ES1208786U - Wind and maritime fluvial water collection system (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Wind and maritime fluvial water collection system using axial or radial blades mounted on floats anchored to the seabed, comprising one or more floats attached to or anchored to one or more concrete blocks at the bottom of the sea by means of one or more more chains or cables, one or more radial blade turbines, electric generators, air compressors or hydraulic pumps, the floats are linked together with chains, cables or ropes.

Description

WIND ENERGY AND MARITIME FLUVIAL ENTRY SYSTEM

FIELD OF THE INVENTION.- In mega wind and maritime collector systems

uviales, which generate a large amount of electricity for homes, agriculture, desalination of seawater, water elevation, feedback of the current to the electricity grid, obtaining hydrogen by electrolysis of water and storage of pressurized air in bags at sea at great depth

STATE OF THE TECHNIQUE.- Current wind energy systems need high technologies, high costs, high altitude placement and high winds to achieve high yields, depending on difficult wind conditions. They are difficult to control, complex, you need to direct them to the wind, they visually pollute the landscape and kill the birds. The energy is more expensive than with conventional systems. The present invention eliminates said drawbacks by providing a simple, useful and economical system, using rotating blade turbines formed by rigid or flexible sails or plates.

OBJECTIVE OF THE INVENTION AND ADVANTAGES. Providing a high energy source with an effective cost independent of the optimal wind conditions, does not need an optimal or high situation. Provide a simple and high performance system, does not kill birds, does not pollute, does not produce noise, vibration, radio interference or visual pollution.

Use sensors, which when using tarpaulins, cables or chains can be built large, difficult to overcome and without competition with current rotating devices.

Use winds and water currents of all the senses low and high intensity, obtaining a reduced cost of Kw / h. Take advantage of the breezes in addition to the powerful and less turbulent winds in the sea.

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

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

DESCRIPTION OF THE INVENTION.- The wind and maritime fluvial energy capture system of the invention consists of one or more floats attached or anchored to concrete blocks at the bottom of the sea by means of one or more chains or cables, the

which by the action of the wind and the current of water are constantly directed as vanes, said floats support one or more turbines of blades or radial blades on cylindrical bodies or ogival floats of radial blades or turbines constituted by multiple villic surfaces whose axes they operate electric generators, air compressors or hydraulic pumps, the floats are linked together with chains, cables or ropes. The turbines can carry ramps or deflector plates inclined in the front area between the float and some sections or extensions of the axle support towers, deflecting the air that flows through the lower area towards the upper half of the turbines, thereby It tends to double the performance of each of the turbines. Can use

10 wind concentrators and / or suckers to drive the turbines. When the separation between the turbines is small, it is not necessary to place the deflector plates of the second and subsequent turbines.

A variant uses semi-submerged or partially submerged turbines and flexible and floating blades, which run through the lower area under water and are

15 flex, opposing low resistance in the lower half of it. The turbines can carry a cylindrical shaft that acts as a shaft and float, totally or partially, and the use of floats may not be necessary.

The radial blade turbines are placed in parallel supported from their axes between two floats and fastened between two rope chains or cables. The separation between said

20 cable chains, etc. it is achieved using inclined side deflector plates which tend to separate them. This separation is also achieved using inclined floats, which are displaced outwards by the flow of water and air, or with two metal bars or beams, one in the front area and one in the rear of each turbine assembly. Axial turbines can be used in deep currents.

25 When the blade turbines are of short length, only one chain can be used in the central zone of turbines divided into two halves or in pairs of turbines. The speed of rotation of the turbines is greater the smaller the radius of the same. Blade turbines may have a cylindrical body that acts as an axis, or may not use a shaft, instead four wires or ropes are placed between the ends of four arms

30 or blades and an N, Z or zigzag-shaped canvas is intertwined, radially creating two V-shaped cavities, one concave with respect to the wind and another concave, generating a pair of sinusoidal rotation. RPM multipliers can be applied between the turbine and the generators or multiple pole pairs 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 its use.

Non-oxidizable materials based on steel, fiberglass or

5 carbon and for the sails of canvas or polyester synthetic fabric, kevlar or can also be made of sheet of flexible thermoplastic material and can be reinforced with a mesh. The fabric of the candles can be made with cords or reinforcement mesh incorporated or integrated in it. The whole system can be colored orange or red.

The protection of strong winds when using sails is done a) Using

10 flexible radial arms that when flexing reduce the surface exposed by the sails, b) Using flexible hooks that release the vertices or edges of at least one candle, c) Using quick-release hook-clamps, d) Electrically retracting the arms radial or reducing the surface of at least one sail by pulling a cable or cord when a wind speed sensor detects a certain intensity, e) Turning and knocking down

15 the lateral support posts, f) By releasing at least one corner or edge by means of fusible cords, g) By automatically retracting the tiltable radial arms or h) Using elastic cords.

The addressing system can be applied to the wind turbine systems of current blades that are used off shore, in this case it is not necessary the

20 direction to the wind carried by current wind turbines. BRIEF DESCRIPTION OF THE DRAWINGS. Figure 1 shows a schematic, side and partial view of a system

sensor of the invention. Figure 2 shows a schematic, side and partial view of a variant of the sensor system of the invention. Figures 3, 4 and 5 show schematic, plan and partial views of variants of systems of the invention. Figures 6 through 10 and 12 show schematic and cross-sectional views of turbines with shaft and blade variants. 30 Figure 11 shows a schematic view of a turbine portion,

sectioned and partial with a floating drum as an axis. MORE DETAILED DESCRIPTION OF THE INVENTION Figure 1 shows an embodiment of the invention, with turbines (1)

of radial blades (2) mounted on the cylindrical bodies (17), whose axes actuate

electric generators (6), air compressors or hydraulic pumps, on one or more floats (3) attached to a concrete block (9) at the bottom of the sea through the chain (8). The chain carries rotating links with each other (19). The floats are joined together by chains (7), cables or ropes and 5 are constantly routed by wind vanes. Inclined baffle plates (4) in the front area between the float and some sections or extensions (5a) of the support towers (5) of the turbine shafts, deflect the air that flows through the lower area towards the upper half of the turbine, as shown by the arrows, which tends to double the performance. The electrical cables towards the coast, or the conduits of

10 pumping air or water to it. A vessel (25) comparatively shows the possible large size of the collector. Figure 2 shows turbines (la) of curved radial blades (2a) that can be flexible, mounted on the cylindrical bodies (17), whose axes held by the masts

or support towers (5), drive electric generators (6), air compressors or pumps

15 hydraulic, on one or more floats (3) attached to a concrete block (9) at the bottom of the sea through the chain (8). The chain carries rotating links with each other (19). The floats are joined together by chains (7), cables or ropes and by the action of the wind they are constantly addressed as vanes. Add a turbine variant (Ib) which has its lower half submerged in water and uses flexible blades and

20 floating (2b) which extend in the upper area or half and rise and attach to the cylindrical body (17) of the turbine in the lower half reducing the resistance of the turbine, thereby increasing the torque. Electrical cables or conduits through which air or water is pumped to the coast are not shown. The size of the floats depends on the type of turbine, with the semi-submerged turbines the floats are less

25 necessary, the cylindrical body of the turbine can act as a float. A vessel (25) comparatively shows the possible large size of the collector. Figure 3 shows turbines (Ib) of curved radial blades (2b), which can be flexible and float, whose axes held by the support towers or columns (5), drive the electric generators (6), air compressors or hydraulic pumps, on one or more

30 floats (3) attached to a concrete block (9) at the bottom of the sea through the chains (8). The chain carries swivels with each other (19). The floats are joined together by chains (7), cables or ropes and by the action of the wind they are constantly addressed as vanes. The turbine (Ib) can have its lower half submerged in water and use flexible and floating blades (2b) which extend in the upper zone or half and rise and attach to the cylindrical body of the turbine in the lower half reducing the resistance of this, which increases the torque. Their shovels or sails are held at their ends by the radial arms (13). The shaft (10) is a metal bar and can be a chain or cable that provides great length and flexibility. The cylindrical body of the turbine can act as a float. The separation of the chains occurs with the baffles (11) or through the front metal bars (12) and the rear ones (12a). Electrical cables or conduits through which air or water is pumped to the coast are not shown. A vessel (25) comparatively shows the possible large size of the collector.

Figure 4 shows a complete sensor formed by a row of turbines (Ib), whose axes are supported by the support towers or columns fixed on the floats (3). They use the chains (8) of subjection to the concrete blocks (9) at the bottom of the sea allowing the direction of the collector with respect to wind.

Figure 5 shows turbines (1b) of curved radial blades (2b), which can be flexible, whose axes drive electric generators (6), air compressors or hydraulic pumps. It is similar to the previous one, differentiating itself in that a single chain (8) is used to hold the concrete blocks (9) at the bottom of the sea, rotating links between them (19) facilitate the movement of the sensor. The floats (3a) are placed inclined to help the separation between the chains. The turbines (Ib) can have its lower half submerged in water and uses flexible and floating blades (2b) which extend in the upper zone or half and rise and attach to the cylindrical body of the turbine in the lower half reducing the resistance of this, which increases the torque. The axis

(10)

It is a metal bar and can be a chain or cable that provide great length and flexibility, its ends rest on the towers or columns (5). Electrical cables or conduits through which air or water is pumped to the coast are not shown. A vessel (25) comparatively shows the large size of the collector.

Figure 6 shows a turbine (1) with the radial blades (2b) attached to the tubular shaft

(14)

with some straps (29). Figure 7 shows a turbine (1) with the tangential blades (2c) attached to the tubular shaft (14) with straps (29). Figure 8 shows a turbine (1) with the tangential blades (2c) fixedly attached to the tubular shaft (14) which carries inside a rope or cable (18).

Figure 9 shows a turbine (1) with the tangential blades (2d) attached and rotating to the tubular shaft (14) with its hinged and tiltable ends (15).

Figure 10 shows a turbine (1) with the floating and flexible curved blades (2a) attached to the shaft (14), which can be a hollow drum or cylinder. The lower area is submerged in the water and by flotation it is attached to the shaft body or, if applicable, to the drum that supports them, reducing their resistance.

5 Figure 11 shows the drum-shaft (17) of a turbine whose blades (2f) internally carry a steel strip (16). The figure only shows a blade, but can be four to six.

Figure 12 shows a shaftless turbine, formed by four ropes or cables (18) whose ends are fixed between the ends of four radial arms of two half shafts 10 fixed to the floats, such as the radial arms (13) of Figure 3. The blades are created by interlacing a canvas (2z) in the form of Z or N between said cables and fixing the extreme edges. Since this system has null or dead points in which no torque is produced, they must be placed in two or more groups rotated 90 ° between them. The ends of the canvas are topped in a bucket (18a) that surrounds and is attached to two of the cables (18). The

15 canvases can be fastened with brooches or tweezers.

Claims (20)

1. Wind and maritime river energy capture system using axial turbines or of radial blades mounted on floats anchored at the bottom of the sea, comprising one or more floats attached or anchored to one or more concrete blocks at the bottom of the sea by means of one or more chains or cables, one or more turbines of radial blades, Electric generators, air compressors or hydraulic pumps, the floats are linked together with chains, cables or ropes.

2.

System according to claim 1, characterized in that the radial blade turbines have ramps or deflector plates inclined in the front area between the float and some sections or extensions (5a) of the supports (5) of the turbine shafts, deflect the air which runs through the lower zone towards the upper half of the turbines.

3.

System according to claim 1, characterized in that the radial blade turbines carry flexible and floating blades in the submerged zone, which run through the lower area under water and flex and rise towards the axis of the turbine, offering low resistance to its rotation in the lower half of it.

Four.

System according to claim 1, characterized in that the radial blade turbines carry a drum or cylindrical body that acts as a shaft and float.

5.

 System according to claim 1, characterized in that the radial blade turbines are placed in parallel supported from their axes between two floats and fastened between two strings or cables, the separation between said chains, ropes or cables, is achieved using inclined side deflector plates ( 11) and the action of the wind or inclined floats (3a) and the action of the water and wind current and two metal bars or beams, one in the front area (12) and one in the rear (12) of each set of turbines.

6.

System according to claim 1, characterized by using only one chain in the central zone of turbines divided into two halves or in pairs of turbines

7.

System according to claim 1, characterized in that the radial blade turbines (Ib) have the lower half submerged in the water and use flexible and floating vanes (2b) which extend in the upper zone or half and rise and attach to the cylindrical body of the turbine in the lower half reducing its resistance.

8.

System according to claim 1, characterized in that the blades or sails of the turbines are held at their ends by radial arms (13).

9.

System according to claim 1, characterized in that the axis (10) of the turbine is a metal bar, a chain or cable and the separation of the chains occurs with the

baffles (11) or by means of the front metal bars or beams (12) and the rear ones (12a).

10.

System according to claim 1, characterized in that the turbines carry radial blades (2b) connected to tubular shafts (14) with strips (9).

eleven.

System according to claim 1, characterized in that the turbines carry tangential blades (2c) attached to the tubular shafts (14) with strips (9).

12.

 System according to claim 1, characterized in that the turbines carry tangential blades (2c) fixedly attached to the tubular shafts (14) which carry inside a rope or cable (18).

13.

System according to claim 1, characterized in that the turbines carry tangential blades (2d) joined and rotatable to the tubular shafts (14) with their hinged and tiltable ends (15).

14.

System according to claim 1, characterized in that the turbines carry floating and flexible curved blades (2a) attached to the shafts (14), the lower area is submerged in the water and by flotation is attached to the shaft body or to the drum that supports them .

fifteen.

System according to claim 1, characterized in that the turbines have a shaft (17) whose blades (2f) internally carry a steel strip (16).

16.

System according to claim 8, characterized in that the protection of strong winds from the turbines is achieved using flexible radial blades or arms or elastic cords.

17.

System according to claim 8, characterized in that the protection of strong winds from the turbines is achieved by quick-release hook-clamps or flexible hooks by releasing the edges of some of the sails.

18.

 System according to claim 8, characterized in that the protection of strong winds from the turbines is achieved by electrically retracting the radial arms or reducing the surface of at least one sail by pulling a cable or cord when a wind speed sensor detects a certain intensity.

19.

 System according to claim 1, characterized by applying rpm multipliers between the turbine and the generators.

twenty.

System according to claim 1, characterized by using multi-pole electric generators.