IT202100000656A1 - WAVE ENERGY CONVERSION DEVICE - Google Patents

Description

WAVE ENERGY CONVERSION DEVICE

DESCRIPTION OF THE INVENTION

The present invention belongs to the technical sector concerning wave motion energy conversion devices, in particular devices to be positioned near of a barrier where the waves of the sea go to break, for example in proximity? of a wall of a port or breakwater, or similar, or on the high seas near? of a platform.

AND? document WO2019/102449 is known which discloses a wave energy conversion device comprising: a float, in the shape of a half-hull of a boat; an arm connected at one end? to the float and anchored, by means of articulation means, to a wall; a hydraulic piston connected in one end? to said arm and in? the other extremity? to a wall structure, with said piston connected to a module comprising at least a hydraulic accumulator, a hydraulic motor, a generator and a hydraulic fluid tank.

The float performs oscillating movements along the axis of the arm of the float, that is? a rush up and a push down, with the movement of the waves.

The movement of the float compresses and decompresses the hydraulic piston which transmits the hydraulic fluid into the accumulator placed in the module; pressure is created in the accumulator.

The hydraulic motor converts compressed hydraulic flow into angular momentum on the generator shaft which produces electrical energy.

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After decompression, the fluid flows back into the water fluid tank, where it is then reused by the piston in the next wave, creating a closed circular system.

This device has a drawback deriving from its configuration, in that the hydraulic circuit is activated only following the lifting of the float, ie when the float compresses the hydraulic piston, negatively affecting the efficiency of the device.

Another drawback derives from the fact that the float ? associated with the module provided with different means for generating electricity, with all the drawbacks that ci? involves in terms of proper functioning, costs and positioning of the individual vehicles.

The prerogative of the invention? that of proposing a wave energy conversion device to be positioned both in the vicinity? of a barrier where the waves of the sea go to break both on the high seas in the vicinity? of a platform, made from known elements which, suitably combined with each other, allow the conversion of energy from wave motion, increasing its efficiency with respect to known solutions.

Another prerogative of the invention? that of proposing a device for converting energy from wave motion made in such a way as not to provide structures on the ground for housing the parts that make it up.

A further prerogative of the invention? that of proposing a wave motion energy conversion device made with the use of flotation units shaped in such a way as to facilitate their oscillation during the rising and falling movements of the waves.

Another prerogative of the invention? that of proposing an energy conversion device which, in addition to satisfying the above prerogatives, is

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shaped in such a way as to make its installation easy and quick, and that it is reliable, functional and of low cost compared to the advantages that are intended to be pursued.

The above features of the invention are obtained in accordance with the content of the claims.

The features of the invention will be highlighted below where ? described a preferred, but not exclusive, embodiment, with reference to the attached drawings in which:

- fig. 1 shows a schematic side view of a wave energy conversion device, object of the invention, in an inoperative position; - fig. 2 shows a schematic side view of the wave energy conversion device of FIG. 1, in a first operating position;

- fig. 3 shows a schematic side view of the wave energy conversion device of FIG. 1, in a second operating position.

With reference to the attached drawing tables, yes ? indicated by 1 a device for converting energy from wave motion comprising: a first fixed arm 2 comprising a first part 2a fixed, cantilevered, for example to the vertical wall P of a wall 3 of a port or breakwater, or the like, and a second part 2b, connected, in a single body or by means of known connection means, not illustrated, to said first part 2a, which develops downwards, for example perpendicular to the calm sea line, known as Still Water Line (SWL); at least a second arm 4, anchored by means of articulation means A to said first arm 2, such as to oscillate with respect to said articulation means A, in one direction F1 and in the opposite direction F2, and vice versa, with said second arm 4 comprising a first and a second portion 4a, 4b, for example aligned or arranged at an angle to each other, and, for example, of equal length; a first and a

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second floating group 5, 50, respectively connected to the ends? of the second arm 4; at least a first and a second electromagnetic actuator 6a, 6b, also known as linear alternator, of which the first actuator 6a is fixed at one end? to the first portion 4a of said second arm 4 and in the other end? to the second part 2b of the first arm 2, and the second actuator 6b fixed at one end? to the second portion 4b of said second arm 4 and in the other end? to the second part 2b of the first arm 2; electrical connection elements E, associated with each electromagnetic actuator, connected to known means C, for example the electric network, or an accumulation station, or external apparatus. It is specified that the connections of said first and second electromagnetic actuators 6a, 6b, to said first and second arms 2, 4, are of the hinge type; instead of said linear alternators, actuators of another type can be provided.

In a first embodiment, as illustrated in figures 1, 2, 3, each of said first and second floatation groups 5, 50 comprises: a first float 5a, 50a, having density? less than the density? of water, shaping for example a sphere (or other geometric shapes) full or empty internally; a second float 5b, 50b, located below said first float 5a, 50a, having dimensions no greater than the dimensions of the first float, empty internally, and affected, for example, by a series of through holes 9 also forming, for example, a sphere, or other geometric shape; a first connection means 7, for example an anchor cable, which connects, in a known way, said first and second float, 5a, 50a, 5b, 50b, so that they are aligned with respect to an axis Y (fig. 1 ); a second connecting means 8, interposed between said first and second means

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floating, 5a, 50a, 5b, 50b, to which one end? of the second arm 4.

In a second embodiment, the first float 5a, 50a has a density less than the density? of? water, such as a sphere (or other geometric shapes) full or empty internally, and the second float 5b, 50b, has density? smaller than water, it also conforms, for example, to a sphere (or other geometric shape) full or empty internally, and ? no larger than the size of the first float.

The wave motion energy conversion device is fixed, for example as illustrated in the attached figures, to the wall 3, with the first float 5a, 50a, protruding from the surface of the sea water and the second float 5b, 50b, immersed under the sea water surface; the device comes into operation following the wave motion of the sea water.

As schematized in figures 2, 3, the waves include a crest of wave C, C1, i.e. the lowest peak? high? wave, and a belly? wave V, V1, or the peak pi? bottom of the wave.

As known, sea waves are irregular movements produced by the wind on the surface of the water and the displacement of the waves is not ? due to a horizontal displacement of the molecules of? water, but? they are determined by vertical oscillations of the water molecules.

There? moving sideways? only the shape of the wave, the cio? the translation of the water due to the force of the wind.

actually? the water molecules perform circular oscillations around a fixed point, and when the wave passes, the water particles are lifted and moved a little? forward, then they are lowered and are moved a bit? backwards.

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Near the shore, where the depth? of the waters? modest, or close? of shallow waters, the circular trajectories of the particles become elliptical, or rather flattened.

When a wave encounters an obstacle, such as wall 3 for example, a wave is generated which propagates in the opposite direction to the incident one. because the two waves, the reflected one and the incident one, overlap each other, resulting in a state of wave agitation much more intense in the body of water in front of it. relevant in terms of wave height than would be the case for the incident wave alone.

As illustrated in figure 2, the crest of wave C causes the rotation of the second arm 4 in the direction F1; this rotation? generated by the Archimedean thrust on the first flotation group 5 and facilitated by the weight of the second flotation group 50.

In fact, when the first flotation group 5 is pushed upwards thanks to the Archimedean thrust supplied by the crest of the wave C to the first flotation group 5, the first electromagnetic actuator 6a is actuated along its movement axis in the direction of the arrow K: in this situation, as known, a variation of the magnetic field is generated inside the first electromagnetic actuator 6a which generates electric energy at its output. The upward displacement of the first flotation group 5 determines the consequent rotation of the second arm 4 in such a way that the second flotation group 50 is, in combination with the action of the force of gravity, pushed downwards to follow the belly V of the wave with consequent actuation of the second electromagnetic actuator 6b along its movement axis according to the direction of the arrow K1: in this situation a variation of the magnetic field is generated inside the second electromagnetic actuator 6b which generates electric energy in exit from it.

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As illustrated in figure 3, the crest of wave C1 causes the rotation of the second arm 4 in the direction F2; this rotation? generated by the Archimedean thrust on the second flotation group 50 and facilitated by the weight of the first flotation group 5.

In fact, when the wave breaks against the wall, a return wave is created, and in this situation when the second flotation group 50 is pushed upwards thanks to the Archimedean thrust provided by the crest of the wave C1 per second flotation group 50, the second electromagnetic actuator 6b is actuated along the movement axis according to the direction of the arrow W: in this situation a variation of the magnetic field is generated inside the second electromagnetic actuator 6b which generates electrical energy at the output from the same. The upward movement of the second floating group 50 consequently determines the rotation of the second arm 4 in the direction F2; it follows that the first flotation group 5 is, in combination with the action of the force of gravity, pushed downwards to follow the belly V1 of the wave with consequent activation of the first electromagnetic actuator 6a along its movement axis according to the direction of the arrow W1: in this situation a variation of the magnetic field is generated inside the first electromagnetic actuator 6a which generates electric energy at its output.

The wave motion energy conversion device object of the present invention has particularly advantageous technical-functional characteristics. Device 1 for how ? achieved allows to exploit the rotation of the second arm 4 both in the F1 direction (movement of the first float upwards and of the second float downwards) and in the F2 direction (movement of the second float upwards and of the first float downwards). bass), and vice versa, e

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not only in a single direction (ie only the upward movement of the float) as occurs in known systems.

The rotation of the second arm 4, following the lifting of the first flotation group 5 and the lowering of the second flotation group 50, and vice versa, determined by the wave motion of the marine waters, causes the actuation of the electromagnetic actuators 6a, 6b, in both movements, which allow the energy of the oscillating motion to be converted into electrical energy, positively affecting the total efficiency of the device.

The fact that each flotation unit is made up of a first and a second float means that the device can also be used in seas where the seabed can constitute an obstacle for its positioning.

In fact, in places where the seabed is low, the float groups are made in such a way that the first and second float are of different sizes, ie more? great the first float 5a, 50a, and pi? small the second 5b, 50b, to avoid cos? that the second float can, during the oscillation of each flotation group, impact with the seabed, with all the drawbacks that this entails? would entail.

Using device 1 near of a wall of a port, or a breakwater, or the like, provides that the first float of each flotation unit 5a, 50a, is made from a sphere with density? less than the density? of sea water and that the second float 5b, 50b is made from an internally empty sphere with through holes 9.

This conformation is advantageous because, from experimental tests, yes? verified that the shape of the second float 5b, 50b, ? such that, during both the incident wave and the reflected wave generated in the vicinity? of the wall, the oscillation movement of the first or second is facilitated

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flotation group 5, 50, and, consequently, the rotation of the second arm 4 in directions F1 or F2, and the actuation of each electromagnetic actuator along the relative movement axes.

Furthermore, the device 1, due to its conformation, can advantageously also be used on the high seas, for example near? of oil platforms. The device, in this situation, ? made with flotation groups in which both the first and second float of each flotation group have a density? less than the density? sea water, both conforming spheres (or other geometric shapes) full or empty internally; the device with such floating groups will come? fixed to the structure of the platform to exploit, as previously described, the wave motion present in the vicinity? of the same. In one embodiment, not shown, the device in question can be provided with two second arms 4 articulated, for example cross-shaped, to the first arm 2, and provided with as many electromagnetic actuators and flotation units; this solution makes it possible to further increase the efficiency of the device by making the most of the wave motion deriving from "progressive" waves (waves that propagate along one direction), "stationary" waves (waves in which the phase lines do not move in space at time) and "translation" waves (waves in which there is also mass transport in the direction of propagation, typical of breakers or waves generated by impulsive phenomena.

The first and second portions 4a, 4b, of the second arm 4, in an embodiment not shown, can be of adjustable length, for example in a telescopic way.

This adjustment of said length pu? take place manually or automatically, by means of suitable devices, to optimally adjust the position of the respective first and second flotation groups 5, 50, associated

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at the ends? of the respective said first and second portions 4a, 4b, on the basis of the variation of the distance between the crest C and the belly V of the wave during the wave motion.

A further advantage of the device comes from the fact that its simplicity? constructive ? such that its maintenance is limited and whose costs are low compared to the advantages listed above.

However, it is understood that what has been said above has an exemplary and non-limiting value, therefore any modifications are considered as of now to fall within the same protective scope defined by the claims set out below.

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Claims (10)

1. Wave energy conversion device that generates a plurality of of crests of wave C and troughs of wave V, with said device comprising: a first fixed arm 2 cantilevered to a wall of a port or breakwater, or similar, or to the structure of a platform, to develop downwards above calm sea line (SWL); at least a second arm 4, anchored by means of articulation means A to said first arm 2, comprising a first and second portion 4a, 4b, with said second arm 4 such as to oscillate with respect to said articulation means A in a direction F1 and in the in the opposite direction F2, and vice versa; at least a first and a second flotation group 5, 50, respectively fixed to the relative ends? of the aforementioned second arm 4 to be partially immersed in sea water and interacting with the latter according to said wave motion to allow the oscillation of said at least second arm 4; at least a first and a second actuator 6a, 6b, each fixed at one end? to said first arm 2 and in? the other extremity? correspondingly to said first or second portion 4a, 4b, of said second arm 4 to be actuated by the oscillation of said second arm 4 in the first direction and in the second opposite direction, and vice versa, along respective movement axes according to the directions of the corresponding arrows K, K1, or W, W1, as a function of said sea water wave motion to generate electrical energy; electrical connection elements E associated with each first and second actuator, connected to means C such as an electrical network, or an accumulation station, or external apparatus. 2. Conversion device according to claim 1 characterized in that each of said first and second float groups 5, 50 comprises: a first float 5a, 50a, having density? less than the density? of water; a second float 5b, 50b, located below said first ??? ? float 5a, 50a; a first connecting means 7 connecting said first and second floats, 5a, 50a, 5b, 50b, in such a way that they are aligned with respect to an axis Y; a second connection means 8, placed between said first and second float, 5a, 50a, 5b, 50b, to which the corresponding end is fixed? of said first or second portion 4a, 4b, of said second arm 4. 3. Conversion device according to claim 1 characterized in that said first and second actuators 6a, 6b are linear alternators. 4. Conversion device according to claim 1 characterized in that said first arm 2 comprises a first part 2a cantilevered to a wall of a port or breakwater, or the like, or to the structure of a platform, and a second part 2b, connected, in a single body or by means of connection means, to said first part 2a, which develops downwards perpendicularly to the calm sea line (SWL). 5. Conversion device according to claim 1 or 2 characterized in that said first and second portions 4a, 4b are of equal length. 6. Conversion device according to claim 1 or 2 characterized in that said first and second portions 4a, 4b are aligned. 7. Conversion device according to claim 1 or 2 characterized in that each of said first and second portions 4a, 4b, of said second arm 4 ? of adjustable length, to adjust the position of the respective first and second flotation groups 5, 50, associated with the ends? of the respective said first and second portions 4a, 4b, on the basis of the variation of the distance between the crest C and the belly V of the wave during the wave motion. 8. Conversion device according to claim 2 characterized in that said second float 5b, 50b, ? of dimensions not exceeding the dimensions of the first float 5a, 50a. ??? ? 9. Conversion device according to claim 2 or 8 characterized in that said second float 5b, 50b, ? internally empty and provided with a series of through holes 9. 10. Conversion device according to any one of the preceding claims, characterized in that each of said first and second floats 5a, 50a, 5b, 50b, forms a sphere that is full or empty internally.