side of them.

When only the turbines are attached at one end, the turbines are automatically steered by the air current or wind because the assembly consisting of cables, frame and sails is set back from the support point or mast on which it rotates and is steered. On the opposite side, the electric generator can be carried as a counterweight, covered by an aerodynamic casing. In a variant, instead of using cap-shaped sail surfaces, triangular sails are used.

In large turbines, rpm multipliers can be applied between the turbine and the generators or synchronous generators can be used.

When possible, the mechanical energy obtained can be used to compress air, storing it in flexible containers submerged in the sea at medium or great depth until the moment of use.

Non-oxidizable materials based on steel, zinc, fiberglass or carbon can be used, as well as fabrics or canvases made of natural or synthetic fibers reinforced with graphene.

Protection from strong winds is achieved by electrically retracting the mast when a wind speed sensor detects a certain intensity. In the latter case, the turbine masts rotate or tilt around the support, which is articulated. The system can be coloured orange, red or green.

Strobe lights are used to determine and warn of their location, when their dimensions are important.

Brief description of the drawings

FIG. 1 shows a schematic and side view of a spherical cap or parachute row turbine in operation of the system of the invention.

FIG. 2 shows a schematic side view of the turbine in Figure 1 with the caps or similar retracted.

FIGS. 3, 4, 8, 9 and 10 show schematic views of turbines of the invention.

FIGS. 6 and 7 show schematic and plan views of groups of turbines that allow steering into the wind.

FIG. 11 shows a schematic and side view of a turbine variant.

FIG. 12 shows a sectional view of the turbine of Figure 11.

FIG. 13 shows a schematic view of a turbine portion formed by two inverted cones valid for winds from both directions.

FIG. 14 shows a schematic side view of a turbine retracted and supported at one of its ends.

FIG. 15 shows a schematic and side view of a retracted turbine supported by an extendable telescopic mast.

FIG. 16 shows a schematic and side view of the turbine of FIG. 15 extended. FIG. 17 shows a turbine applied to a building.

FIG. 18 shows a ship's propulsion and current generating turbine.

Preferred embodiment of the invention

FIG. 1 shows an embodiment with a turbine formed by a row of spherical caps or parachutes (1), and constituted by the fabric veil surfaces (2), with the openings or slits (4) and held by the cords (3) attached in turn to the cable (6), which passes through the caps (1) whose ends activate the electric generators (5) and these in turn are held by the posts (7), articulated (8) at their lower end to be able to fold it, which is done with the electric motors (9). The air outlet (10) through the openings (4) generates a torque and rotary movement to the entire turbine.

FIG. 2 shows the turbine of figure 1 with the row of spherical caps or parachutes (1) lowered by the effect of the wind, which acts in the opposite direction, it is formed by the sail surfaces of fabric (2), and held by the cords (3) attached in turn to the cable (6), which passes through the caps (1) whose ends activate the electric generators (5) and these in turn are held by the posts (7), with the joints (8) at their lower end to be able to lower it, which is done with the electric motors (9).

FIG. 3 shows a turbine formed by a row of spherical caps or parachutes (1d), consisting of the fabric sail surfaces (2), with openings or slits (4) and held by cords (3) which are applied to both sides to produce a bell and take advantage of the winds from both directions, in turn attached to the cable (6), which loosely passes through the caps (1) whose ends drive the electric generators (5) and these in turn are held by the posts (7). The air outlet through the openings (4) also generates a torque and rotary movement to the entire turbine.

FIG. 4 shows a turbine formed by a row of spherical caps or parachutes (1d), made up of the fabric sail surfaces (2), with openings or slits (4) and held by cords (3) which are applied to both sides to take advantage of the winds from both directions, in turn attached to the cable (6), which passes through the caps (1d) whose ends drive the electric generators (5) and these in turn are held by the posts (7). The air exit through the openings (4) also generates a torque and rotary movement to the entire turbine. In this case the caps (1d) are filled with air from the wind acting in the opposite direction.

FIG. 5 shows the cap (1d) used in figures 3 and 4, consisting of the fabrics (2), the openings or slits (4) and the central hole that allows the cap to move and inflate with the wind from both directions.

FIG. 6 shows a group of turbine rows with caps (1d) which are fixed at one end to poles or masts (7) and the other ends to a cable (26) which is wound on a drum (25) driven by the electric motor (9a). The arrows indicate the displacement with winds from both directions. The springs (29) provide the correct distance between the poles and the cable.

FIG. 7 shows a group of turbine rows with caps (1d) which are fixed at one end to a cable (28) between two posts (7) and the other to a cable (26) which is wound on a drum (25) driven by the electric motor (9a). The arrows indicate the displacement with winds from both directions. It is similar to the system of figure 6, but with perpendicular winds. Between both ends they can be adjusted for winds from all directions or senses. The springs (29) provide the correct distance for the turbine rows.

FIG. 8 shows a turbine formed by a row of spherical caps or parachutes (1), of different dimensions and held by cords (3) attached in turn to the cable (6), which passes through the caps (1) whose ends activate the electric generators (5) and these in turn are held by the posts (7). The air output through the openings also generates a torque and rotary movement to the entire turbine.

FIG. 9 shows a turbine formed by a row of spherical caps or parachutes (1), held by cords (3) to the dome of the adjacent cap and whose end drives the electric generator (5) on the other side of the post (7) that supports it. The air output through the openings also generates a torque and rotary motion to the entire turbine. The row of caps is automatically directed by the air stream.

FIG. 10 shows a turbine formed by a row of spherical caps or parachutes (1), held in place by their periphery by cables (36) and whose end drives the electric generator (5) on the other side of the post (7) that supports it. The air output through the openings also generates a torque and rotary motion to the entire turbine. The row of caps is automatically directed by the air stream.

FIG. 11 shows a turbine (1a) consisting of triangular sail surfaces of fabric (2a), held at their outermost vertices by cables (36) whose ends drive an electric generator (5) supported on and on the other side of the pole (7).

FIG. 12 shows the triangular sails of the turbine in Figure 11 in section.

FIG. 13 shows the turbine (1d) for operation with two-way winds, formed by two conical caps (2c) joined at their vertices and crossed by the cable (6) and the caps attached to it by the cords (3). The air exits through the openings (4).

FIG. 14 shows the turbine (1) with the caps retracted supported by the pole (7) and the arm (12) to which the electric generator (5) is attached on the other side of the pole.

FIG. 15 shows the turbine (1) with the caps retracted supported by a retracted extendable pole, with the electric generator (5) on the other side of the pole. The extendable pole carries a cap (13) and is supplied with pressurized air by means of the pump (17). At the lower end the extendable pole carries a ball joint that allows it to rotate and tilt due to the action of the wind. It may have a spring to keep it vertical when there is no wind.

FIG. 16 shows the turbine (1) with the caps retracted supported by an extendable pole, formed by tubular elements (15) and the stem (14) having the electric generator (5) on the other side of the pole. The extendable pole carries a cap (13) and is extended by the application of pressurized air through the pump (17). At the lower end the extendable pole carries a ball joint that allows it to rotate and tilt due to the action of the wind. It can have a spring to keep it vertical when there is no wind. This extendable type can be used for the poles of all the other figures used in this description.

FIG. 17 shows a building (31) to which the extensible turbine (1) is applied, supported by the cable (6), whose extension is helped by the inflatable and extensible conduit (13a) initially housed together with the generator inside the chamber (27a).

FIG. 18 shows a vessel (30) partially pulled by a turbine (1) which is retracted into a housing or chamber (27). Its use can be carried out automatically when it is armed and the wind direction is favorable. Any of the turbine models used in the report can be used.

Claims (15)

1. Wind energy capturing system, using turbines consisting of sails and cables, characterized in that it consists of a turbine or rows of turbines formed by one or more sail surfaces made of canvas, fabric or plastic sheet in the shape of a spherical cap, cone, cap or bell-shaped, attached to one or two masts by means of cables and peripheral cords at their ends, to the axis of the electric generator or mechanical element to be moved, and whose sail surfaces carry lateral openings through which the air exits at an inclined manner, creating a constant torque, a microprocessor controls the operation providing light and audible warnings and its safe operation by means of sensors, motors and actuators. 2. System according to claim 1, characterized in that the generators are placed between the turbines and the poles or on the other side of them. 3. System according to claim 1, characterized in that the rows of turbines between two posts consist of spherical caps or caps with fastening cords on both sides and a central hole so that it moves along the cable and allows it to flare with winds from both directions. 4. System according to claim 1, characterized in that the rows of turbines between two posts consist of pairs of conical elements or caps joined at their vertices. 5. System according to claim 5, characterized in that the other ends of the rows of turbines are fixed to a cable held between two posts. 6. System according to claim 1, characterized in that when only the turbines are attached at one end and have the assembly formed by the cables, frame and sails set back from the support point or post on which it rotates and is directed, on the opposite side with respect to the post it carries as a counterweight the electric generator covered by an aerodynamic casing. 7. System according to claim 1, characterized in that it adds caps formed by triangular sails. 8. System according to claim 1, characterized in that rpm multipliers are applied to large-scale systems between the turbines and the generators. 9. System according to claim 1, characterized in that the mechanical energy obtained can be used to compress air, storing it in flexible containers submerged in the sea at medium or great depth until the moment of use. 10. System according to claim 1, characterized in that it uses non-oxidizable materials based on steel, zinc, fiberglass or carbon and fabrics or canvases of natural or synthetic fibers reinforced with graphene. 11. System according to claim 1, characterized in that the protection from strong winds is carried out by electrically retracting the mast when a wind speed sensor detects a certain intensity, for this purpose the turbines that rotate or tilt around the support that is articulated are used. 12. System according to claim 1, characterized in that orange, red or green colors and strobe lights are applied to the system. 13. System according to claim 1, characterized in that the posts are extendable, formed by tubular elements (15) and a rod (14) that supports the turbine, the extendable post optionally carries a cap (13) and is extended by the application of pressurized air through the pump (17), at the lower end the extendable post carries a ball joint that allows it to rotate and tilt due to the action of the wind, it uses a spring to keep it vertical when there is no wind. 14. System according to claim 1, characterized in that the turbine is extensible and is added to the upper area of a building (31) whose extension is aided by the inflatable and extensible duct (13a) initially housed together with the generator inside a chamber (27a). 15. System according to claim 1, characterized in that the turbine is extendable and retracts into a housing or chamber (27) of a ship, operating automatically when the system is armed and the wind direction is favorable.