WO2018149969A1 - Wave installation for a static wave - Google Patents

Abstract

A wave installation for generating an artificial wave (14), having a supply basin (16) and a wave basin (11) and having at least one delivery means, in particular at least one pump (15), for delivering liquid from the supply basin (16) to the wave basin (11). The wave basin (11) is designed for a liquid to flow through it from an inlet (20) to an outlet (21) so as to form a static wave (14), with at least one wave excitation element arranged in the wave basin (11). The wave installation is characterized in that an intermediate basin (17) is provided, which has an outlet that is fluidically connected to the inlet of the wave basin (11).

Description

 WAVING FOR A STANDING WAVE Description

The invention relates to a shaft system according to the preamble of claim 1. The shaft systems described here are not only suitable for mobile, but especially for stationary use with generally increased demands on operational safety.

The wave surfing developed as a sport as well as a recreational activity, an increasing appeal to water and recreational athletes. The surfer uses the formation of waves in a liquid, which is typically water. The wave must therefore be suitable for carrying the surfer on a surfboard. As a rule, these are so-called standing waves, ie essentially stationary wave crests. Optionally, but also progressive waves can be used. In the midst of a suitable shift of weight on the surfboard, the surfer can reach his position on the wave or wave crest.

In the practice of his sport, the surfer is typically dependent on suitable conditions in natural moving waters, such as rivers or even the open sea, prevail, just allow the formation of appropriate waves in order to then use them for surfing. Depending on the boundary conditions, such waves are either standing waves, such as in rivers or canals with barrages, obstacles or the like, or even running waves, such as in the open sea.

Recently, technical developments of artificial wave systems with the purpose of providing artificial waves have been started pushed for surfing. This is intended to reduce the surfers' dependence on the presence of natural wave training conditions. Ultimately, the goal of these developments is to replicate natural waves for surfing artificially. Typically, this is done in the form of artificial standing waves to keep space and effort of the wave system within manageable limits.

It is provided by means of at least one pump as a subsidy or possibly also by using a flow from an existing flowing water for a liquid flow in or through a wave pool. Thus, the liquid may flow from an inlet to an outlet of the wave pool. This ideally laminar flow of liquid can then, in particular due to a disturbance, form a substantially stationary wave crest on which the surfer can then surf with his surfboard. In particular, at least one wave exciter, such as an unevenness, an edge, a guide element or the like, serves as a disturbance.

An artificial wave plant is known, which has a wave pool and a reservoir. The water used as liquid is pumped simultaneously by means of several serving as a conveyor pumps by separate conveyor lines directly from a storage tank and a sloping ramp in a wave pool in which a standing wave is excited by a guide. From the wave pool, the water then flows back into the reservoir.

The disadvantage of this is in particular that in case of failure or shutdown already a pump, the flow in the wave pool is at least inhomogeneous or even turbulent. A failure of a conveyor therefore already puts the whole system down. In addition, no energy-saving operation by switching off individual funds is possible without considerable effort in driving and operation of the funds used is driven. It is therefore an object of the invention to eliminate the disadvantages described. In particular, the most cost-effective, reliable and energy-saving construction and operation of the shaft system should be ensured. This object is achieved by an artificial wave system with the features of claim 1. Such a wave system is provided for generating an artificial water wave for surfing. For this purpose, it has a reservoir (reservoir) and a wave pool. The basins can at least partially also be closed tanks. In addition, at least one conveying means, in particular at least one pump, is provided for conveying liquid from the supply basin into the wave basin. The wave pool is formed by a liquid from an inlet to a Ausiass for forming a standing wave can be flowed through, wherein at least one arranged in the wave pool wave excitation element is provided. The shaft system according to the invention is characterized in that an intermediate basin is provided, which has a Ausiass, which is in flow communication with the inlet of the wave pool. Thus, the intermediate basin serves to receive the liquid conveyed by the at least one conveying means and to discharge into the wave basin. The liquid is thus promoted in particular by the wave pool in the intermediate basin to be discharged from there back into the wave pool.

In a particularly preferred embodiment of the invention, several conveying means or, ideally, all conveying means jointly convey into an intermediate basin, into one of the intermediate basins or, ideally, into the single intermediate basin. Thus, the at least one intermediate basin can be used as a buffer for the delivery of the liquid. The outflow of liquid through the Ausiass depends on the funding in particular practically only on the flow rate or the liquid level in the basin. It can thus be achieved a particularly uniform outflow.

Preferably, the intermediate basin is arranged fluidically between the reservoir and wave pool. This means that the flow direction of the liquid from the reservoir basin towards the wave pool or in this runs. However, this also includes that the liquid is conveyed at least in sections in this direction. In particular, the intermediate basin is arranged in the flow direction or conveying direction after the reservoir tank and before the waves basin, so in fact between these two. The spatial position of the pelvis may differ. The intermediate basin does not have to, but may be located spatially between the reservoir and the wave pool.

In particular, a flow path is provided in the region between the outlet of the intermediate basin and the inlet of the wave basin. This can contribute to the reduction of turbulence as well as to the formation of a laminar flow. The flow path is further preferably formed at least in sections in the form of a preferably sloping surface or ramp. The flow path is further preferably formed at least partially adjustable in their inclination. Thus, the flow velocity can be varied at the flow path.

In fact, discharge of liquid into the wave pool occurs just when a particular condition occurs. When reaching or exceeding a predetermined level in the intermediate tank preferably a discharge of liquid in the wave pool. This means that the level has reached a level that allows drainage from the intermediate basin. The liquid capacity of the intermediate basin is preferably smaller than that of the wave pool, but may also be similar or even larger. Possibly, the intermediate basin can also be designed variably in size or capacity, for example by adjustable wall or floor elements. This can be done to adjust the amount of liquid contained in the pool or dispensed. An adjustment may also be provided for varying the fluid intake and / or fluid delivery during operation of the system.

Preferably, the at least one conveying means is arranged in the region of a fluidic connection between supply basin and intermediate basin. This makes it possible to directly convey the liquid from the storage tank into the intermediate tank. Further preferably acts it is in the fluidic connection to a breakthrough and / or pipe section, which is respectively arranged between the storage tank and the intermediate basin and this preferably connects to each other. As a fluidic connection while a connection between two containers is considered, which is provided for the forwarding of liquid.

More preferably, each of the conveying means is arranged in or on a separate fluidic connection between the reservoir and the intermediate basin. Thus, a separate connection is provided for each conveyor. In particular, it can be a flow channel, such as a pipeline, a channel, a hose, a gutter, a basin or the like. So promotes each funding through its own fluidic connection, preferably its own flow channel. The flow channel preferably has a similar cross-section as the conveyor. Thus, an optimal, preferably laminar or turbulence-free promotion of the liquid can be achieved.

The at least one conveying means, preferably a plurality of the conveying means or all conveying means, is associated in each case with one or at least one reflow prevention means. This ensures that when the conveyor is deactivated no liquid can escape through the flow channel of the opposite to the conveying direction. This prevents the intermediate basin from emptying when individual conveyors are at a standstill. The backflow prevention means is designed in particular as a non-return valve, valve or the like. This allows a simple but reliable function, especially in a design as a non-return valve. The at least one backflow prevention means works in particular automatically, so it opens and / or closes preferably automatically. Optionally, an alternative or additional manual and / or mechanical, in particular motor operation of the backflow prevention means may be provided, so a corresponding opening and / or closing. Preferably, the backflow prevention means operate independently of each other. Thus, an individual operation of the funds can be done. It may preferably be a possibility of locking the at least one Reflux preventive be provided. Thus, a flow through individual funding can be selectively prevented or made possible, for example, for control purposes or for maintenance purposes. The outlet of the intermediate basin is in particular adjustable. The adjustability is preferably provided at least with respect to the cross section of the outlet and / or the liquid level in the intermediate basin. Thus, the discharged amount of liquid can be regulated, in particular with regard to the flow behavior. For this purpose, at least one adjusting means can be provided. This may in particular be a preferably adjustable and / or pivotable flap, ramp, gutter, a slide, a valve or the like. The adjustment can be done manually, but preferably by motor, in particular electrically, hydraulically, pneumatically or in another suitable manner.

More preferably, the outlet of the intermediate basin is designed as at least one overflow. In particular, at least one overflow edge is provided. Preferably, the overflow is formed on or in the wall of the intermediate basin. An overflow ensures a trouble-free drainage of the liquid from the intermediate basin into the wave basin. In particular, thus, a laminar flow of the liquid can be achieved in the wave pool. The outlet of the intermediate basin is formed in a preferred embodiment of the invention as at least one breakthrough and / or pipe section. Preferably, the outlet is located in a wall of the intermediate basin. The overflow may be adjustable, in particular height adjustable.

The at least one conveying means is preferably designed as a pump, more preferably as an electrically driven pump. The drive of the pump is arranged in particular outside the liquid or the basin. This ensures a high degree of operational safety.

In particular, the conveying means or the conveying means may be at least one regulated pump. Preferably, several, preferably all conveying means are switched on and off, in particular individually or groups. Thus, the flow rate can be adjusted gradually. Further preferably, the power of at least one conveying means or a plurality of conveying means by means of at least one control device is adjustable, preferably stepped or graded, in particular individually or in groups. This allows a stepless or almost stepless adjustability of the flow rate to be achieved. Particularly preferably, a conveyor is designed controllable, while the remaining are only switchable. Thus, by switching on or off gradually, the power can be adjusted, while the regulated conveyor allows an additional setting of all intermediate values. For power control, a control electronics and / or a computer control can be provided.

Preferably, the at least one conveying means is provided directly only for conveying liquid from the supply tank into the intermediate basin. A discharge of liquid from the intermediate basin takes place only indirectly due to the filling by the at least one conveying means. This means that the at least one conveying means fills the intermediate basin. Due to the amount of liquid present in the intermediate basin there is a discharge into the wave pool. For this purpose, the liquid exits the drain into the wave pool.

The at least one conveying means is preferably arranged in a lower region of the wave basin for filling the intermediate basin. Thus, in particular, liquid can be introduced in a simple manner from a lower reservoir. The outlet of the intermediate basin is furthermore preferably arranged in an upper region of the intermediate basin. This ensures that some level of fluid must be present before discharge of fluid through the outlet. Preferably, the intermediate basin is provided with one or at least one outflow means in the region of the outlet. The discharge means is preferably designed to convey and / or regulate the delivery of liquid to the wave pool. The discharge means can be designed in particular as a pump and / or valve. There may be several same or be present different discharge. This can be done a steering, regulation and / or promotion of the liquid flow.

Preferred embodiments of the invention are described below with reference to the drawings. In these show:

Fig. 1 is a side sectional view of a Wellenaniage invention

2, the shaft system of FIG. 1 is in operation, FIG.

Fig. 3 is a side detail view of a shaft system according to the invention, and Fig. 4 is a plan view of the area of the intermediate basin.

In Figures 1 and 2, a Wellenaniage 10 is shown in a side, partial sectional view.

The shaft system 10 has a wave basin 11 with a guide device 12. The guide device 12 serves to excite a wave 14 in a flowing liquid, such as the water 13 shown here, as shown in FIG. 2. As a guide 12 here a quarter-circle-shaped element is used, which is pivotable about a horizontal axis of rotation up and down. The guide device 12 is completely retractable in a recess or depression at the bottom of the wave tank 11 in order to achieve a smooth bottom. In operation, the guide device 12 is pivotable out of this recess in order to be able to excite a shaft 14. For example, it may alternatively also be a wing-like or louvered construction of the guide device 12.

The water 13 is conveyed in the illustrated embodiment by means of a pump 15 or feed pump as a subsidy from a main basin or storage tank 16 via a conveyor line 17 into the wave pool 1 1. In the following, some examples only speak of a pump 15, Whatever the number of pumps 15 are conceivable or vice versa instead of multiple pumps only one pump 15th

According to the invention, an intermediate basin 17 is present. This is mitteis the pump 15 filled with water 13 as a liquid. For this purpose, 16 pipe sections 18 are arranged in the lower region of the intermediate basin 17 as well as the reservoir. These pipe sections 18 serve as a fluidic connection between the tanks 16 and 17. In order to be able to transport water from the storage tank 16 into the intermediate basin 17, the pumps 15 are arranged there. In the present embodiment, the pumps 15 are arranged with their pump rotors just inside the pipe sections 18. The pump rotors ideally fill the respective cross-section of the pipe sections 18 for a flow that is as laminar as possible. When operating the pumps 15, the water is pumped into the intermediate basin 17.

The pumps 15 each shown here as an impeller are each arranged with a motor drive 19. In this case, the motor drive 19 is an electric motor. The pipe section 18 serves in this case as an inlet 20 for sucking water 13 into the intermediate basin 17. The inlet 20 is arranged for this purpose in the storage tank 16, usefully below the water level. At the top of the drawing and then to the outlet 21 of the intermediate basin 17 is here still exemplified a ramp 22, through which the water 13 is passed into the actual wave pool 11. This ramp 22 may optionally be omitted. Because of the ramp 22 running down at a shallow angle, a flow of the liquid 13 which is accelerated but rather essentially laminar develops here. The laminar instead of turbulent flow is in particular due to the water 13 flowing out of the intermediate basin 17 instead of directly turbulently pumped water 13 reached. At the right end of the wave pool 11, a drain 23 for the water 13 is present. Through this drain 23 through the water 13 can flow back into the main basin 16. The drain 23 may be formed, for example, as a perforated plate or grate to let pass the large amounts of water can occur.

In the present case, only a single pump 15 is shown in the sectional view of FIGS. 1, 2 and 3. In practice, however, several pumps 15 are typically arranged next to each other here, as shown in FIG. 4. This is necessary in order to be able to provide the required throughput of water 13 on the widest possible surface of the wave pool 11.

In order to be able to control the throughput by means of the pumps 15, it is possible to regulate all pumps 15 in terms of their power. Since this is disadvantageous for cost reasons, according to the invention, only a single pump 15 can be designed to be adjustable if the other pumps 15 can be switched on and off at least individually. One of the pumps 15 can be selected. In addition, the check valves 29 shown here in this case only one controllable pump 15 are particularly important. These check valves 29 are equipped in a conventional manner with pivot axes 30 so that they can release or close the pipe sections 18 depending on the water pressure and flow. They thus serve to shut off the associated pipe section 18 when switching off a pump 15 and thus to prevent the outflow of water 13 into the storage tank 16. It may also be provided seals on the check valves 29.

In FIGS. 1 and 2 an arrangement of the check valves 29 in front of the pumps in the pipe section 18 is shown by way of example. Alternatively, FIGS. 3 and 4 show, for the sake of completeness, exemplary arrangements of the check valves 29 in terms of flow, downstream of the pumps 15, that is to say in the intermediate basin 17.

By selective connection of pumps 15 and setting of intermediate values by a controllable pump 15 can be virtually any Flow rates set between zero and maximum power of all pumps 15. The pump power can also be controlled in addition, in particular continuously variable, but it does not have a sufficient number of independent pumps 15.

In addition, the intermediate basin 17 serves to store and calm a lot of water 13 between. The effluent from the intermediate basin 17 via an overflow edge at the outlet 21 is practically almost always laminar, regardless of which and in which composition the pumps 15 operate.

In the illustration of FIG. 1, therefore, the shaft system 10 is initially shown at rest or in sleep mode. So here are the pumps 15 are not in operation, so that no water 13 is promoted. Consequently, no wave 14 can form in this case.

When the shaft assembly 10 is put into operation, the at least one pump 15 ensures that the water 13 is conveyed from the reservoir 16 into the wave pool 11. The reservoir tank 16 serves accordingly as a reservoir for the water 13. The conveyed into the wave pool 11 water 13 flows through this in the direction of the drain 23. There it flows down into the reservoir 16. The flow direction of the water 13 is indicated by arrows.

In the rest state of the wave system 10 is in the present embodiment, the water level here below the lower edge of the wave tank 11. Accordingly, the water 13 after switching off the pump 15 flows almost completely out of the wave pool 1 1 out. After this short drainage phase, the water level in the wave basin 11 in the idle state of the pumps, the water 13 is virtually zero.

As soon as the pumps 15 are switched on again in the operating mode, the wave pool 11 fills immediately again up to a certain minimum height. Thus, in the operating state always a certain amount of water 13 in the wave tank 1 1 available. On the other hand, this avoids, however, at the same time, that even when at rest, there is still a significant amount Water 13 is present in the wave pool 11, which may need to be monitored and possibly cleaned.

Since the amount of water pumped by the pumps 15 is relatively large compared to the capacity of the drain 23, a certain amount of water 13 will be permanently present in the wave tank 1 1 in the operating condition. Thus, this water 13 in the wave pool 11 can ensure that a shaft 14 can be excited by means of the guide device 12. The drain 23 may for this purpose also have a water level-dependent or height-dependent permeability. Thus, different free cross sections of the drain 23 may be provided, so that depending on the water level different throughputs of water 13 are possible. This means that a lower throughput of water 13 per unit of time is possible in the lower region of the outlet 23 than in its upper region. This can be ensured, for example, by differently formed openings in the outlet 23, that is to say in concrete terms, for example, different number of holes, hole size and / or hole spacing. For example, a height-dependent variation of the free cross-section may provide for lower throughput at the bottom and higher throughput at the top. Thus, after switching on the at least one pump 15, a rapid filling of the wave tank 1 1 to a minimum, and then ensure above this water level continuous flow. After switching off the at least one pump 15, the basin 11 can then idle again.

To drive the at least one pump 15, the already mentioned at least one drive motor 19 is provided. For each pump 15, a separate drive 19 is typically provided. Optionally, a plurality of pumps 15 may have a common drive 19. The drive 19 is arranged in the present case within the engine room 25. A cable 24 serves to supply the drive 19 with electrical energy. The cable 24 connects the drive 19 with a power supply 26 for the pump 15. The power supply 26 is disposed outside of the water 13. The drive 19 and the actual pump 15 are connected to each other in the usual way by a drive shaft 28. Serves here the drive shaft 28 for connecting the actual pump 15 with the separated drive 19 in a separate room 27. This is not shown here in detail implementation through the walls of the pump housing 17 as well as the space 25 required together with a corresponding storage and sealing. These mechanical seals, which are not shown here in detail, can be used without endangering the surfer. For example, glands or the like can be used for this purpose. Thus, in contrast to the prior art, only purely mechanical components are arranged in the water 13. Although the complex-built pumps 15 are provided with additional components for the transmission of mechanical power, so in particular corresponding feedthroughs and drive shafts 28. In addition, the pumps 15 are correspondingly efficient to select. As a result, however, a high level of safety against a risk of electric current is achieved.

By using an intermediate basin 17, a particularly well controllable and efficient operation of the shaft system 10 is made possible. The precise adjustability and the stabilization of the water 13 in the intermediate basin 17 caused by the buffering provide optimized conditions for the generation of a standing wave 14.

LIST OF REFERENCE NUMBERS

10 shaft system

11 wave pools

12 guide device

13 water

 14 wave

 15 pump

 16 reservoirs

17 intermediate pools

18 pipe section

19 drive

 20 injectors

 21 outlet

 22 ramp

 23 expiration

 24 cables

 25 engine room

26 power supply

28 drive shaft

29 non-return valve

30 pivot axis

Claims

claims

1. wave plant for generating an artificial wave (14), with a reservoir tank (16) and a wave pool (11) and with at least one conveying means, in particular at least one pump (15) for conveying liquid from the storage tank (16) in the Wave tank (11), wherein the wave pool (11) is formed by a liquid from an inlet (20) to an outlet (21) for forming a standing wave (14) can be flowed through with at least one in the wave pool (11) arranged wave excitation element, characterized in that an intermediate basin (17) is provided which has an outlet which is in fluid communication with the inlet of the wave pool (11).

2. Welienanlage according to claim 1, characterized in that several funds or all funding together in an intermediate basin (17) or in the single Zwi see basin (17) promote.

3. shaft system according to claim 1 or 2, characterized in that the intermediate basin (17) fluidly between the storage tank (16) and wave pool (11) is arranged, in particular in the conveying direction after the storage tank (16) and in front of the wave pool (11).

4. shaft system according to one of the preceding claims, characterized in that in the region between the outlet of the intermediate basin (17) and the inlet (20) of the wave pool (11) is provided a flow path, in particular at least partially in the form of a preferably sloping surface or ramp (22), wherein the flow path is preferably formed at least partially adjustable in their inclination.

5. shaft system according to one of the preceding claims, characterized in that due to reaching or exceeding a predetermined level in the intermediate basin (17) a discharge of liquid into the wave pool (11) takes place.

6. shaft installation according to one of the preceding claims, characterized in that the conveying means in the region of a fluidic connection between the reservoir tank (16) and intermediate basin (17) is arranged, preferably in or at an opening and / or pipe section (18) between the reservoir (16 ) and intermediate basin (17).

7. shaft installation according to one of the preceding claims, characterized in that each of the conveying means is arranged in or on a separate fluidic connection between the reservoir tank (16) and intermediate basin (17).

8. shaft system according to one of the preceding claims, characterized in that the at least one conveying means, preferably a plurality of the conveying means or all conveying means in each case at least one backflow prevention means, in particular a non-return valve (29) is assigned.

9. shaft installation according to one of the preceding claims, characterized in that the outlet of the intermediate basin (17) is adjustable, preferably at least with respect to its cross-section and / or the liquid level for dispensing liquid.

10. Shaft installation according to one of the preceding claims, characterized in that the outlet (21) of the intermediate basin (17) as at least one overflow, in particular with at least one overflow edge, and / or as at least one breakthrough and / or at least one pipe section (18 ) is formed, preferably on or in the wall of the intermediate basin (17), wherein the overflow is further preferably adjustable.

11. shaft system according to one of the preceding claims, characterized in that the at least one conveying means is designed as a pump (15), preferably as an electrically driven pump (15), wherein the Drive (19) of the pump (15) is arranged in particular outside of the liquid or the basin.

12. shaft installation according to one of the preceding claims, characterized in that the at least one conveying means is provided directly only for the promotion of liquid from the storage tank (16) in the intermediate basin (17), while a discharge of liquid from the intermediate basin (17) only indirectly due to the filling by the at least one conveyor.

13. shaft system according to one of the preceding claims, characterized in that the at least one conveying means for filling the intermediate basin (17) in a lower region of the wave tank (11) is arranged and that the outlet (21) of the intermediate basin (17) in an upper region of the intermediate basin (17) is arranged.

14. Shaft installation according to one of the preceding claims, characterized in that several, preferably all subsidies are switched on and off, in particular individually or in groups, and / or that the performance of at least one conveying means or more funding means of at least one control device is controlled, preferably stepped or continuously, in particular individually or in groups.

15. Shaft installation according to one of the preceding claims, characterized in that the intermediate basin (11) is provided with a Ausströmmittel in the region of the outlet (21), wherein the Ausströmmittel preferably for promoting and / or regulating the delivery of liquid to the wave pool ( 11) is formed, in particular as a pump and / or valve.