WO2012072830A1

WO2012072830A1 - Electrogenerator using tidal energy

Info

Publication number: WO2012072830A1
Application number: PCT/ES2010/070785
Authority: WO
Inventors: Domingo Bengoa Saez De Cortazar
Original assignee: Domingo Bengoa Saez De Cortazar
Priority date: 2010-11-29
Filing date: 2010-11-29
Publication date: 2012-06-07

Abstract

The invention relates to a high performance device that takes advantage of tidal energy. Said device includes a base (2); side faces (3) having gaps (11); a rotor (4) having blades (5); a first diversion means (6) for dividing a first water current into a first lower stream (9) directed toward the blades (5) arranged below the axis of the rotor (4), and a second upper stream (7) directed above the rotor (4); a second diversion means (10) for directing the first stream (9) from the blades (5) toward the gaps (11); a platform (22) for directing the second stream (7) toward the outside; a selection means (23) for guiding the second stream (7) over the rotor (4), as well as guiding the second current, along with the second diversion means (10) for activating the blades (5) in the same direction as said second stream (7).

Description

ELECTROGENERATOR FROM MAREMOTRIZ ENERGY

D E S C R I P C I Ó N

OBJECT OF THE INVENTION

The present invention can be included in the technical field of harnessing tidal energy to obtain electrical energy.

Specifically, the object of the invention relates to an electrogenerator from tidal energy.

BACKGROUND OF THE INVENTION

Some of the known devices for harnessing wave energy are arranged on the surface of the sea and incorporate pistons that transform the variation of the height of the waves into electrical energy.

Other known devices comprise an axis provided with blades that receive the thrust of the waves and transmit it to the axis, causing the rotation of said axis connected to an alternator. Such devices may be arranged both on the surface and on the seabed.

The technical problem posed by these devices consists of reduced performance due mainly to the complexity of interconnected mechanical elements, which generates high mechanical losses; and the use of wave energy only in a sense of movement. DESCRIPTION OF THE INVENTION

The present invention saves the aforementioned drawbacks by using an electrogenerator from tidal energy with improved performance, due, first, to a simple construction, with a reduced number of moving elements and, therefore, with a decrease of the mechanical losses and, on the other hand, that it is configured to take advantage of the kinetic energy of the waves both in its movement from sea to coast and in the opposite direction.

The electrogenerator according to the invention comprises a base adapted to keep the wind turbine at the bottom of the sea, which comprises a first front end, a second rear end and two third side ends. Preferably, the base is constructed of a material substantially denser than seawater, such as concrete. Altenatively or additionally, the base may be provided with fasteners to the seabed. The invention additionally incorporates two lateral walls arranged parallel to the third ends, extending perpendicularly to the base between the first end and the second end, as well as having holes in the vicinity of the second end. An impeller is arranged parallel to the base, above said base, between the third ends and held by the walls at a distance substantially separated from the first end and the second end, to roll along its longitudinal axis, said impeller provided with arranged vanes parallel to said axis. The invention further comprises first bypass means, arranged between the first end and the impeller, to divide a first stream of water, directed towards the electrogenator, into a first lower portion and a second upper portion. The first portion runs by driving the blades located below the axis of the impeller. The first portion leaves the electrogenerator through the holes in the walls. The second portion runs over the impeller blades. The invention further comprises second bypass means, arranged between the impeller and the second end, to derive the first portion from the blades located below the axis of the impeller towards the gaps of the walls. Additionally, a platform arranged on the second bypass means is included to derive the second portion towards the outside of the electrogenerator once the impeller has been exceeded and to drive a second stream of water incident on the electrogenerator over the axis of the impeller. in the opposite direction to the first current.

It is envisaged the existence of selection means to selectively drive the second portion of the first stream over the blades above the axis of the impeller, without actuating said blades, as well as driving the second stream, in cooperation with the platform, towards said blades, to activate them.

The operation of the electrogenerator is described below: When a first current hits the first end of the electrogenerator, is divided by the first bypass means in a first portion, which runs below the axis and drives the lower blades, rotating the impeller, and in a second portion that is driven by the selection means above the impeller, preventing said second portion from actuating said impeller disadvantageously in a direction opposite to that of the first portion. The first portion is driven by the second bypass means to leave the electrogenerator through the gaps of the walls, while the second portion, once the impeller is exceeded, leaves the electrogenerator driven by the platform towards the second end. The impeller is connected to an alternator to obtain electrical energy.

Subsequently, a second current strikes the second end, that is, in the opposite direction as the first current. Said second current is conducted on the platform and by the selection means for operating the blades located above the axis of the impeller in the same direction as recently the second portion of the first current, also taking advantage of the kinetic energy of the second current, and not only of the first current, to operate the impeller and obtain electrical energy.

The invention additionally incorporates a flywheel inertia integral to the impeller, to produce greater continuity in the movement of the impeller. Optionally, the invention may additionally include an accumulator to initiate the impeller rotation (for example, through the flywheel), in situations where the kinetic energy of the swell is not sufficient to drive said impeller. Both the steering wheel, as well as the alternator, and, where appropriate, the accumulator, are housed in airtight containers arranged on the seabed to insulate said alternator, accumulator and flywheel from the water. Said vessels have a fusiform shape for better cutting of the waves and have a height higher than that of the waves or, preferably, airtight lids in their upper part to prevent the entry of water.

DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of practical implementation thereof, a set of drawings is attached as an integral part of said description. where, for illustrative and non-limiting purposes, the following has been represented:

Figure 1.- It shows a view of the invention from the first end, where the blades and the sealed containers have not been represented.

Figure 2.- Shows a view of the invention from the second end, where neither the blades nor the sealed containers have been represented.

Figure 3.- Shows a side view of the invention, where the airtight containers have not been represented.

Figure 4.- Shows a plan view of the invention.

Figure 5.- Shows a side view of the invention according to a section given by plane VV of figure 4. PREFERRED EMBODIMENT OF THE INVENTION

A detailed description of a preferred embodiment of the invention is presented below with the help of the attached figures 1 to 5.

As can be seen in Figure 1, the electrogenerator of the invention comprises a concrete base (2) perched at the bottom of the sea, comprising a first first end (35), a second rear end (36) and two third third ends. (37) lateral.

Figures 1 and 2 show that the invention further incorporates two lateral walls (3) arranged parallel along the third ends (37), extending perpendicularly to the base (2) between the first end (35) and the second end ( 36), as well as having holes (11) near the second end (36).

An impeller (4) is arranged parallel to the base (2), above said base (2), between the third ends (37) and held by the walls (3) at a distance substantially separated from the first end (35) and of the second end (36), for rolling along its longitudinal axis, said impeller (4) provided with blades (5) arranged parallel to said axis.

In Figures 1, 2, 3 and 5 it is shown that the invention additionally comprises first bypass means (6), arranged between the first end (35) and the impeller (4), to divide a first stream of water, directed towards the first end (35) of the electrogenerator, in a first lower portion (9) and a second upper portion (7). The first portion (9) runs by driving the blades (5) located below the axis of the impeller (4). The impeller (4) is connected to an alternator (12) to obtain electric power. The first portion (9) leaves the electrogenerator through the holes (11) of the walls (3). The second portion (7) runs over the impeller (4), without operating the blades (5).

The invention further comprises second bypass means (10), arranged between the impeller (4) and the second end (36), to derive the first portion (9) from the vanes (5) located below the axis of the impeller towards the gaps (11) of the walls (3).

Additionally, a platform (22) arranged on the second bypass means (10) is included to derive the second portion (7) towards the outside of the electrogenerator once the impeller (4) is exceeded and lead to the blades (5) located above the impeller axis (4) a second stream of water incident on the electrogenerator in the opposite direction to the first current.

The existence of selection means (23) articulated in the upper part of the walls (3) is provided to selectively conduct the second portion (7) of the first current over the blades (5) located by on the axis of the impeller (4), without operating said blades (5), as well as driving the second current, in cooperation with the platform (22), towards said blades (5), to drive them.

The first bypass means (6) comprise a first lower plate (15) and a first upper plate (14), joined along a first edge (16) forming an angle, arranged between the first end (35) and the impeller (4 ) perpendicular to the walls (3), where the first edge (16) points outwards and is parallel to the axis of the impeller (4). Thus, the first current strikes the first edge (16) and is divided into a first lower portion (9) and a second upper portion (7). The first portion (9) is driven by the first lower plate (15) to drive the blades (5) located below the axis of the impeller, while the second portion (7) is driven by the first upper plate (14) by above the impeller (4) without actuating said impeller (4).

The second bypass means (10) comprise two second plates (17, 18) in the form of right triangles, comprising both first leg (19), second leg (20) and hypotenuse (21). Said second plates (17, 18) are supported perpendicularly on the base (2) according to the first legs (19), and are joined at an angle according to the second legs (20) defining a second edge (38), which points towards the impeller (4).

The third plate (22) is supported on the hypotenuses (21) of the second plates (17, 18) covering said second plates (17, 18) along the entire distance between the walls (3).

The first portion (9), after actuating the vanes (5) located below the axis of the impeller (4), strikes the second edge (38) and is deflected by the second plates (17, 18) towards the first end ( 35) and the second end (36), leaving the electrogenerator through the holes (11) of the walls (3). The second portion (7), once it passes the impeller (4), descends on the platform (22) and leaves the electrogenerator at the second end (36).

The selection means (23) comprise an angle-shaped profile (24), pivotable with respect to the walls (3) according to an articulation (27) between a first position and a second position. In the first position, the selection means (23) are arranged above the first upper plate (14), while in the second position said means of Selection (23) are arranged above the platform (22). First stop means (31) serve to fix the selection means (23) in the first position, providing a distance with the first upper plate (14) for the passage of the second portion (7) of the first current, while that a second stop means (32) serve to fix the selection means (23) in the second position, providing a distance with the platform (22) for the passage of the second current.

The invention further comprises blades (40) disposed externally to the first end (35) and the second end (36), said blades (40) in solidarity with the selection means (23), to be driven by swell that hits from the outside of the electrogenerator, cooperating with the profile (24) in the pivoting of said selection means (23). The second portion (7) of the first current runs along the first top plate (14) and pushes the profile (24) by pivoting it with respect to the walls (3) according to the joint (27) from the first position to the second position, to drive said second portion (7) to the platform (22) above the impeller (4) without operating said impeller (4).

Subsequently, the second current runs through the third plate (22) and pushes the profile (24) by pivoting it with respect to the walls (3) according to the joint (27) between the second position and the first position, to make said second current affect by actuating the vanes (5) located above the axis of the impeller (4) in the same direction as before the second portion (7) of the first current.

The invention additionally incorporates a flywheel (13) integral with the impeller (4), to produce greater continuity in the movement of said impeller (4). The invention additionally includes an accumulator to initiate the rotation of the impeller (4) for example, through the flywheel (13), in situations where the kinetic energy of the swell is not sufficient to drive said impeller (4).

Figure 4 shows that both the flywheel (13), and the alternator (12), and, where appropriate, the accumulator, are housed in airtight containers (39) arranged on the seabed to insulate said water alternator (12), accumulator and flywheel (13). Said containers (39) have a fusiform shape for better cutting of the waves and have a height greater than that of the waves or, preferably, some covers (not shown) sealed in their upper part to prevent the entry of water.

Claims

R E I V I N D I C A C I O N E S - Electrogenerator from tidal energy, characterized in that it comprises:

5 - a base (2) adapted to keep the wind turbine at the bottom of the sea, equipped with a first end (35), a second end (36) and third lateral ends (37);

- lateral walls (3) arranged parallel along the third ends (37), extending perpendicularly to the base 0 (2) between the first end (35) and the second end (36), as well as having holes ( 11) in the vicinity of the second end (36);

- an impeller (4) arranged parallel to the base (2), above said base (2), between the third ends (37) and held by the walls (3) at a distance substantially separated from the first end (35) and of the second end (36), for rolling along its longitudinal axis, said impeller (4) provided with blades (5) arranged parallel to said axis;

- first bypass means (6), arranged between the first end (35) and the impeller (4), to divide a first stream of water, directed towards the first end (35), into a lower first portion (9) or directed towards the vanes (5) arranged below the axis of the impeller (5), and a second upper portion (7) directed above the impeller (4);

- second bypass means (10), arranged between the impeller (4) and the second end (36) to derive the first portion (9) from the vanes (5) located below the axis of the impeller (5) towards the 5 exterior of the electrogenerator through the gaps (11);

- a platform (22) arranged on the second bypass means, to derive the second portion (7) towards the outside of the electrogenerator once the impeller (4) is exceeded and to lead towards the blades (5) arranged above the axis of the impeller (4) a second stream of 0 water incident on the electrogenerator in the opposite direction to the first stream;

- selection means (23) arranged articulated at the top of the walls (3) to selectively drive the second portion (7) of the first stream over the blades (5) located above the axis of the impeller (4), without operating said blades (5), as well as driving the second current, in cooperation with the second bypass means (10), to drive said vanes (5) arranged above the axis of the impeller (4) in the same sense as said second portion (7);

- an alternator (12) connected to the impeller (4) to transform the rotation of said impeller (4) into electrical energy;

- a flywheel (13) integral with the impeller (4), to produce greater continuity in the movement of said impeller (4); Y

- airtight containers (39) of fusiform shape arranged on the seabed to house the alternator (12) and the flywheel (13) and protect said alternator (12) and said flywheel (13) from the water.

2. - Electrogenerator from tidal energy, according to claim 1, characterized in that it additionally comprises an accumulator housed in a container (39) to initiate actuation of the impeller (4) in situations where tidal energy is not sufficient for actuate said impeller (4).

3. - Electrogenerator from tidal energy, according to claim 1, characterized in that it additionally comprises blades (40) arranged externally to the first end (35) and the second end (36), said blades (40) in solidarity with the selection means (23), to be driven by waves that impact from outside the electrogenerator, cooperating with the profile (24) in the pivoting of said selection means (23).

4. - Electro-generator from tidal energy, according to claim 1, characterized in that the first bypass means (6) comprise a first lower plate (15) and a first upper plate (14), joined according to a first edge (16) forming an angle, arranged between the first end (35) and the impeller (4) perpendicular to the walls (3), where the first edge (16) points outwards and is parallel to the axis of the impeller (4) ), to divide the first current into a first lower portion (9) directed towards the vanes (5) arranged below the axis of the impeller by the first lower plate (15) and a second upper portion (7) directed above the impeller (4) by the first top plate (14).

5. - Electrogenerator from tidal energy, according to claim 1, characterized in that the second bypass means (10) comprise two second plates (17, 18) in the form of right triangles, with each first leg (19), second leg (20) and hypotenuse (21), said second plates (17, 18) are perpendicularly supported on the base (2) according to the first legs (19), and are angled together according to the second legs (20) defining a second edge (38), which points towards the impeller (4) to divide the first portion (9) of the first current and deflect it by means of the second plates towards the holes (11).

6. - Electrogenerator from tidal energy, according to claim 1, characterized in that the selection means (23) comprise:

- an angle-shaped profile (24), pivotable with respect to the walls (3) according to an articulation (27) between a first position and a second position, where in the first position, the selection means (23) are arranged by on top of the first top plate (14), while that in the second position said selection means (23) are arranged above the platform (22);

- first stop means (31) for fixing the selection means (23) in the first position, providing a distance with the

5 first top plate (14) for the passage of the second portion (7) of the first current;

- a second stop means (32) for fixing the selection means (23) in the second position, providing a distance with the platform (22) for the passage of the second current; Y

lo - blades (40) disposed externally to the first end (35) and to the second end (36), to be driven by swell that strikes from outside the electrogenerator, cooperating with the profile (24) in the pivoting of said means of selection (23).