FR3014470A1 - WAVE GENERATING SYSTEM, WAVE SWIMMING POOL, AND SYSTEM INSTALLATION METHOD - Google Patents

Abstract

The invention is a system for generating waves (9) for an aquatic basin (1) comprising at least one profile (7) adapted to be driven horizontally parallel to the bottom (6) of the basin by means (4, 5) of drive, the drive means (4, 5) being adapted to drive in a reciprocating movement (13) the profile or sections (7) each for a distance less than 1/10 of the length of the water basin .

Description

FIELD OF THE INVENTION The present invention relates to the field of swimming pools. The present invention more particularly proposes a system for generating waves in a swimming pool. The generation of waves in a pool such as a pool can have several reasons. She can have a playful reason. The waves generated in a swimming pool can give the illusion of being at the seaside on a beach and, for example, allow activities to be practiced that require waves such as surfing. Wave generation can have a scientific reason. The waves generated in an experimental basin can be used to know the effect of wave on a littoral or on a boat for example. EP 2 123 850 A1 teaches a wave generation system in a pool. The system includes a profile that moves to the bottom of the pool through a drive means. The profile forms an angle different from 90 ° with respect to its direction of travel. The profile profile is chosen so that it has no concavities facing its direction of movement, the ratio between its height and the depth of the basin being between 1/2 and 3. It can be rigid without concavity or deformable such as an inflatable section or filled with water so that it has no concavities. This system requires the use of high profile profile which can be a disadvantage. The present invention therefore aims to overcome one or more of the disadvantages of the prior art by providing a wave generating device in a pool easy to manufacture and inexpensive. To this end, the invention relates to a wave generation system for aquatic basin comprising at least one profile adapted to be driven horizontally parallel to the bottom of the basin by drive means, characterized in that the drive means being clean in a reciprocating movement the profile or profiles each at a distance less than 1/10 of the length of the water basin. According to another particularity, the drive means comprise at least two winches adapted to be arranged each in the vicinity of the two opposite walls of the water basin, each winch being adapted to control the winding and unwinding of at least one cable attached to the profile. According to another feature, the winches are controlled by a synchronization means, the synchronizing means controlling a winch disposed in the vicinity of one wall of the basin to wind the cable and to the other winch disposed in the vicinity of the opposite wall simultaneously unwinding the cable and vice versa to obtain a back and forth movement of the profile or profiles. According to another feature, the cable or cables are integrated in rails that can be placed or fixed to the bottom of the basin. In another feature, the synchronization means is a computer means communicating with the winches by wired or wireless communication means. According to another feature, the drive means are at least one integrated motor at least in the profiles, the motor being adapted to drive wheels allowing the (x) profile (s) to move to the bottom of the basin. According to another feature, the system comprises rails that can be fixed to the bottom of the basin, the rails guiding the wheels of the profile or profiles. According to another feature, the drive means are at least one integrated motor at least in the profiles that are not arranged between two profiles, or the motors are adapted to drive a double groove pulley, a first end of at least one first cable being capable of being fixed to one of the two opposite walls of the basin, the second end of the first cable being wound around a groove of the double pulley, a first end of at least one second cable being wound in the opposite direction around the other groove of the double pulley, the second end of the second cable being fixed to the other of the two opposite walls of the basin. According to another feature, the drive means are at least one integrated motor at least in the profiles that are not arranged between two profiles, or the motors are adapted to drive a double groove pulley, a first end of less a first cable being adapted to be fixed to one of the two opposite walls of the basin or wound around a groove of a double pulley driven by the integrated motor in an adjacent section, the second end of the first cable being wound around a groove of the double pulley, a first end of at least a second cable being wound around the other groove of the double pulley, the second end of the second cable being fixed to the other of the two opposite walls of the basin or well wrapped around a groove of a double pulley driven by the motor into an adjacent profile. In another feature, the motors are controlled by a computer means that communicates with them by wired or wireless communication means.

According to another particularity, the computer means comprises an input means allowing a user to enter parameters for adjusting the movement of the profile or profiles. According to another particularity, the system furthermore comprises sensors detecting the wave propagation speed and / or the wave height, the signals representative of the wave propagation speed and / or the wave height being sent to the computer means. . According to another feature, the profile or profiles are regularly spaced between them every 10 m to 100 m between the two opposite walls of the basin. According to another feature, the profile or profiles are regularly spaced angularly between them every 20 ° to 360 °. According to another particularity, the ratio between the height of the profile and the depth of the aquatic basin is between 1/20 and 1/10.

According to another feature, the profile or profiles have a cross section in the form of a semicircle, square or triangle. The invention also relates to a wave pool comprising a water basin and a wave generation system according to the invention. The invention also relates to a method for installing the system according to the invention in an aquatic basin characterized in that it comprises at least one step of installation of profile (s) at the bottom of the water basin. According to another feature, the method further comprises a step of fixing the profiles on cables and a step of installing the profile drive means.

According to another feature, the method further comprises a step of fixing rails capable of guiding profile wheels to the bottom of the basin. According to another feature, the method further comprises the attachment of wave speed sensor and / or wave height on the walls of the water basin. In another feature, the method includes attaching at least one first cable to a wall of the pool and at least one second cable to another opposite wall of the pool.

Other features and advantages of the present invention will appear more clearly on reading the description below, made with reference to the accompanying drawings: FIG. 1 represents a cross-section of a rectangular basin with the wave generation system according to a configuration, FIG. 2 represents a cross section of a rectangular basin with the wave generation system according to another configuration, FIG. 3 represents a cross section of a rectangular basin with the wave generation system according to another configuration. FIG. 4 shows a top view of a rectangular basin with the wave generation system in a configuration; FIG. 5 shows a top view of a circular pool with the wave generation system in a configuration, the FIG. 6 represents a top view of a rectangular basin with the selo wave generation system n another configuration, Figure 7 shows a top view of a circular basin with the wave generation system according to another configuration. The invention will be described with reference to the figures listed above.

The present invention provides a wave generation system (9) for aquatic basin (1). The water basin can take several forms In a configuration shown in Figures 1, 2, 3, 4 and 6, the water basin has a rectangular shape. In this configuration, the length of the water basin corresponds to the distance between two opposite walls (2, 3) of the basin in the direction of the length of the basin or in the direction of the width of the basin. In another configuration shown in Figures 5 and 7, the water basin has a circular shape comprising two walls (24, 25) concentric circular. In this configuration, the length of the water basin corresponds to the distance that can be traveled by an object moving in the pool at an angle of 360 ° from its starting point (26) while remaining equidistant from the two circular walls (24, 25). The circular form is not limiting. Indeed, the basin may also have an oval shape or chain link for example. The bottom of the basin can be horizontal or inclined. For example, in a circular basin, the bottom may be inclined towards the center of the circular shape of the basin.

The system comprises at least one profile (7). This or these profiles (7) are adapted to be driven horizontally parallel to the bottom (6) of the basin (1) aquatic by means (4, 5) of training. The cross section of the profile or profiles (7) can be in the form of a semicircle, square or triangle. Preferably, the cross section of the profile or profiles (7) is square. The height (hp) of the profile or profiles (7) is determined according to the depth (H) of the basin (1). In a nonlimiting manner, the ratio between the height (hp) of the profile (s) (7) and the depth (H) of the aquatic basin (1) is between 1/20 and 1/10. For example, in a basin (1) 2 m deep, the profile or profiles (7) have a height (hp) of about 15 cm. In another example, for a basin (1) having a depth (H) of 25 cm, the profile or profiles (7) can have a height (hp) of 2.5 cm. The depth (H) of the basin (1) can correspond to the depth of water contained in the basin (1).

In a basin whose bottom is inclined, the depth (H) of the basin may correspond to the depth of water contained in the basin (1), for example, vertically from a point situated at an equal distance between two opposite walls. .

Thus, this ratio of heights (hp, H) allows the user of the basin (1) to enjoy a significant height of water between the plane (14) comprising the upper part of the profile (s) and the plane (12). ) including the surface of the water, while improving safety.

The profiles (7) can be made of wood, or metal, or plastic or foam or other suitable materials. In the remainder of the description, in order not to obscure the description, the system will be described for a rectangular basin and then for a circular basin. For a rectangular basin, or profiles (7) are adapted to be driven by the drive means between two walls (2, 3) opposite the basin (1) aquatic. The distance between these two opposite walls (2, 3) corresponds to the length of the aquatic basin.

In a rectangular basin configuration, the length of the basin corresponds to the largest dimension of the rectangular aquatic basin (1), with the exception of the basin depth. In another configuration of the rectangular basin, the length of the water basin corresponds to the smallest dimension of the rectangular aquatic basin (1), with the exception of the depth of the basin. In a configuration shown in FIG. 4, the driving of the one or more profiles (7) is carried out in such a way that the longitudinal axis (22) of the profile (s) is perpendicular to the driving direction (13) of the one or more profiles (7). This configuration makes it possible to obtain a swell.

In another configuration shown in FIG. 6, the driving of the one or more profiles (7) is carried out in such a way that the longitudinal axis (22) of the profile (s) is not perpendicular to the direction (13) of driving the profile or profiles (7). This configuration makes it possible to obtain a breaking wave. The drive means (4, 5) are adapted to drive in a movement (13) back and forth or the profiles (7).

The profile or profiles (7) are each driven a distance less than 1/10 of the distance between the walls (2, 3) opposite the basin (1) aquatic. In a configuration where the system comprises several profiles (7), the profiles (7) are driven in the same direction (13) simultaneously.

In one configuration, the one or more profiles (7) are evenly spaced between them between the two opposite walls (2, 3) of the basin (1). For example, the value of the spacing (L) between two profiles (7) can be in a range from 10 m to 100 m, preferably every 50 m. For example, in a basin (1) whose distance between the two walls (2, 3) opposite is 200 m, the system may comprise three sections spaced between them of 50 m. In a configuration of the means (4, 5) for driving, the means (4, 5) for driving the profile (s) (7) comprise at least two winches (4, 5) adapted to be arranged each in the vicinity of the two opposite walls (2, 3) of the aquatic basin (1). Each winch (4, 5) is able to control the winding and unwinding of at least one cable (8) attached to (x) section (s) (7). In one embodiment, the cable or cables (8) are integrated in rails placed or fixed to the bottom (6) of the basin. For example, a winch (4) may be disposed adjacent a wall (2) of the basin and another winch (5) is disposed adjacent the wall (3) opposite. In one embodiment, the winches (4, 5) can pull a cable (8) fixed in the middle of each profile. In another embodiment, the winches (4, 5) can pull a first cable connected to two cables whose ends opposite to the ends connecting them to the first cable are each fixed to one end of the profile closest to the winch.

The other profiles can be interconnected by parallel cables joining the ends of the profiles. In another example, the system may include two winches per wall. Each of the winches can pull a cable attached to the ends of the or profiles.

The profiles (7) may comprise wheels. The wheels can be guided by rails placed or fixed to the bottom of the basin. In one embodiment, the winches (4, 5) are integrated in the opposite walls (2, 3). In another embodiment, the winches (4, 5) are integrated in the ground at the bottom (6) of the pond (1) aquatic.

In one embodiment, the winches (4, 5) are controlled by synchronization means for synchronizing the winding and unwinding of the cable (s) (8) by the winches. The synchronization means controls a winch (4) disposed in the vicinity of one wall (2) of the basin to wind the cable (8) and to the other winch (5) disposed in the vicinity of the wall (3) opposite simultaneously unrolling the cable (8) and vice versa to reciprocate the profile or profiles (7). The synchronization means may be a computer means (14) which communicates with the winches (4, 5) by means of wired or wireless communication means (16).

In another configuration of the drive means, the drive means are at least one integrated motor at least in the profiles (7) which are not arranged between two profiles (7). The motor is used to drive wheels (18) allowing the (x) section (s) (7) to move to the bottom (6) of the basin (1). In one embodiment, the system comprises rails that can be fixed or placed at the bottom of the basin to guide the wheels (18) of the profile or profiles. In one embodiment, the motors may be controlled by computer means (14) that communicates with the motors by wired or wireless communication means (16).

In another configuration, the drive means are at least one integrated motor at least in the profiles that are not arranged between two profiles. In one embodiment of this configuration, in the case where a profile is used, the motor or motors are adapted to drive a pulley (19) with double groove. A first end (20a) of at least one first cable (20) is attached to one (2) of two opposite walls of the basin. The second end (20b) of the first cable (20) is wound around a groove of the double pulley (19). A first end (21a) of at least one second cable (21) is wound in the opposite direction around the other groove of the double pulley (19). The second end (21b) of the second cable (21) is attached to the other (3) of the two opposite walls of the basin. Thus, when the motor integrated in the profile drives the double pulley, a cable is unrolled from the pulley while the other cable is unwound from the pulley which advances the profile.

In another embodiment of this configuration, in the case where at least two profiles are used (FIG. 3), the motor or motors are capable of driving a double groove pulley (19). A first end (20a) of at least one first cable (20) is attached to one (2) of the two opposite walls of the basin or wound around a groove of a double pulley driven by the motor integrated in a profile adjacent. The second end (20b) of the first cable (20) is wound around a groove of the double pulley (19). A first end (21a) of at least one second cable (21) is wrapped around the other groove of the double pulley (19). The second end (21b) of the second cable (21) is fixed to the other (2) of the two opposite walls of the basin or wrapped around a groove of a double pulley (19 ') driven by the engine in a adjacent profile. In each configuration, the computer means (14) may include input means (17) for allowing a user to input wave height and wave displacement rate adjustment parameters. The calculation means of the computer means (14) then calculate the speed of displacement of the profiles which makes it possible to obtain the desired height and wave speed.

In one configuration, sensors (10, 11) may be attached to basin walls to determine the wave propagation velocity (9) and / or the wave height (9). The walls in question are the walls other than the opposite walls (2, 3) in the vicinity of which the winches are arranged. For example, two sensors (10, 11) which follow each other can allow the calculation of the wave propagation speed. The first sensor (10) detects the passage of the wave (9) and sends to the computer means a first signal representative of the moment when the wave is detected by the first sensor. The second sensor (11) then detects the passage of the wave (9) after its passage to the first sensor (10). The second sensor (11) then sends the computer means a second signal representative of the passage of the wave (9). The computer means comprises storage means which store the signals sent by the sensors and calculation means. The calculation means calculate the speed of the wave from the first signal and the second signal and the distance between the two sensors. The sensors (10, 11) communicate with the computer means (14) via wired or wireless communication means (15). For example, sensors may be attached to walls to measure the height of the waves. The sensors send signals representative of the height of the waves to the computer means which stores these signals in its storage means. The signals sent by the sensors allow the computing means of the computer means (14) to control that the speed of movement of the profiles and the wave height correspond to the parameters input by the user by the means (17) of capture.

In another configuration, the arrangement of the system is stored in the storage means of the computer means (14). The arrangement of the system corresponds at least to size values of the basin and dimension of the profile or profiles, number of profiles and their arrangement. These values are stored in the storage means of the computer means. The user can thus input by the input means of the wave height adjustment parameters and wave displacement speed. The calculation means of the computer means (14) then calculate the speed of displacement of the profiles which makes it possible to obtain the desired height and wave speed.

The computer means (14) may be a desktop computer, a laptop, a tablet, a smartphone or any other means for implementing the system.

For a circular basin as shown in Figures 5 and 7, the or profiles (7) are adapted to be driven by the drive means in the channel formed by the two walls (24, 25) concentric.

In a configuration shown in FIG. 5, the driving of the one or more profiles (7) is carried out in such a way that the longitudinal axis (22) of the profile (s) remains perpendicular to the tangents (23) of the walls (24, 25). concentric at the points of intersection of the longitudinal axis (22) of the profile with the tangents (23). This configuration makes it possible to obtain a swell. In another configuration as shown in FIG. 7, the driving of the one or more profiles (7) is carried out in such a way that the longitudinal axis (22) of the profile (s) is not perpendicular to the tangents (23) of the walls. (24, 25) and is not parallel with them.

This configuration makes it possible to obtain a breaking wave. The drive means (4, 5) are adapted to drive in a movement (13) back and forth or the profiles (7). The profile or profiles (7) are each driven a distance less than 1/10 of the length of the basin (1) aquatic. The length of the pool (1) corresponds to the distance that can be traveled by an object moving in the pool at an angle of 360 ° from its starting point (26) while remaining equidistant from the two circular walls. . In a configuration where the system comprises several profiles (7), the profiles (7) are driven in the same direction (13) simultaneously.

In one configuration, the one or more profiles (7) are regularly spaced apart. For example, the value of the angular spacing a between two profiles (7) can be in a range from 20 ° to 360 °, preferably every 120 °. For example, in a basin (1) whose length is 200 m, the system may comprise three sections spaced angularly from each other by 120 °. In a configuration of the drive means, the drive means are at least one integrated motor at least in the profiles (7). The motor is used to drive wheels (18) allowing the (x) section (s) (7) to move to the bottom (6) of the basin (1). In one embodiment, the system comprises rails capable of being fixed or placed at the bottom of the pool to guide the wheels (18) of the one or more sections. The track or rails are concentric with the two concentric walls of the basin. In one embodiment, the motors are controlled by a computer means that communicates with them by wired or wireless communication means. The computer means may include input means for a user to input wave height and wave displacement rate adjustment parameters. The calculation means of the computer means then calculate the speed of movement of the profiles (7) which makes it possible to obtain the desired height and wave speed. In one configuration, sensors may be attached to basin walls (1) to determine the speed of wave propagation and / or wave height. For example, two sensors that follow each other can be used to calculate the speed of wave propagation. The first sensor detects the passage of the wave and sends the computer means a first signal representative of the moment when the wave is detected by the first sensor. The second sensor then detects the passage of the wave after it passes to the first sensor. The second sensor then sends the computer means a second signal representative of the passage of the wave. The computer means comprises storage means which stores the signals sent by the sensors and calculation means. The calculation means calculate the speed of the wave from the first signal and the second signal and the distance between the two sensors. The sensors communicate with the computer means by wired or wireless communication means. For example, sensors may be attached to walls to measure the height of the waves. The sensors send signals representative of the height of the waves to the computer means which stores these signals in its storage means. The signals sent by the sensors allow the calculation means of the computer means to control that the speed of movement of the profiles and the wave height correspond to the parameters entered by the user by the input means. In another configuration, the arrangement of the system is stored in the storage means of the computer means. The arrangement of the system corresponds at least to size values of the basin and dimension of the profile or profiles, number of profiles and their arrangement. These values are stored in the storage means of the computer means. The user can thus input by the input means of the wave height adjustment parameters and wave displacement speed. The calculation means of the computer means then calculate the speed of displacement of the profiles which makes it possible to obtain the desired height and the desired wave speed. The computer means may be a desktop computer, a laptop, a tablet, a smartphone or any other means to implement the system. The system can be installed on all kinds of watersheds to get a wave pool.

The method of installing the system in an aquatic pond to obtain a wave pool includes at least one step of installing profile (s) at the bottom of the water basin.

According to a configuration, the method further comprises a step of fixing the profiles on cables and a step of installing the drive means of the profiles. According to a configuration, the method further comprises a step of fixing rails capable of guiding profiled wheels to the bottom of the basin. According to another feature, the method further comprises the attachment of wave speed sensor and / or wave height on the walls of the water basin. In another configuration, the method includes attaching a first cable to a wall of the pool and a second cable to another opposite wall of the pool. The present description details various embodiments and configurations or variants with reference to figures and / or technical characteristics. It will be appreciated by those skilled in the art that the various technical features of the various modes or configurations may be combined with one another to achieve other embodiments and configurations, unless the reverse is explicitly mentioned or these technical features are not readily apparent. are incompatible. Likewise, a technical feature of an embodiment or configuration may be isolated from the other technical features of this embodiment unless the reverse is mentioned. In the present description, many specific details are provided for illustrative and not limiting, so as to detail precisely the invention. Those skilled in the art will understand, however, that the invention can be realized in the absence of one or more of these specific details or with variations. On other occasions, certain aspects are not detailed so as to avoid obscuring and weighing down the present description and one skilled in the art will understand that various and varied means may be used and that the invention is not limited. to the only examples described.

It should be obvious to those skilled in the art that the present invention allows embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration, but may be modified within the scope defined by the scope of the appended claims, and the invention should not be limited to the details given above.

Claims (22)

REVENDICATIONS1. Wave generation system (9) for an aquatic basin (1) comprising at least one profile (7) capable of being driven horizontally parallel to the bottom (6) of the basin by means (4, 5) for driving, characterized in that the driving means (4, 5) are adapted to drive the recess (s) (7) in a reciprocating movement (13) each for a distance less than 1/10 of the length of the water basin. 2. System according to claim 1, characterized in that the drive means (4, 5) comprise at least two winches (4, 5) adapted to be arranged each in the vicinity of two walls (2, 3) opposing the basin (1) aquatic, each winch (4, 5) being adapted to control the winding and unwinding of at least one cable (8) attached to the profile. 3. System according to at least one of claims 1 and 2, characterized in that the winches (4, 5) are controlled by a means (14) of synchronization, the means (14) of synchronization controlling a winch (4) disposed in the vicinity of one wall (2) of the basin to wind the cable and the other winch (5) disposed in the vicinity of the wall (3) opposite to unwind simultaneously the cable (8) and vice versa to obtain a movement (13) back and forth of the or profiles (7). 4. System according to at least one of claims 1 to 3, characterized in that the or cables (8) are integrated in rails that can be placed or fixed to the bottom (6) of the basin (1). 5. System according to at least one of claims 1 to 4, characterized in that the means (14) for synchronization is a means (14) computer that communicates with the winches (4, 5) by means (16) of wired communication or wireless. 6. System according to claim 1, characterized in that the drive means (4, 5) are at least one integrated motor at least in the profiles, the motor being adapted to drive wheels (18) allowing the (x) profile (s) (7) to move to the bottom of the basin. 7. System according to claim 6, characterized in that the system comprises rails that can be fixed to the bottom of the basin, the rails guiding the wheels (18) of the profile or profiles (7). 8. System according to claim 1, characterized in that the drive means are at least one integrated motor at least in the profiles that are not arranged between two profiles, or the motors are adapted to drive a pulley (19). double groove, a first end (20a) of at least one first cable (20) being adapted to be fixed to one of (2) two opposite walls of the basin, the second end (20b) of the first cable (20) being wrapped around a groove of the double pulley (19), a first end (21a) of at least one second cable (21) being wound in the opposite direction around the other groove of the double pulley (19), the second end (21b) of the second cable (21) being fixed to the other (3) of the two opposite walls of the basin. 9. System according to claim 1, characterized in that the drive means are at least one integrated motor at least in the profiles that are not arranged between two profiles, or the motors are adapted to drive a pulley (19). double groove, a first end (20a) of a first cable (20) being adapted to be fixed to one (2) of the two opposite walls of the basin or wrapped around a groove of a double pulley driven by the integrated motor in an adjacent profile, the second end (20b) of the first cable (20) being wound around a groove of the double pulley (19), a first end (21a) of a second cable (21) being wound around the other groove of the double pulley (19), the second end (21b) of the second cable (21) being fixed to the other (2) of the two opposite walls of the basin or wrapped around a groove of 'a double pulley (19') driven by the engine in a profile adj acent. 10. System according to at least one of claims 1 to 9, characterized in that the motors are controlled by means (14) 5 computer that communicates with them by wired or wireless communication means. 11. System according to one of claims 5 or 10, characterized in that the computer means (14) comprises a means (17) of input allowing a user to enter parameters for adjusting the movement (13) of the profile or profiles (7). System according to at least one of claims 1 to 11, characterized in that the system further comprises sensors (10, 11) for detecting the propagation velocity of the waves (9) and / or the height of the waves, the representative signals the wave propagation speed and / or the wave height being sent to the computer means (14). 13. The system of claim 1, characterized in that the or profiles (7) are evenly spaced between them every 10 m to 100 m between the two walls (2, 3) opposite the basin. 14. System according to claim 1, characterized in that the or the profiles (7) are regularly spaced angularly between them every 20 ° to 360 °. 15. System according to claim 1, characterized in that the ratio between the height (hp) of the profile and the depth (H) of the basin (1) aquatic is between 1/20 and 1/10. 25 16. System according to at least one of claims 1 to 14, characterized in that the or profiles (7) have a cross section in the form of semicircle, square or triangle. 17. Wave pool comprising a water basin and a wave generating system according to at least one of claims 1 to 16. 18. A method of installation of the system according to claim 1 5 in an aquatic basin characterized in that it comprises at least one profile installation step (s) at the bottom of the water basin. 19. The method of claim 18, characterized in that it further comprises a step of fixing the profiles on cables and a step of installing the profile drive means. 10 20. Method according to one of claims 18 and 19, characterized in that it further comprises a step of fixing rails capable of guiding profile wheels to the bottom of the basin. 21. Method according to at least one of claims 18 to 20, characterized in that it further comprises the attachment of wave speed sensor 15 and / or wave height on the walls of the water basin. 22. Method according to at least one of claims 18 to 21, characterized in that it comprises the fixing of at least a first cable to a wall of the basin and at least a second cable to another opposite wall of the basin. 20