FR3010422A1 - IMBRITIC AND MODULAR IMMERSION DEVICE FOR DEFROSTING AND CONTROLLING THE WAVE - Google Patents

Abstract

The invention relates to a device (1) for the submerged development of a sea area for the control and breaking of the swell, comprising a structure consisting, on the one hand, over its entire upper surface, inclined walls and / or watertight curves (2,3) from a first upstream face (13) to a second back face (7), on the other hand, at least one intermediate link (4) connecting the upper part (2, 3) to the lower supporting part (15,11,9), intermediate connection (4) composed of at least two parts interleaved by telescoping so as to achieve the lowering or raising of a mesh. The lowering of all the mesh allows to adapt the structure to a strong swell. Their deployments adapt the structure to an optimal surf. Thus, this invention aims to optimize the sports practices associated with the breaking of the swell.

Description

The present invention is in the field of development of a maritime area for the control and surge of the swell. In particular, the invention relates to a device 5 for the development of a maritime area, as well as a method of setting up a man-made modular shore. The invention will find a preferential application, but in no way limiting, in order to allow the breaking of the swell in a delimited area. The swell characteristics can be adapted to sports such as surfing and bodyboarding, but also kitesurfing and windsurfing. As is well known, artificial shorelines for coastal protection are becoming more and more widespread around the world. Existing modular devices are provided with complete modularity by removal of the structure. These current shoreline protection devices make it possible to recreate the surf for all types of swells considered, therefore the work done on the sea floor acts irreversibly on the fauna and marine flora. Manufacturing processes and implementation related to these types of solutions are expensive. Many tests to develop artificial shoreline development have been carried out in recent years. In most cases the problem is that during a severe storm, the structure has a failure which calls into question the integrity of the user in the breaking zone. In recent years more reliable tests have been completed and the establishment of a shoreline for coastal protection has become more common. The current devices of shorelines intended for the breaking of the modulating swell in case of strong waves are provided completely reversible. In the latter case the structure is provided removable and transportable in an area where the swell 35 transmits little effort to the structure, for example offshore or on the natural shore, in the open air. However, the cost of labor and the technical means are very expensive during a year. Moreover in areas of strong swells and regular, the structure is very rarely available.

Among the devices for creating an artificial wave in a non-marine aquatic environment, type wave pool are numerous. Around the world there is a large structure of this type. The disadvantages are known, first of all the overall cost of manufacture and maintenance, more sports do not find the naturalness that can be found in the marine environment. The peculiarity of the present invention is to allow a simple and less expensive fast modular shoreline to be put in place. The wave can be controlled within the breaking zone through the orientation, inclination and curvature of the upper shore. A simple and fast system allowing the modularity is realized in case of strong swells. In addition, it respects the marine environment while ensuring optimal and safe sporting practice. Thus we can control the aquatic environment in which the athletes evolve, namely control the wave, from its swelling to its break above a predefined area. It should be noted that the term articulation within the meaning of the present invention designates a pivot or patella connection. The present invention therefore aims to overcome the disadvantages of the state of the art, by proposing a device for fitting a maritime area for the control 30 and the breaking of the swell. Such an arrangement is intended, on the one hand, to create wave breaking in a defined area, and, on the other hand, to ensure the safety of the athlete within the zone.

To do this, such a device comprises a structure constituted, on the one hand, over its entire upper surface, of inclined and / or curved walls, on the other hand, at least of an intermediate link connecting the upper part 5 to the lower carrier part, intermediate link being composed of at least two nested parts by telescoping. In addition, the inclination and / or the curvature of said upper surface is formed by the shape of the beams located on the sides of each mesh. According to one embodiment, said lower bearing portion is composed of at least one beam having at its end a mass oriented towards the center of the mesh. Advantageously, said upper structure is reinforced by at least one beam situated between the upper part and the intermediate connection. Essentially, the set of meshes organized between them constitute a part or all of said device. In particular, spacing is left between each adjacent mesh. To ensure the safety of the athlete and the tightness of the structure, the spacing left at each junction between the meshes is filled by a soft material secured at each respective end. According to a specific characteristic, the sealing of the upper part is ensured by a surface contact composed of a semicircle connected to a plate between each transverse beam. Finally, the placing and holding in position the telescoping 30 of the intermediate beams is provided by a position in the form of a horizontal beam and a position hold in the form of mobile and stationary toothings placed between two respective telescoping links. FIG. 1 schematically represents a perspective view of a first embodiment of a device according to the invention; FIG. 2 diagrammatically represents a perspective view of the upper supporting structure of a mesh based on FIG. 1; FIG. 3 represents a side view of said device in a position of strong swell or inclined with the shape of the movement as a function of the depth; FIG. 4 diagrammatically shows a side view of said device in wave breaking position; - Figure 5 shows schematically in top view of a particular embodiment of the device according to the invention. FIG. 6 represents a particular embodiment of a sectional view of a portion of said upper floor.

The present invention relates to a device (1) for developing a maritime area. Such a device (1) is intended to be implanted at sea, near the coast, or not, so as to define a surface constituting the breaking zone. In addition, first of all, said device (1) provides for creating the swelling of the swell and the breaking of the swell of the plunging and / or sliding type within the previously defined area. Furthermore, in a combined way, the device 1 is provided to be flexible to allow the structure to be adapted to a large swell is to ensure its integrity at sea. A device to ensure the safety of the user in case of projection is planned. The location of this structure is defined such that the structure is located upstream of the natural shoreline. Upstream, naturally, the depth is greater, the wavelength of the swell is greater and its height relative to the surface of the water is less ample. Thus the difference in depth between the seabed (16) and the artificial bottom (2,3) at the junction located upstream of the structure (13) will cause an increase in the amplitude of the swell in parallel with a decrease of its wavelength. During its penetration into the structure in the direction (50) in the device (1), the amplitude will increase between the front face (13) and the rear face (7) and then cause the breaking or breaking of the swell between these two faces. The breaking or breaking of the swell is characterized by a release of energy in the form of foam. There are several types of surf, diving and rolls, the surf in the form of rollers is very popular surfers. The structure is composed of several meshes, as can be seen in FIG. 1, to form, for example, a global structure (30), FIG.

In a more detailed manner, this control consists first of all in causing the breaking, for an amplitude or a range of amplitudes, and in guiding the breaking waves along the overall structure (30) according to the orientation and the direction of propagation. (50), Figure 5. To do this, firstly, the surface of said artificial bottom (2,3) is provided sealed. This surface then forms a floor. Therefore, the swell is split in two when it passes through the device (1). In particular, the waviness of the swell is divided, remaining identical or substantially equivalent under the device 1 and the portion passing through it above will be modified. As such, the sealed surface of said artificial bottom is composed of an inclined and / or curved surface with respect to the horizontal in an increasing slope extending from said first face (13) to the rear wall (7). Said front wall (13) is upstream relative to the direction of the swell (50), while the rear face (7) is downstream. Thus, the shape, the inclination and the tightness of the floor (2, 3) simulates a gradual increase of the seabed, so that the increase in amplitude of the swell during its penetration into the artificially recreated structure by the device 1 generates the surf in the form of waves. In sum, this inclined and / or curved upper part (2, 3) constitutes an ascending floor which will slow the swell and cause it to break in the form of breaking waves. Like a beach, the ascending face (2, 3) causes the formation of the waves, their breaking and their breaking along its increasing slope between said front face (13) and said rear face (7) and along the direction of propagation along the global structure (30). It will be noted that the degree of inclination of the slope of said artificial bottom composed of the inclined and / or curved walls (2,3), as well as its height relative to the seabed (16), determine, in relation to the level of the entrance of the swell within the device (1) the height of the waves thus created. In particular, this height is variable, depending on the characteristics of the swell, but the configuration of the upper floor makes it possible to obtain waves at a defined interval of sizes and forces. In particular, this configuration makes it possible to obtain rolling waves of roll type, with a view to the sporting practice of surfing. According to different embodiments, the degree of inclination can be constant, forming a uniformly rectilinear slope, such as a single plane, but this degree can also be expected to vary, forming several planes with different gradients. Preferably, said artificial base consists of several degrees of inclination which vary in the transverse direction, from the upstream side (13) to the other side downstream (7) of said device (1). This protuberance placed at the level of the stroke of the swell is intended to realize a jump of amplitude.

Theoretically and by observations a projecting slab placed upstream of the direction of propagation of the swell allows an increase in the characteristic height of the waves. This projecting portion is recreated within the device (1) by a curvature of the beam structures (8) located on each side of each mesh. Thus, as can be seen in FIGS. 1 and 4, the floor may be provided forming several different gradients, from the front face (13) to the projecting face (2), the slope may be expected to increase, from the projecting face (2 ) on the rear face (7) the slope can be expected forming a slope of about ten degrees, the numerous tests carried out in artificial basin prove that a slope equivalent to about ten degrees causes a breaking wave in rolls of the swell, in reminding that this type of surf is very popular with athletes.

In addition, the orientation of the device (1) relative to the direction of propagation of the wave (50) will allow a break progressively along the structure, longitudinal orientation made with respect to an axis 54, Figure 5. This breaking can to be more or less rapidly along the structure 30 as a function of the orientation with respect to the direction of propagation (50) and of its inclination with respect to the axis 54, FIG.

In a first aspect, said upper structure is constituted, on the one hand, of walls inclined and / or curved with respect to the horizontal defined by the upper walls (2, 3), on the other hand, of a system of intermediate links (4) connecting the upper walls (2,3) to the lower part (15) positioned on the seabed (16). For this purpose the vertical length of the links (4) defines the inclination of the upper part 2,3. These intermediate links (4) are defined by a system of beams interlocked with each other. Thus the upper part may be more or less inclined depending on the length of the intermediate links (4). In addition, the intermediate connecting system (4) and the lower part (15) constitute the supporting structure of the upper part (2, 3). This system thus defined constitutes a mesh. Note that a mesh may consist of one or more links (4) each being associated with a block (15). In addition, Figure 1 and 3 shows the configuration of two meshes by way of example. These meshs organized between them form the artificial shoreline, as can be seen in FIG. 5. The organization of the meshes between them and their shape makes it possible to carry out the orientation of the said artificial shoreline with respect to the direction of propagation of the swell. ).

To do this, the placement of a mesh will define the placement of the other meshes, the orientation of the meshes relative to the direction of propagation of the swell (50) will thus define the orientation of the reef and consequently the speed of 5 breakage of the swell. The meshes interleaved together thus define a structure 30 as visible in FIG. 5. For rapidly breaking waves or rapid breaking, the inclination with respect to the direction of propagation (50) is further away from the axis of propagation ( 54). For slow-breaking waves or slow breaking, the inclination with respect to the direction of propagation (50) is closer to the axis of propagation (54), FIG. 5. Note that the device (1) can be According to a plurality of embodiments, the structure of the floor is defined to withstand positive and negative cyclic stresses. For example, the floor can be laid then bolted, welded floor, glued on a supporting structure. Preferably, the upper surface composed of the parts 2 and 3 is formed by several meshes interconnected at each side (8) by a suitable device. Essentially, the shape of the ends composed of beams system (8) thus ensures the shape of the floor 25 rectilinear or curved. By experience and observation, a first inclined rectilinear primer surface located upstream (13) of the reef associated with an upstream projecting portion (2), allows for greater swelling of the swell and causes the break-up type or optimal rollers. Thus, the increasing inclination of the various upper parts which constitute the device (1) ensures the adequate breaking of the swelling of the swell upstream (13) to the foam downstream (7). The characteristics of breaking or breaking type plunging or sliding being carried out by the shape of the upper part 2,3. Essentially, the floor should be waterproof. Sealing can be ensured by the establishment of transverse beams (14) secured to the outer ends placed on the sides (8), as shown in Figure 2. It will be noted that this leaves a gap between the beams (14) this vacuum can be filled by plates (20) located between two transverse beams (14) partially sealing, FIG. 6. The transverse structure is subjected to cyclic positive and negative forces, respectively to the forces due to swell. The connection system can therefore be provided secured and fitting each beam (14), as shown in Figure 6. This configuration has the advantage of being adapted to negative and positive vertical forces. Thus, the fixing of the floor on the reinforcement structure (14) placed horizontally makes it possible to ensure a seal of the upper part. The floor therefore withstands the cyclic forces exerted by the fluctuation of the surface swell. To do this, a portion 21 forming a notch fitting each transverse round beam (14) is placed between the plate (20) and the horizontal beams (14) constituting the upper part of a mesh. Joints can be placed between the two parts 14 and 21. The beam systems can be connected to each other by welding. The notches (21) may be steel. The plate (20) connecting each portion may be epoxy or thermoplastic. Among other things the device (1) for creating the upper part may be provided in other materials and forms ensuring a recovery efforts exerted up and down and bottom up. In a second aspect, the connection of the floor with the supporting structure is carried out by a system of intermediate link beams (4). The beams 4 are secured and assembled at the lower level of the upper floor (2,3) and the upper level of the block (15) located on the seabed (16). In particular, the intermediate link beams (4) may be located at each end of each mesh. In addition, the beams 4 are preferably vertical and their dimensions taken to withstand cyclic and three-dimensional reversible forces. The forces in the three dimensions correspond to the potential forces due to the currents and the swell which exerts forces of compression, traction and composite flexions. In addition, reinforcement connections (5) are placed between the upper floor (2,3) and the intermediate link beams (4). The reinforcement beams increase the resistance of the structure with respect to the previously applied forces mentioned. Essentially, the lengths of the intermediate beams 20 (4) define the inclination of the plank with respect to the sea surface. Preferably, the intermediate link system (4) consists of several beams forming a lattice. Each lattice consists of beams placed vertically on their respective block (15). The shape of the beams of the device (1) is round to minimize the forces of the fluid interacting with the beams. The assembly of two beams thus defined can be obtained by welding. By experience and observation a round structure placed in the marine environment 30 takes less effort than a square structure or others form. In addition, the said trellises are composed of tenacious and rigid material which makes it possible to ensure a minimum displacement of the meshes between them, for example steel. Prior treatment or / and a suitable paint may be applied to resist corrosion due to seawater, for example paint or a suitable treatment. In a third aspect, the block 15 placed on the seabed ensures the holding in position and placing in position of the entire system on the seabed (16). The entire supporting structure associated with each mesh composed of the elements 15, 11 and 9 makes it possible to ensure an organization without overlapping of the upper parts with each other.

More particularly, the configuration thereof permits their placement below their respective meshes, as shown in FIG. 4. Blocks 15 have adequate weight and toughness to withstand vertical stresses and adequate shape and weight. to resist horizontal efforts. Thus, this foundation configuration is intended to withstand the vertical forces that would cause a lifting of the structure. The different upper meshes composed of their carrier members 15, 11 and 9 thus provide positioning and holding in position of the entire device (1) on the seabed. More specifically, to ensure the fixing of the structure on the seabed, the part composed of the blocks (15), the lever arm (11) and the mass associated with the ballast (9) have an adequate mass. Thus, the maximum vertical potential force applied to the device (1) is always less than the weight of the lower part of the structure composed of the elements 15, 11 and 9. The lower part therefore prevents the lifting and the movement of the device. (1). The mechanical characteristics, in particular the toughness and the plastic deformation of the materials, are adequate to withstand compressive, tensile and compound forces. According to one embodiment, the foundations are made of reinforced concrete. Reinforced concrete thus ensures the material 13 of the water holding the structure on the seabed (16). Concrete has a density greater than sea that it flows into the water, thus ensuring a and maintaining optimal position. In a fourth aspect, the structure is designed to be flexible for a strong swell, this modularity is provided by beams interlocked with each other. The device (1) is lowered manually to reach a minimum horizontal position on the seabed (16), position visible in Figure 3. The meteorological data can predict the wave characteristics at an interval of seven days, so it allows to adapt the device (1) days or hours in advance. By experimental and theoretical analysis, a submerged structure located towards the surface receives a lot of energy with respect to the movement of surface water (61), FIG. 3. The deeper a structure is, the less the forces applied to the structure. These are important thus defining the gait (62), FIG. 3. Thus the beams interlaced by telescoping make it possible to go from a minimum height (51) to a maximum height (52). The structure does not receive wave forces because the articulation system causes a synchronized movement of the entire device 1 relative to the fluctuation of the surface swell (53). In such a case, the support links (10, 17) are free and not held in position, therefore the structure is in free movement on the seabed (16). Consequently, any potential forces applied 30 cause the device (1) to move, and consequently the forces are not taken up by the structure. Potential fluctuations in the structure at the seafloor correspond to the movement of the surface swell. In addition, the height of the structure before and after tilting recreated the natural conditions of swell. Consequently, wave breaking is non-existent in the zone defining the device (1) after lowering. Then, to return the device (1) to the initial position, it is reassembled and fixed. Deployment and folding can be assisted by a suitable device, for example a cable held at a buoy. Thus, this configuration offers the advantage of being simple and fast. To do this, the intermediate link beams 10 interleaved by telescoping (4) are placed on either side of the meshes. In the case where a mesh consists of an intermediate connection (4), an articulation can be made. It will be appreciated that the reinforcing bonds (5) can be removed by a bolt device for example. In the case where the device is in function of surf it is fixed and mounted. In the case where the device is in function called strong swell it is lowered and not fixed (60), Figure 3. 20 Thus, all the meshes are deployed or not depending on the forecast of the swell. Thus, in a so-called fixed position the wave sweeps over the structure and in so-called high wave position the structure is lowered manually to be subjected to less stress of the swell. The translations made by entanglement of the bonding structures between them (4) thus defined can be made by cylinder / cylinder surface contact. In a fifth aspect, the telescoping nested beams (4) are positioned by a suitable system placed horizontally within each beam (10). In the case of moving the telescoping nested connecting beams (4), the positioning system 35 (10) is adaptable to allow translation of the inner beam into the outer beam. Thus this stop in translation is achieved by a stop. Preferably, the nested beams (4) are put in position by a system of stops (10). The stops are positioned vertically to allow movement of an inner beam in an outer beam. The stops are placed horizontally to allow stopping in translation of the inner beam. The transition from the vertical position to the horizontal position is achieved by a pivot connection. This setting in motion makes it possible to go from a high position, as can be seen in FIG. 4, to a base position as can be seen in FIG. 3. To do this, the pivot connection can be made by a plate having at its end a hole shaped cylinder. A cylindrical beam is embedded in the outer link (4). The placement of the plate in the hole thus ensures a cylinder / cylinder connection and therefore the pivot connection, the horizontal positioning can be achieved by a square. The material used is preferably steel. The holding in position is ensured by fixing the outer and inner beams. This attachment is intended to make a reversible embedding. To do this, the holding in position (17) can be done by a pin placed between the outer and inner connections. This position retention can also be achieved by a semicircle device secured on the outer links matching each respective inner beam. Whatever the solution adopted, it is removed for moving the inner beams in adequacy with the positioning system, then reset to perform its function of holding in position or embedding. Preferably, the holding in position is achieved by a bolt on which the holding device is placed. Essentially a positional setting associated with more precise positional hold is performed at the last inner link. Inside bonded on the upper surface (2,3). To make teeth are placed on the last and the penultimate inner link. A portion of movable teeth on the inner link and the other stationary on the other respective part, worm or pinion type associated with a toothed beam. Thus, the movable part marries the immovable part to the desired height. In addition, the holding position can be achieved as previously, by a semicircle device secured on the outer link and then fixed on the inner link, finally the semicircle is held by pin or bolts. By similarity, the semicircle is similar to the semicircle 21 visible in Figure 6. By way of example the holding in position of the semicircle on the inner link acts as a brake. The high friction between the two parts prevents movement and thus provide the embedding connection, position (17) visible in Figures 1 and 4. Preferably holding in position said brake compound semicircle is made by bolts. More precisely, the bolt is composed of threading associated with a beam without threading. The thread is placed externally of the holding device in position to increase the mechanical characteristics in shear of the bolt.

According to one embodiment, the threaded beam passes through the outer part, the semicircle is placed between the inner part and the outer part. The tightening of the bolt pushes the said brake to tighten the inner part. According to a particular embodiment, the holding in position can be carried out from above. Thus the said brakes are no longer placed on the sides but over the inner beam considered. The embedding is therefore more achieved by friction but by the threaded beam and the bolts held in position vertically.

Note that teeth can be placed on the semicircle to marry the system and maintain in position all at the desired height. The placement of the assembly can be assisted by a buoy associated with a cable.

The materials used to achieve this can be steel, treated steel. In addition, the translation of the beams together can be assisted by placing guide beams on either side of the intermediate link (4). The purpose of translational guidance is to avoid arching. This more precise setting configuration offers the advantage of placing the floor (2,3) at a precise height without moving the whole of the mesh. In a sixth aspect, said meshes taken independently with each other are provided to limit the natural phenomenon of burying a structure in the seabed (16). Therefore each mesh 20 taken independently does not influence the neighboring mesh if it moves a minimum vertical or horizontal distance. More particularly, the main function of this feature is that mesh motion does not influence the mechanical properties of the overall structure. When immersed in seawater, a structure is subjected to different efforts, it can create a displacement of the structure with respect to the forces exerted on it. In the case where the meshes are embedded between them, this embedding could modify the mechanical characteristics and create stress on a section of the device (1) and cause a rupture of the device (1). To avoid this, the meshes are placed without embedding with each other on the seabed (16). Essentially, to note a possible movement of the meshes between them, an element composed of two rings placed between two meshes located next to each other makes it possible to check a possible movement of the meshes. To do this, the rings have an inside diameter greater than the beams constituting part 8. The two rings are interconnected by a bar. In the case where the meshes have not moved a certain value, the device composed of bar and wide rings is not constrained and can be set in motion. In the case where the meshes have moved a certain value, the device 10 composed of bar and wide rings is constrained and can not be set in motion. In the latter case, a replacement of the stitches may be necessary. In a seventh aspect, independently of the vertically exerted pulling and compression forces, lateral forces can be applied on either side of the meshes. These lateral forces are due to the current and the swell. By experience, a solid placed vertically on the seabed subjected to lateral forces can be displaced with respect to its vertical and move until it falls completely in the horizontal position. Therefore to avoid this phenomenon on the structure, a suitable form is recreated to achieve a lever effect 11.9 and ensure the stability of the mesh. More precisely, the lever arm effect is recreated by putting an offset mass towards the center of the mesh in question. The purpose of the shape of the foundations 15, 11 and 9 is to withstand the horizontal forces which would cause a movement of the beam 30. structure. To avoid this, a ballast (9) made of heavy materials makes it possible to weigh down the block (15). This weighting (9) thus leads to an increase in the mass of the foundations and thus increases the positional and position-keeping properties of the system assembly on the seabed (16).

Essentially, the ballast (9) can be shifted towards the center of each mesh to withstand the horizontal forces going from the outside towards the center of the mesh. The horizontal forces going from the center of the mesh to the outside are taken up by the effect of leverage made by the eccentricity of the weight due to the ballast (9) and the beams (11). To do this, the ballasting (9) can be achieved by a cage into which rocks or other heavy materials of this type are introduced, the beams 11 connecting the portion (15) to the ballast 9 can be made of suitable steel. Thus defined the structure is configured to increase its stability with respect to the different external forces exerted. In an eighth aspect, the meshes taken independently of each other will leave a void. This void can therefore compromise the safety of athletes. Thus to solve this significant problem a security system 20 is provided to be placed between each mesh. This device fills the void created by the offset of the meshes while allowing a movement of the meshes between them for a considered range. The shape of the protection at each junction (12) thus forms a protrusion, or a flat surface. It will be noted that the holding in position can be obtained by strings, wiring or a form matching the gap created between each mesh. For this purpose the protection is therefore of a soft material or a suitable foam. This configuration in soft material plastic or foam adapted ensures the safety of the athlete and the tightness of the mesh to allow an optimal surf.

It will be appreciated that a protective layer in the form of soft materials may be secured above portions 2 and 3. In sum, in a first aspect, said upper structure consists of inclined and / or curved walls with respect to horizontally defined by the upper walls (2,3) allowing the breaking of the swell In a second aspect, the connection of the upper parts 2 and 3 with the supporting structures 15, 11 and 9 10 is achieved by a system of connecting beam 4 Reinforcements in the form of beams 5 are placed between the upper part 2 and 3 and the connection 4. In a third aspect, the block 15 placed on the seabed maintains the position and position of the assembly. of the system on the seabed 16. The entire supporting structure associated with each mesh composed of the elements 15, 11 and 9 makes it possible to ensure an organization without overlapping of the upper parts with each other. In a fourth aspect, the structure is provided modular for a high swell, this modularity is provided by beams that entangle (4). The device 1 tilts manually to reach a horizontal position on the seabed, position visible in Figure 3. In a fifth aspect, the nested beams (4) are placed in position (10) and held in position (17) by a suitable system placed horizontally and vertically inside each link (4). In a sixth aspect, said meshes taken independently with each other are intended to limit the natural phenomenon of burying a structure in the seabed. Therefore each mesh taken independently does not influence the neighboring mesh if it moves a minimum vertical or horizontal distance.

In a seventh aspect, independently of the forces of traction and compression exerted vertically, lateral forces can be applied on both sides of the meshes. Therefore, a suitable shape is recreated to achieve a lever effect 11.9 and to stabilize the mesh. In an eighth aspect, the meshes taken independently between them will leave a vacuum. This void can therefore compromise the safety of athletes. To solve this problem a structure made of soft materials, foam or plastic type can be secured between each mesh. Thus the breaking of the swell is carried out along the device 1. The structure is inclined and lying down for a strong swell. The safety of athletes is therefore ensured within the structure.

Note that the device (1) can be an area of a few tens of square meters to several hundred square meters. An industrial application of this invention is implantation at sea for sporting practice.

Claims (10)

REVENDICATIONS1. Device (1) for the submerged development of a sea zone for the control and breaking of the swell, comprising at least one mesh-type structure constituted, on the one hand, over its entire upper surface, inclined walls and / or watertight bends (2,3), on the other hand, at least one intermediate connection (4) connecting the upper part (2,3) to the lower carrier part (15,11,9), intermediate connection (4) composed of at least two parts nested by telescoping so as to achieve the lowering or raising of at least said mesh. 2. Device (1) according to claim 1, characterized in that the inclination and / or the curvature of said upper surface (2,3) is formed by the shape of the beams located on the sides (8) of each mesh. and the length of each intermediate link (4). 3. Device (1) according to claim 1, characterized in that said lower bearing portion (15, 11, 9) is composed of at least one beam (11) having at its end a mass (9) facing the center of the mesh. 4. Device (1) according to claim 1, characterized in that said upper structure (2,3) is reinforced by at least one beam (5) between the upper part (2,3) and the intermediate connection (4). ). 5. Device (1) according to any one of the preceding claims, characterized in that the set of meshes organized together form a part or all of said overall device (30). 6. Device (1) according to claim 5, characterized by a spacing between each adjacent mesh. 7. Device (1) according to claim 6, characterized in that the spacing left at each junction between the meshes is filled by a soft material secured at each respective end (8). 8. Device (1) according to claim 1, characterized in that the sealing of the upper part (2,3) is provided by a surface contact composed of a semicircle (21) connected to a plate (20). ) between each transverse beam (14). 9. Device (1) according to any one of the preceding claims characterized in that each mesh is connected with its neighbor by at least one element consisting of rings and bar. 10. Device (1) according to any one of the preceding claims, characterized in that the telescoping of the intermediate beams (4) is ensured by positioning in the form of a horizontal stop (10) and holding in position in the form of movable and stationary brakes placed between two telescoping links (17).