Ocean waves have been used recreationally for hundreds of years. One of the most popular sports at any beach with well-formed, breaking waves is surfing. Surfing and other board sports have become so popular, in fact, that the water near any surf break that is suitable for surfing is usually crowded and overburdened with surfers, such that each surfer has to compete for each wave and exposure to activity is limited. Further, the majority of the planet's population does not have suitable access to ocean waves in order to even enjoy surfing or other ocean wave sports.
Another problem is that the waves at any spot are varied and inconsistent, with occasional “sets” of nicely formed waves that are sought after to be ridden, interspersed with less desirable and, in some cases, unrideable waves. Even when a surfer manages to be able to ride a selected wave, the duration of the ride lasts only a mere 2-30 seconds on average, with most rides being between 5 and 10 seconds long.
Ocean surface waves are waves that propagate along the interface between water and air, the restoring force is provided by gravity, and so they are often referred to as surface gravity waves.
Ocean waves generally have five stages: generation, propagation, shoaling, breaking, and decay. The shoaling and breaking stages are the most desirable for rideable waves. The point of breaking being strongly dependent on the ratio of the water depth to the wave's amplitude but also depends on the contour, depth and shape of the ocean floor. In addition, velocity, wavelength and height of the wave, among other factors, can also contribute to the breaking of a wave. In general, a wave can be characterized to result in one of four principal breaker types: spilling, plunging, collapsing, and surging. Of these wave types the spilling waves are preferred by beginner surfers while the plunging waves are revered by more experienced surfers. These breaker types are illustrated in
Various systems and techniques have been tried to replicate ocean waves in a man-made environment. Some of these systems include directing a fast moving, relatively shallow sheet of water against a solid sculpted waveform to produce a water effect that is ridable but is not actually a wave. Other systems use linearly-actuated paddles, hydraulics or pneumatics caissons or simply large controlled injections of water to generate actual waves. However, all of these systems are inefficient in transferring energy to the “wave”, and none of these systems, for various reasons and shortcomings, have yet to come close to generating a wave that replicates the desired size, form, speed and break of the most desirable waves that are sought to be ridden, i.e. waves entering shallow water that plunge, breaking with a tube and which have a relatively long duration and sufficient face for the surfer to maneuver.
This document presents a wave generator system and wave pool that generates surface gravity waves that can be ridden by a user on a surfboard.
The wave pool includes a pool for containing water and defining a channel having a first side wall, a second side wall, and a bottom with a contour that slopes upward from a deep area proximate the first side wall toward a sill defined by the second side wall. The wave pool further includes at least one foil at least partially submerged in the water near the side wall, and being adapted for movement by a moving mechanism in a direction along the side wall for generating at least one wave in the channel that forms a breaking wave on the sill; and
In aspect, the wave pool includes one or more passive flow control mechanisms to mitigate a mean flow of the water induced by the movement of the at least one foil in the direction along the side wall. In another aspect, the wave pool includes one or more passive current control gutter mechanisms to mitigate currents in the water induced by the movement of the at least one foil in the direction along the side wall. In yet another aspect, the wave pool includes a passive chop and seich control mechanism to mitigate random chop and seich in the water at least partially induced by the movement of the at least one foil in the direction along the side wall, and at least partially induced by a shape and the contour of the channel. In still yet another aspect, the wave pool can include any or all of the aforementioned control mechanisms for controlling and/or minimizing water flow, chop or auxiliary waves besides a main surface gravity wave generated by each of the at least one foil.
The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims.
These and other aspects will now be described in detail with reference to the following drawings.
Like reference symbols in the various drawings indicate like elements.
This document describes an apparatus, method, and system to generate waves of a desired surfability. Surfability depends on wave angle, wave speed, wave slope (i.e. steepness), breaker type, bottom slope and depth, curvature, refraction and focusing. Much detail is devoted to solitary waves as they have characteristics that make them particularly advantageous for generation by the apparatus, method and system presented here. As used herein, the term “solitary wave” is used to describe a shallow water wave, or “surface gravity wave” having a single principal displacement of water above a mean water level. A solitary wave propagates without dispersion. It very closely resembles the type of wave that produces favorable surf in the ocean. A theoretically-perfect solitary wave arises from a balance between dispersion and nonlinearity, such that the wave is able to travel long distances while preserving its shape and form, without obstruction by counteracting waves. A wave form of a solitary wave is a function of distance x and time t, and can be characterized by the following equation:
where A is the maximum amplitude, or height, of the wave above the water surface, h0 is the depth of the water, g is the acceleration of gravity and η(x,t) is the height of the water above h0. The length of a solitary wave, while theoretically infinite, is limited by water surface elevation, and can be defined as:
Pools
The systems, apparatuses and methods described herein use a pool of water in which solitary type or other surface gravity waves are generated. In some preferred implementations, the pool can be circular or annular, being defined by an outer wall or edge that has a diameter of 200 to 800 feet or more. Alternatively, a round or circular pool having a diameter of less than 200 feet can be used, however, a diameter of 450 to 550 feet may be preferred. In one exemplary implementation, the pool can be annular with a center circular island that defines a channel or trough. In this annular configuration, the pool has an outer diameter of 550 feet and a channel width of at least 50 feet, although the channel can have a width of 150 feet or more, which can yield 30-100 feet of rideable wave length.
In another exemplary implementation, the pool can be a contiguous basin such as a circular pool without a center island. In the circular configuration, the pool can have a bottom that slopes up toward the center to a shoal or sill, and may include a deeper trough or lead to a shallow sill or flat surface. In yet other implementations, the pool can be any closed-loop, curvilinear channel, such as a racetrack shape (i.e. truncated circle), oval, or other rounded shape. In still other implementations, the pool can include an open or closed looped linear or curvilinear channel through which water is flowed (such as a crescent shape or a simple linear canal), and which may or may not use a water recapture or recirculation and flow mechanism.
Wave Generator
The bottom contour of the pool can further include a slope 204 that rises upward from the deep region 202. The slope 204 can range in angle from 1 to 16 degrees, and also from 5 to 10 degrees. The slope 204 can be linear or curved, and may include indentions, undulations, or other geometrical features. The bottom contour can further include a shoal 206 or sill. The surface from a point on the slope 204 and the shoal 206 can provide the primary break zone for a generated wave. Wave setup in the break zone can change the mean water level. The shoal 206 can be flattened or curved, and can transition into a flattened shallow planar region 208, a shallow trench 210, or a deep trench 212, or any alternating combination thereof. The basin side opposite the wave generator ultimately ends in a sloping beach.
The shoal 206 can also be an extension of the slope 204 and terminate directly into a beach. The beach may be real or artificial. The beach may incorporate water evacuation systems which can include grates through which the water can pass down into. The water evacuation systems may be linked to the general water recirculation and/or filtering systems, any may incorporate more advanced flow redirection features. The beach may also incorporate wave damping baffles that help to minimize the reflection of the waves and reduce along shore transport and currents.
The bottom contour can be formed of a rigid material and can be overlaid by a synthetic coating. In some implementations, the bottom may be covered with sections of softer more flexible materials, for example a foam reef or covering may be introduced that would be more forgiving during wipeouts. For example, the coating can be thicker at the shoal 206 or within the break zone. The coating can be formed of a layer that is less rigid than the rigid material used for the bottom contour, and may even be shock dampening. The slope 204, shoal 206 and/or other regions of the bottom contour can be formed by one or more removable inserts. Further, any part of the bottom contour may be dynamically reconfigurable and adjustable, to change the general shape and geometry of the bottom contour. For example, the bottom contour may be changed on-the-fly, such as with the assistance of motorized mechanics, inflatable bladders, simple manual exchange, or other similar dynamic shaping mechanisms. In addition, removable inserts or modules can be connected with a solid floor making up a part of the pool, including the bottom contour. The inserts or modules can be uniform about the circle, or variable for creating recurring reefs defined by undulations in the slope 204 or shoal 206. In this way particular shaped modules can be introduced at specific locations to create a section with a desirable surf break.
The wave generators may also be configured to run in the center of the channel in which case there would be beaches on both the inner and outer walls and the track/rail mechanism would be supported either from an overhead structure or by direct attachment to the floor of the pool.
Foils
Some implementations of the wave pools described herein can use one or more foils for generating waves of a desired surfability. The foils can be shaped for generating waves in supercritical flow, i.e. the foils move faster than the speed of the generated waves. This can allow for significant peel angle as the wave is inclined with the radius. The speed of a wave in shallow water (when the water depth is comparable to the wave length) can be represented by VW:
VW=√{square root over (g(ho+A))}
where g is the force of gravity, and ho is the depth of the water and A in the wave amplitude. Criticality can be represented by the Froude number (Fr), in which a number greater than 1 is supercritical, and a number less than 1 is subcritical:
Fr=VF/VW, where VF is the velocity of the foil relative to the water
The foils can be adapted to propagate the wave away from a leading portion of the foil as the water and foil move relative to each other. This movement may be able to achieve the most direct transfer of mechanical energy to the wave. In this manner, ideal swells can be formed immediately adjacent to the leading portion of the foil. The foils can be optimized for generating the largest possible swell height for a given water depth. However, some foils can be configured to generate smaller swells.
In order to achieve the best energy transfer from the foil to the wave and to ensure that the generated swell is clean and relatively solitary, the foils can be designed to impart a motion to the water that is close to a solution of a known wave equation. In this way it may not be necessary for the wave to have to form from a somewhat arbitrary disturbance as is done with some other wave generation systems. The proposed procedure can rely on matching the displacement imparted by the foil at each location to the natural (theoretical) displacement field of the wave. For a fixed location through which the foil will pass P, the direction normal to the foil can be x and the thickness of the part of the foil currently at P can be X(t).
The rate of change of X at the point P may be matched with the depth averaged velocity of the wave ū. This can be shown expressed in equation (1).
Applying the change of variable from (x,t) to (θ=ct−X,t) where c is the phase speed of the wave.
In equation (2) the depth averaged velocity of the wave ū can be given by any of a number of different theories. For the case of solitary waves, which generally take the form of equation 3 and 4 below, several examples can be provided. This technique of foil design may also apply to any other form of surface gravity wave for which there is a known, computed, measured or approximated solution.
Here η(θ) is the free surface elevation from rest, A is the solitary wave amplitude, ho is the mean water depth, β is the outskirts decay coefficient, c is the phase speed, and ū(θ) is the depth averaged horizontal velocity. C and β can differ for different solitary waves.
Combining equations (2) and (3) with (4) can give the rate of change of the foil thickness in time at a fixed position (5), and can be related to the foil shape X(Y), through the foil velocity VF, by substituting t=Y/VF
A maximum thickness of foil can be given from (5) as:
The length of the active section of the foil can then be approximated as:
Values for C and β corresponding to the solitary wave of Rayleigh can be:
In this example for small displacements after linearization the foil shape X(Y), can be approximated as.
This solution can also be approximated with a hyperbolic tangent function. These foil shapes, as described by at least some of the mathematical functions, would have extremely thin leading edges which would be structurally unstable. The actual leading edges would be truncated at a suitable thickness typically of 3-12 inches, and rounded to provide a more rigid leading edge. The rounding may be symmetrical or not and in some implementations may loosely follow the shape of an ellipse.
As shown in an exemplary configuration in
In some implementations, the foils 500 are shaped and formed to a specific geometry based on a transformation into a function of space from an analogy to an equation as a function of time. Hyperbolic tangent functions that mathematically define the stroke of a piston as a function of time, such that the piston pushes a wave plate to create a shallow water wave that propagates away from the wave plate. These hyperbolic tangent functions consider the position of the wave plate relative to the position of the generated wave in a long wave generation model, and produce an acceptable profile for both solitary and cnoidal waves. These techniques can be used to generate any propagating surface gravity wave accounting for the propagation of the wave away from the generator during generation (i.e. adapt to how the wave is changing during generation). Compensation for movement of the generator over time and the specific shape of the recovery section can assist in removing trailing oscillatory waves, which can provide a more compact and efficient generation process. Other types of waves to those discussed here can be defined.
The thickness of the foil can be related to the amplitude (height) of the wave and the depth of the water. Accordingly, for a known depth and a desired amplitude A, it can be determined that a thickness of the foil, FT, can be given approximately by:
For a Rayleigh solitary wave:
For a Boussenesq solitary wave:
For shallow water, second order solitary wave:
Virtual Bottom
In some implementations, a system of jets positioned near the bottom of the pool on the slope can simulate the water being shallower than it actually is which can allow the wave to break in deeper water than what could otherwise be achieved. These jets may be positional so as to generate both mean flow and turbulence at a required level. The distribution of these jets may change both radially and in the direction from the outer wall towards the beach with more jets on the beach. There may also be azimuthal variation in the nature and quantity of the jets. This jet system may be incorporated with both the filtering system and the wave system to provide mean flow or lazy river mitigation. Roughness elements may be added to the bottom of the pool to promote the generation of turbulence that may promote changes in the form of the breaking wave. The distribution and size of the roughness elements can be a function of both radius and azimuth. The roughness elements may take the form of classical and novel vortex generators and are described below.
Mean Flow
A moving foil or set of foils within a pool, particularly a circular basin as described above, will eventually generate a mean flow or “lazy river” effect, where water in the pool will develop a slight current in the direction of the one or more moving foils.
In other implementations, a pool can include a system to provide or counter a mean flow or circulation. The system may include a number of flow jets through which water is pumped to counter or mitigate any “lazy river” flow created by the moving foils, and/or help to change the shape of the breaking wave. The mean circulation may have vertical or horizontal variability. Other mean flow systems may be used, such as a counter-rotational opposing side, bottom or other mechanism.
Passive “Lazy River” Flow Control
In some implementations, as shown in
The interactions between the mean flow with the vortex generators can increase the Reynolds stresses and overall turbulence intensity in the vicinity of the hydrofoil path which can provide for thicker boundary layers in the water. These enhanced boundary layers can dissipate substantially more energy than an equivalent-sized smooth surface. Additionally, the transport of momentum by turbulent diffusion, specifically associated with the larger vortices, can allow the basin floor or wall areas covered with the vortex generators to provide strong sinks for both azimuthal and radial momentum. In effect these elements can allow the fluid within the basin to better transmit a torque to the basin itself.
While each vortex generator can have a squared cross section, as shown in
In order to facilitate cleaning of the vortex generators and pool, and to avoid the collection of debris in the corners in and around the vortex generators, some implementations may opt for smooth (curved) pool profiles 1500 where the vortex generators meet the side walls or floor, as shown by way of example in
In some implementations, the vortex generators can be formed out of a rigid or solid material and can be permanently affixed to the pool. For example, the vortex generators may be made of concrete reinforced with rebar and integrated into the basin structure. In other implementations, the vortex generators may be modular and attached with bolts, or constructed of plastic, carbon fiber, or other less rigid or solid material. These modular vortex generators can also allow for custom configuration of variable spacing, sizes and orientation. For instance, various combinations and arrangements of fixed and modular vortex generators may be employed.
Gutter System to Counter Azimuthal Currents (Vaned Cavity Gutters)
The previously discussed systems, such as vortex generators, roughness enhancement and other protrusions or flaps, can be configured to reduce lazy river flows by increasing turbulent dissipation within the flow. Additionally, these systems can act as a sink or inhibitor for both the mean azimuthal/longitudinal momentum and also the alternating currents in the radial/transverse and vertical directions. Alternatively, or additionally, azimuthal/longitudinal flow can be redirected by a gutter system employed at an inner beach area of the circular, crescent shaped or linear basin (“inside gutter system”), at an outer wall of the basin (“outer gutter system”), or both. The basic principal of these flow redirection gutters can be to capture the kinetic energy of the flow as potential energy by running it up a slope. The fluid can then be returned to the basin with a different velocity vector direction to that with which it arrived. This redirection can be accomplished with a system of vanes, but other means such as tubes or channels can also be implemented.
In some implementations, the gutter system includes a sloped floor overlaid by a water-permeable, perforated grate, typically of 25-40% open area. In this case for an inside (sloped beach) gutter system, the slope of the grating can be greater than the slope of the angled floors or beach, forming a cavity between the sloped floor of the beach and the more steeply sloped grating that extends around the center island in the basin. For a 500 ft diameter circular wave pool with wave generation around the outer perimeter, the cavity may extend 20-40 ft. away from the island with the bottom floor being sloped at approximately 5-9 degrees and the perforated gratings forming the top cover of the cavity being sloped at approximately 10-20 degrees. The slopes may be chosen differently for smaller or larger pools, with larger pools requiring less steep slopes and smaller pools requiring a somewhat steeper slope.
This cavity alone can absorb wave energy and reduce reflected waves generated from the movement of the foil around the basin. Additionally, the cavity can reduce the azimuthal currents near the sloped beach through simple dissipative mechanisms as water entering through the gratings may encounter enhanced turbulence. For a circular wave pool implementation, the importance of reducing the currents near the central island cannot be overstated. When there are significant currents parallel to the shore in the direction that the wave is breaking the currents can allow the wave to “overtake itself” requiring the wave generating mechanism to move at a higher speed if the form of the wave barrel is to be preserved. It is these currents that can tend to limit the minimum operational speed of the wave, whether it is generated by a hydrofoil type system or some other type of wave generator. This minimum operational speed where the wave will no longer barrel but instead presents itself as a foamy crest of white water is associated with a condition that has been dubbed “foam-balling”.
In other implementations, and as illustrated in
In some implementations, the gutter system can provide complete or near-complete current reversal proximate the gutter. The importance of these vaned cavity gutter systems in their ability to mitigate the detrimental effects of foam-balling on the tube of the wave where a surfer may be riding is related to the extent to which their effects can be propagated away from the island. For this reason it is important that the vanes that redirect the flow be angled so as to inject the redirected flow into the interior of the basin away from the island. Typical configurations call for these vanes be angled at 45-70 degrees from the radius around a vertical axis. The exact angle will depend somewhat on the specific bathimetry of the basin, but in general there is a tradeoff where more steeply angled vanes will perform better at redirecting the currents, and less steeply angled vanes will better transfer the redirected fluid to the interior of the basin, slowing the wave at that location.
The vanes are angled both relative to a radius from the inner island 1402, as well as to the horizontal forming a triangle to accommodate the slope of the grating over the vanes.
A further implementation of the flow redirection gutter system includes allowing the water that enters between any two vanes 1700 to run up the slope as described above. Upon approaching the highest point of the run-up, some of the flow is redirected to the adjacent gutter through a sloped opening 1720. In this way the flow is ratcheted around the beach further enhancing the cross shore transport.
Wave Absorbing and Phase Cancellation Gutters
In accordance some implementations of a wave pool using an annular basin, both the exterior and interior boundaries of the annular basin can be fitted with gutters and/or baffles that are configured to limit both the reflection of any incident waves that may be generated by the passage of a wave generating hydrofoil, and also reduce the persistence of the general random chop within the basin. For example, the gutters and/or baffles can be configured to control particular seiching modes, or other waves of known wavelength that are present within the basin. As illustrated in
In some implementations, a gutter 1500 can include a simple vertical porous plate of approximately 20% to 50% open area, and preferably about 33% open area which can form a cavity between the outer wall and the hydrofoil path. The cavity width can be tuned for optimal phase cancellation, as described in further detail below.
In some implementations, the gutters are provided in the basin and are adapted for limiting the vertical displacements and reflected energy associated with any trailing, or recovery, waves generated by a moving foil or other wave generating device. This may involve the use of a horizontal splitter plate or step 1508 set at a height h1 that is typically 0.2 h-0.4 h. In the case of a step the volume under the horizontal plate is filled, while for a splitter plate this volume is left open, in another variation the step replaces the horizontal splitter plate in the form of a vertical solid wall that extends from the bottom up to the height typically associated with the horizontal splitter plate. These gutters can also be integrated with azimuthal flow control and redirection systems, as described in the above section.
If there were no perforated wall, the node may occur at a distance of L/4 from the back wall of the basin, and the largest energy loss may also occur at this distance. However, due to the inertial resistance at the porous wall, a phase change can occur inside the gap which can slow the waves. This makes the distance for maximum energy loss to occur smaller than L/4. As can be seen in
A relationship between the wavelength of the wave incident on the gutter (L) and that of the wave inside the gutter cavity (L1) can be such that L>L1. This wavelength reduction can be due to dispersion and can allow for the use of smaller width gutters that would otherwise be required.
Note that there can be a similar effect when a splitter plate is used and the condition for minimum reflection can occur at a ratio of approximately b/L, which can be less than a corresponding ratio for a wave chamber without the splitter plate. This can be due to the waves in the gutter becoming shorter over the submerged plate and hence slowing down.
Additional implementations of a gutter 2000 are shown, for example, in
Note a non-perforated step 2500 that differentiates the gutter shown in
Horizontal and vertical slots or piles have different properties. Vertical slots or piles, when adequately spaced and sized, have a property that when the waves impact the vertical slots or piles obliquely, the incident and reflected paths can be different. For horizontally aligned piles or slots, obliqueness can have no effect and the submersion of the slot or pile closer to the still water level can be of importance as it can allow smaller scale chop or waves to enter exit the gutter area. Additionally, small variations in the water level can be used to adjust the relative depth of the horizontal pile or slot.
The porous walls for some gutter systems may also be integrated with vortex-generating roughness elements, such as described above, these can be seen on the lower wall of
Although a few embodiments have been described in detail above, other modifications are possible. Other embodiments may be within the scope of the following claims.
This application is a continuation and claims the benefit of priority under 35 U.S.C. § 120 of U.S. patent application Ser. No. 16/292,272 filed Mar. 4, 2019 entitled “Surface Gravity Wave Generator and Wave Pool” which is a continuation and claims the benefit of priority under 35 U.S.C. § 120 of U.S. patent application Ser. No. 15/435,205 (now issued U.S. Pat. No. 10,221,582), filed Feb. 16, 2017, entitled “Surface Gravity Wave Generator And Wave Pool” which is a continuation and claims the benefit of priority under 35 U.S.C. § 120 of U.S. patent application Ser. No. 13/612,716 (now issued U.S. Pat. No. 9,574,360), filed Sep. 12, 2012, entitled “Surface Gravity Wave Generator And Wave Pool” which is a continuation-in-part and claims the benefit of priority under 35 U.S.C. § 120 of U.S. patent application Ser. No. 13/609,239 (now issued U.S. Pat. No. 8,573,887), filed Sep. 10, 2012, entitled “Surface Gravity Wave Generator And Wave Pool”, which is a Continuation of U.S. patent application Ser. No. 12/274,321 (now issued U.S. Pat. No. 8,262,316), filed Nov. 19, 2008, entitled “Surface Gravity Wave Generator And Wave Pool”, which the disclosures of the priority applications are incorporated by reference herein.
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