The current invention generally relates to fountains and displays involving water or other fluids that interact with walls or other structures to provide visual effects, including displays where water is shot towards a transparent, translucent or other type wall or structures.
Displays that include water fountains and water nozzles, lighting and other visual effects have existed for some time. For example, the water and light display in front of the Bellagio Hotel has entertained millions of people for years.
However, many existing water and light displays have limitations and other shortcomings.
As such, there continues to be a need for new and innovative displays that introduce new variables into the display to provide enhanced visual effects. For example, many existing water displays include water nozzles that shoot water into the air, but do not involve walls or other structures with which the water may interact. Accordingly, there is a need for a display wherein water or other liquid may interact with walls or other structures.
In a first aspect of the invention, a display is described including water and a structural component. The structural component may include a wall that may be glass or some other transparent or translucent material. Water may be shot at the wall or other structure to provide a visual effect such as a waterfall or a cascading wall of water. The angle at which the water is shot towards the wall and/or the flow rate of the water being shot may be varied, so that the visual effect may also be varied.
In another aspect of the invention, water may be shot from a manifold assembly including one or more nozzles to shoot water onto the wall or other structure. In a preferred embodiment, the manifold may comprise a pipe or tube having a number of water nozzles extending along its length. In this manner, a number of water streams may be shot at the wall or other structure. The manifold may also be rotated along its axis so that the direction of the water nozzles relative to the wall is varied. Multiple such manifolds may be used in the current invention which, when rotated, may provide many different streams of water striking the wall at different angles and/or patterns.
In another aspect of the invention, the placement of the water nozzles on the manifold(s) may be varied to provide different visual effects. For example, the nozzles may be located a certain distance apart and shoot water at the same angle. Alternatively, the direction of the nozzles may be varied so that water strikes the wall or other structure at different angles for a given manifold position.
In another aspect of the invention, the water nozzles may be individually controlled so that their directions may change relative to each other. Such water nozzles may also be connected to individual bases as opposed to all being connected to a manifold. The flow rate may also be changed for a number of nozzles at one time or for individual nozzles. The flow rate may be varied to achieve laminar or turbulent flow.
Another aspect of the invention involves the wall or other structure that water is shot at. For example, the wall may comprise glass which may provide a cascading and shimmering effect as the water impinges on the wall and flows downward. With a glass wall, observers may be located on the side of the wall opposite from the water nozzles. In this manner, the observers may be up close to the display itself. Alternatively, the observers may observe from the same side as the water nozzles. The glass wall may be clear, textured or translucent. With a textured surface, the appearance of the water interacting with the wall may be varied.
Another aspect of the invention involves the structure at which water is shot. For example, glass walls may be located adjacent to each other so that they form a tunnel through which observers may walk.
Yet another aspect of the invention involves an additional structural component that may be located separately from the first structural component. The additional structural component may include an additional wall that may be glass or some other transparent or translucent material. Water may be released from above the wall onto the front or back surfaces of the wall such that the water may flow downward upon the wall surfaces forming water flow effects. Different types of water formations may be delivered to the wall such as water droplets, water streams, water droplet blooms, water blooms, and other types of shapes and formations of water.
In one aspect of this additional structural component, water may be released onto the additional wall by water holes. In another aspect of this additional structural component, water may be emitted onto the additional wall by water shooters or nozzles. In yet another aspect of this additional structural component, water may be released onto the wall by a water fall component. The flow rate and water pressure of the emitted water may be controlled by one or more water pumps.
In another aspect of the invention, water may be released in close proximity to the additional wall to fall through the air in front of or behind the additional wall. Water may be release by water holes, water droppers, water nozzles and other types of water deliver devices. The flow rate and water pressure of the emitted water may be controlled by one or more water pumps.
Other aspects of the invention are discussed herein.
The display 10 of the current invention and the visual effects that it may produce are now described with reference to the figures. Where the same or similar components appear in more than one figure, they are identified by the same or similar reference numerals. The invention is described herein with reference to water. However, other liquids and combinations thereof are within the scope of the invention.
In general, display 10 provides dramatic visual effects by applying water to the surface of a structure such as a wall. For example, display 10 may shoot water onto a transparent wall from different distances and angles to be viewed by onlookers on either side of the wall.
In general, display 10 may include wall or structure 100 and water delivery assembly 200 which shoots water at wall or other structure 100. Light assemblies (not shown) which may be particularly suitable for use at night, and other accessories or features (not shown) may also be included in display 10.
As discussed in more detail below, water may shoot from water delivery assembly 200 onto wall assembly 100 from different locations and angles, and at different water pressures or flow rates to create a dramatic visual effect. Wall 100 may include water wall 102 with front surface 104 on which the water engages wall 102. Wall 102 may be formed of a transparent material such as glass so that water hitting water wall 102 may be viewed from either side of wall 102. In addition, illumination from lighting assemblies (not shown) may be added to further enhance the visual effect of the display.
Depending on the angle and water pressure at which the water is shot onto water wall 102, the water may adhere to and generally flow down water wall 102, or may splash off of water wall 102. Changing the angles and pressure of the water shot at water wall 102 may alter the appearance of the water as it engages wall 102 and flows down thus providing an entertaining water display effect.
In the embodiment of
Given its size, display 10 may provide a very dramatic entrance to a building such as a hotel to provide a very unique experience when entering the building that may serve as an attraction to the building itself. To this end, where the building is a hotel or other brand establishment, display 10 may enhance the brand. As noted above, display 10 of the current invention is not limited to large installations. For example, display 10 may be configured to be smaller and/or portable. To this end, a portable embodiment of the current invention may be temporarily set up for concerts, parks, museums or other events or locations.
Display 10 is now further described with reference to
Upon contacting front surface 104 of water wall 102, the water may generally may generally adhere and flow down front surface 104 where the water pressure is not exceeding large. Alternatively, where water pressure is increased, the water may splash off front surface 104 upon contact. In either situation, it is preferred that water is received by water trough 106. Water trough 106 may generally have a width that may correspond with the width of water wall 102 and may be generally positioned at the front base of water wall 102 and joined with front surface 104 such that water flowing down front surface 104 or splashing off of it is generally caught by water trough 106. Water received into water trough 106 may then be treated and returned to water supply 206 through water return pipe 210 to be recirculated to water manifold pipe 202 as desired.
Water wall assembly 100 is now further described with reference to
Observers may view water wall 102 from the sides or from above, for example, from the balcony of their hotel room. Front surface 104 may also be frosted or tinted of different colors. To this end, front surface 104 may comprise glass, acrylic, polycarbonate or other suitable materials and combinations thereof. Being transparent or translucent may also allow water splashing off of or flowing down wall 102 to be more easily seen by observers, especially when illuminated by lighting assemblies.
As an alternative, front surface 104 may be a solid color or opaque. In this embodiment, water wall 102 may be formed of materials such as stone, metal, mirrored materials or other suitable materials. In addition, front surface 104 may comprise any combination of transparent or translucent, and solid or opaque materials. As a further alternative, front surface 102 may comprise a generally solid structure, a sheet of material that may be rolled down from the top and secured into place, a mesh or any combination thereof. Accordingly, it should be noted that water wall 110 of the current invention is not limited to a solid wall in the conventional sense. Instead, water wall 110 may comprise any configuration on which water may be shot upon and travel downward.
Front surface 104 of water wall 102 may also be textured with ridges, bumps or other types of texturing, and such texturing may cover the majority of front surface 104 or only parts or subsections of front surface 104. Water traveling over textured areas of front surface 104 may appear visually different to viewers of water wall 102 compared to water traveling over areas of front surface 104 that may not include texturing. In addition, front surface 104 may include a variety of different types of texturing with each type of texturing positioned in different areas or subsections of front surface 104, or in patterns or shapes upon front surface 104, such that water cascading down front surface 104 and traveling over the one type of texturing may appear different compared to water traveling over a different type of texturing. To this effect, front surface 104 may include different texturing that may form patterns or pictures of different abstract or recognizable forms or shapes. For example, front surface 104 may include texturing that may form the logo of a brand, or the name of the hotel where display 10 may be installed.
In addition, front surface 104 may include channels, ridges, laser etchings or other similar types of elements that may act to guide water that may be traveling down front surface 104 to form different shapes as the water passes down front surface 104. In the example from above, these channels or ridges may form the name and logo of the brand that may own or sponsor display 10, such that water running down front surface 104 of water wall 102 may form the individual letters of the name of the brand along with the logo symbol.
Water wall assembly 100 may also include support structure 108 that may generally support water wall 102 in a secure and stable manner. To this end, support structure 108 may include various beams, struts or other members, such as vertical beams 110, horizontal beams 112, diagonal beams 114 as well as other types of beams configured in a manner that may provide adequate support to water wall 102. Support structure 108 may also include base 116 with an adequate girth, weight and footprint to provide stability and to hold support structure 108 securely in place while supporting water wall 102. Base 116 may include a portion that may be buried underground and secured with concrete, may be attached to a concrete foundation or may be anchored to the ground using other methods.
To this end, lower ends of vertical beams 110 may be attached to base structure 108, and may run along and be attached to, the left and right sides of water wall 102 thereby providing vertical support to wall 102. Vertical beams 110 may also be positioned in the interior area of water wall 102, as depicted by the vertical dashed lines in
Left ends and right ends of horizontal beams 112 may attach to vertical beams 110 on the left and right sides of water wall 102 respectively, and may be attached to water wall 102 to supply horizontal support thereto. While
Additional vertical beams 110, horizontal beams 112, diagonal beams 114 and other types of beams or components may be configured with support structure 108 and water wall 102 to provide additional stability to support structure 108 and water wall 102 as necessary. For example, as shown in
In general, support structure 108 is preferably designed to adequately support water wall 102 while withstanding the pressure of water shot onto water wall 102, any added weight of this water on water wall 102, as well as any other forces that may impinge upon water wall 102 including forces of nature such as gravity, wind, rain, snow or other forces.
One skilled in the art will appreciate that other types of support structures with other elements and components may be configured with water wall 102 to supply the necessary support and stability to water wall 102. In any event, in certain applications of display 10, it is preferred that support structure 108 be relatively minimal in physical appearance to avoid obstructing the visual effects provided by display 10. To this end, the number and size of beams may be reduced as long as sufficient support is provided, and the beams may be configured in the interior areas of water wall 102 so that they do not distract viewers and diminish the aesthetics of water display 10. As an alternative, the industrial look that may be provided by support structure 108 may actually enhance the overall appearance of display 10 in certain applications.
Water delivery assembly 200 is now further described with reference to
In
In addition, water supply 206 is depicted as a water tank in
The direction at which water may be shot out of water nozzles 204 is now further described with reference to
As depicted in
As an alternative to parabolic trajectories, the directions of water nozzles or jets 204 may be varied to provide non-parabolic streams such as those described in U.S. patent application Ser. No. 14/214,514, which is hereby incorporated by reference as if fully set forth herein.
Referring again to
As shown in
The manner in which the water streams emanating from manifold 202 may be controlled is now further described. As noted above, the angle of nozzles or jets 204 may be varied by rotating manifold 202. The rotation of manifold 202 may be programmable, such as by programmable control by controller 220 (in
Furthermore, the exit velocity of the water streams emanating from nozzles 204 may also be varied, programmable or otherwise, by varying the water flow and/or pressure into nozzles 204. Water flow and pressure may be controlled by controller 220. And the variation in water flow and pressure may be effected by, e.g., varying the rotational speed of a pump via a variable frequency drive, where the pump may be located in water source 206. Alternatively, water source 206 may include other types of flow control, such as variable or programmable valves, which may be located in water source 206. It should be noted that the above-mentioned pump, valves or other device for controlling water flow and pressure into nozzles 204 may be located at locations other than water source 206.
Though the nozzle angle and exit velocity variables are both variable, different visual effects may be achieved by changing one variable while keeping the other variable constant. For example, as shown in
By combining the variable (i) nozzle angle and (ii) water exit velocity, many different artistic and visual effects may be achieved. These effects may be enhanced by choreographing the angle, height and volume of the water streams simultaneously. These effects may be further enhanced by choreographing them with lighting, music and/or other sensory effects.
It should be noted that the exit velocity of the water shot from nozzles 204 may also depend on the dimensions of the exit orifice of nozzles 204 and the water pressure at the exit orifice. To control these parameters, nozzles 204 may include jets 212, as depicted in
To provide the adjustability of the water streams, the ends of manifold 202 may be attached to rotating mounts 214 as depicted in
For example, rotating axles 216 may be set to an angle of θ1 so that the resulting water stream S1 may intersect front surface 104 at intersect height H1. Rotating axles 216 may then be adjusted clockwise to an angle of θ2 so that the resulting water stream S2 may intersect front surface 104 at intersect height H2. It should be noted that as rotating axle 216 is rotated clockwise from an angle of θ1 to an angle of θ2, the water emitted from nozzles 204 may flow continuously such that the intersection point of the water stream with front surface 104 may travel continuously from H1 to H2 as the water stream travels downward.
With the foregoing embodiment, the direction of the water streams and the location and manner in which they contact water wall 102 may be varied so that they are choreographed with music, lighting and other visual or audio effects. For example, the water streams may be directed higher to correspond to a crescendo in accompanying music or intensity in lighting. Various other choreographies may be achieved by display 10.
It is preferred that the rotation of water manifold pipe 202 and nozzles 204 is unobstructed. In one embodiment, water delivery assembly 200 may be located under ground or under a cover so that its hardware is generally obscured from view. In this embodiment, slots in the floor or other cover may exist to accommodate the travel of nozzles 204 as their direction is varied.
The angle setting of rotating axles 216 may be manually adjusted by use of a knob, handle, wheel, or other suitable adjustment mechanisms, or may be controlled by a controller 220, such as a computer, or other type of controller 220 with or without the use of specialized software. This is further described below. In any event, the manual or computer control of manifold 202 and nozzles 204 may be choreographed to correspond to other audio and/or lighting features.
The manner in which nozzles 204 may be configured with manifold 202 is now further described. In the above embodiments, nozzles 204 are fixed to manifold 202 so that they rotate together. In one embodiment, nozzles 204 may be aligned along the length of water manifold pipe 202, spaced evenly from one another, and may be pointed at the same general upward angle. In this manner, the streams emitted by nozzles 204 may generally have the same trajectories.
Alternatively, the spacing of nozzles 204 and their directions may vary. For example, as shown in
As described above, the water pressure and flow rate within manifold 202 and nozzles 204 may be controlled to vary the water streams' nozzle exit velocity, as well as the intersection points of the water streams upon front surface 104. For example, the water pressure of water released by water supply 206 into water supply pipe 208 may be controlled to vary these parameters. In addition, valves (not shown) within water supply 206, water manifold pipe 202 or nozzles 204 may be utilized to adjust the water pressure within these components. Furthermore, jets 212 may also include valves (not shown) or adjustable exit orifices that may control the water pressure and thus the exit velocity of the water streams as they are emitted by nozzles 204. Other types of mechanisms or components may be used within water delivery assembly 200 to control and adjust the water pressure within its components. The control of water pressure and flow rate may occur manually or by computer control, as described later.
Referring back to
One or more of the foregoing parameters may be simultaneously adjusted to vary the launch angle θ, the water pressure and exit velocity of the water streams, and the position of nozzles 204 relative to front surface 104. By adjustably controlling one or more these parameters simultaneously the trajectories of the water streams and their intersection points along front surface 104 may be adjusted in a variety of dimensions in real time to provide a dynamic and entertaining water display experience. These parameters may be controlled simultaneously by a controller 220 such as a PC or other type of controller 220 with or without the use of specialized software. This is described in further detail below.
In addition to the adjustment of the variables described above, jets 212 may also be configured with nozzles 204 to have the ability to physically alter the water streams as the streams are emitted therefrom. For example, jets 212 may have the ability to increase the size of their water exit orifices to allow a higher volumetric flow of water to be shot from nozzles 204 upon front surface 104 of water wall 102. Likewise, jets 212 may have the ability to decrease the size of their exit orifices to create a lower volumetric flow of water to be shot from nozzles 204 upon front surface 104 of water wall 102. These dimensional adjustments of the exit orifices of jets 212 may be adjusted manually or through a controller 220 or by other means. Launching higher and lower volumetric flows of water from nozzles 204 may result in a different appearance of the water as it intersects front surface 104 of water wall 102 thus providing yet another variable aspect of water display 10.
Nozzles 204 may include jets 212 that may physically adjust the water streams into different types of shapes and water blooms. For example, jets 212 may alter the emitted water stream into a laminar stream. Or, jet 212 may alter the emitted water stream into a fan-shaped stream, into a bloom-shaped stream, into a bell-shaped stream or into other shaped streams. In addition, jets 212 may have the ability to quickly open and close in order to release bursts of water streams from nozzles 204. In sum, nozzles 204 and jets 212 may be configured to emit a wide variety of types and shapes of water streams to intersect with front surface 104.
In another embodiment of the current invention as shown in
As also shown in
The positioning of water delivery assemblies 200 may further varied with respect to water wall 102. For example, manifolds 202, nozzles 204 and jets 212 may be located on the left and right sides of water wall 102 as shown in
From the foregoing, one skilled in the art will appreciate that manifolds 202, nozzles 204 and jets 212 may be located in a wide variety of positions relative to water wall 102. In another embodiment, water may be shot from flying drones that may fly near water wall 102.
In these additional embodiments, as in the embodiments discussed previously, the control of the direction of the water steams, their nozzle exit velocity, the distance between nozzles 204 and front surface 104, and other variables that may affect the trajectory of the water streams emitted by nozzles 204 may also be manually or automatically controlled.
In another embodiment as shown in
With this embodiment, manifold 202 need not rotate to vary the visual effects of display 10, so components such as rotating mounts 214 may be unnecessary. Alternatively, manifold 202 may still rotate in order to add another element of variability to the control and adjustment of the resulting water streams.
In another embodiment as shown in
As with other embodiments discussed above, nozzles 204 mounted on angular mounts 218 may be positioned in any location on or around water wall 102 so that water shot from nozzles 204 may interact with water wall 102 in any number of manners. Individual nozzles 204 may also be mounted on tracks or other mechanisms that may allow their positions to be moved relative to water wall 102. Each independent nozzle 204 and angular mount 218 may be manually adjusted or adjusted under computer or other automatic control.
Additional embodiments of display 10, such as that shown in
As such, dramatic visual and entertainment effects may be provided to observers as they walk through display 10. For example, this embodiment may provide the sensation of water being shot at the observers while they themselves remain dry. Alternatively, some amount of water may be directed over the tops of water walls 102 so that a slight or some other amount of water does reach observers.
While
In another example, water walls 102 may be configured to form a maze through which observers may pass. In this embodiment, water walls 102 may be configured generally upright at different angles relative to one another. Music, lighting and/or other effects may be added for additional enhancement.
Regarding any of the foregoing embodiments, water walls 102 need not be generally upright, but may be configured in different angles with respect to the ground. For instance, water walls 102 may be slanted such that observers may pass underneath the slanted arc of water wall 102. It should also be noted that water walls 102 need not be generally rectangular in shape, but may be configured in other types of shapes such as triangles, circles, trapezoids and other types of shapes. In addition, water walls 102 may be configured to form other types of three dimensional shapes such as pyramids, cones or other types of three dimensional shapes that may or may not allow observers to enter into the interior of the shapes.
While the above embodiments have been described with nozzles 204 shooting water onto front surface 104, nozzles 204 may be configured and positioned to shoot water onto any surface or element of water wall 102, such as rear surface 105. To this end, the descriptions above regarding manifold pipes 202, nozzles 204, jets 212 and other components in relation to shooting water onto front surface 104, may also apply to nozzles 204 shooting water onto any other surfaces or elements of water wall 102.
In addition, with respect to all of the embodiments described above, water manifold 202 and water nozzles 204 may be hidden and out of sight so that only the emitted water streams may be visible to the viewers of the display 10. For example, when the water manifold 202 and associated water nozzles 204 may be located generally below the water wall 102, the manifold 202 and the nozzles 204 may be located beneath the top surface of a false-bottom pool (not shown) at the base of the wall 102. The top surface of the false-bottom pool may include slits or openings through which the water streams emitted by the water nozzles may pass through while the nozzles themselves are hidden beneath. This may result in a visual effect of the water streams emanating out of the surface of the bottom pool. This same concept may be applied to other configurations where water manifold 202 and water nozzles 204 may be positioned in other areas with regards to water wall 102.
As noted above, display 10 may include one or more lighting assembles to illuminate display 10, such as lighting assemblies 203 shown in
In another embodiment, the lighting assemblies may include fiber optic bundles that may emit different colors of light. In this embodiment, the fiber optic bundles may be configured with nozzles 204 as described above. In addition, if different nozzles 204 utilize fiber optic bundles that may emit different colors, the water streams of different colors emitted by different nozzles 204 may intersect and blend as they hit water wall 102 to create new combinations of color.
In another embodiment, lighting assemblies may be positioned to illuminate front surface 102 from the front, from the rear, or from other areas or positions. In this embodiment, lighting assemblies may illuminate the textures that may exist on front surface 104 of water wall 102. As described above, front surface 104 may include a variety of textures that may form patterns or shapes such as brand logos or the name of the hotel where water display 10 may be installed. By illuminating the textured shapes from different angles, an exciting visual effect may be formed with lighted shapes appearing on water wall 102 behind the water streams as they intersect, splash off and travel down water wall 102. In another embodiment lighting assemblies may be fixed to support structure 108. In another embodiment, flying drones may be equipped with lighting assemblies and may fly around water display 10 while illuminating the water streams, front surface 104 and other elements and components of water display 10.
In general, by lighting water streams and the various surfaces and elements of water wall 102, the finer details of the water streams as they shoot through the air, intersect water wall 102, splash off of water wall 102 or travel down the front surface 104 may be highlighted to further enhance the viewing of water display 10. Examples of lighting applied to display 10 are shown in
As described above, to add to the dramatic visual effect of water display 10, the trajectory, shape and position of the water streams emitted by water nozzles 204 may be controlled in real time by a controller 220 such as a computer. To accomplish this, the water pressure within water manifold pipe 202 and nozzles 204, the launch angle of the water streams, the distance between nozzles 204 and front surface 104 of water wall 102 and the general position of nozzles 204 relative to water wall 102, the output water stream shape emitted by jets 212 of water nozzles, and other variables may be controlled by controller 220. In addition, the various elements of the lighting assemblies that may be utilized with water display 10, such as color, intensity, position and other elements regarding the use of lighting assemblies in conjunction with water display 10 may also be controlled by controller 220.
Software may reside in controller 220 of water manifold assembly 200 and the lighting assemblies such that both the water manifold assembly 200 and the lighting assemblies may be controlled in real time in an orchestrated fashion. That is, the trajectory, shape and position of the water streams emitted by nozzles 204 at any given moment in time may be adjusted and controlled in parallel with the adjustment and control of the illumination of water display 10. By controlling both the water steam characteristics and the display illumination together in real time in an orchestrated fashion, the result may be a dramatic blend of beautifully illuminated water streams, charging water as it intersects the water wall 102, and cascading ripples down front surface 104.
In addition, software residing within the controller 220 of water manifold assembly 200 and the lighting assemblies may have preprogrammed shows that are automated. Conversely, the software may allow for the manual orchestration of the display 10. In addition, the software may allow for a combination of automated preprogrammed shows that may be manually altered and otherwise manually controlled in real time as desired.
Software may be written to control the characteristics of the water streams and lighting, as well as music, other audio or other media that may be incorporated into the performance of display 10. This may allow for a number of such different programs may be loaded to controller 220 of display 10 to be performed as desired.
In another embodiment, display 10 may include additional walls or structures with associated water delivery assemblies such as lower water wall 300 and water delivery assembly 400 as depicted in
In general, water may be delivered to the surfaces of wall 300 or to an area in front of or behind the surfaces of wall 300 by water delivery assembly 400. This will be described in later sections.
In the embodiment shown in
As depicted, water wall 302 may generally extend from the floor surface 312 to the ceiling surface 310 such that patrons may stand in front of, behind or to the side of water wall 302 while viewing the display. In this configuration, wall 302 may be held securely to the floor 312 by holders 308 and to the ceiling by holders 306. Note however, that water wall 302 may be configured in other positions so that it may not extend all the way from the floor to the ceiling. For example, wall 302 may be secured to the floor with holders 308 and extend upward to a position below ceiling 310. Or, wall 302 may be secured to the ceiling by holders 306 and extend downward to a position above floor 312. It should also be noted that while
Water delivery assembly 400 may include a water manifold 402 that may receive water from a water source and deliver the water to the front 304 or back 305 surfaces of the wall 302 so that the water flows down the surfaces of the wall 302. In addition, water pool 432 may be generally located at the base of wall 302 to receive water from wall 302 and may include a water uptake (not shown) that may return the water to the manifold 402. In one embodiment, water manifold 402 may be positioned generally at the top or above wall 302 and may generally extend across the upper dimension the wall 302. In addition, water manifold 402 may be configured with a variety of different water delivery devices 404 such as water holes, water droppers, water shooters, water nozzles, water sprayers, water fall delivery devices, water misters, and other types of water delivery devices to deliver the water accordingly. Note that water manifold 402 may also be configured to stretch across only a portion of the dimension of wall 302, may be configured to stretch across other areas of wall 302 such as the middle or the bottom or other areas, or may be configured in any other position or dimension with respect to wall 302.
In one embodiment, these various water delivery devices 404 may be configured to deliver water directly to the front surface 304 or the back surface 305 of water wall 302. For example, as shown in
Note that
Water may be delivered to water manifold 402 from water supply 408 via water delivery network 410. Water supply 408 may include water pool 432, a water tank, a water reservoir, a neighboring water fountain, a pond, a lake or any other type of water supply. In addition, water delivery network 410 may include water pipes, tubes, channels or other types of liquid delivery mechanisms. Accordingly, water may flow from water supply 408 into water manifold 402 and out of water delivery devices 404. The water flow and pressure into water manifold 402 and out of water delivery devices 404 may be controlled by a water pump 412 that may be configured with water delivery network 410 and powered and controlled by a variable frequency drive (VFD) or other type of pressure and flow control device.
The water pump 412 and variable frequency drive (VFD) may be controlled either manually or by a controller (for example, a computer running software) in real time such that the water pressure and flow rate out of water pump 412 and into the water manifold 402 may also be dynamically controlled. This may in turn control and vary the water pressure and flow rate of the water as it emits from water holes 404a-404d such that the shapes and configurations of the water droplets or streams delivered to wall 302 may also be controlled to vary in real time. For instance, the water droplets 406a emitting from water dropper 404a may increase or decrease in frequency, the water droplets 406a may enlarge or shrink in size, or other characteristics of the water droplets 406a may be controlled. In addition, the characteristics of water streams and blooms 406b, 406c, 406d emitting from water holes 404b, 404c, 404d respectively may also be controlled in real time in a similar fashion.
It should also be noted that water delivery assembly 400 may include more than one water manifold 402, each with water delivery devices 404 configured to deliver water to wall 302. For example, several water manifolds 402 may be positioned above one another, side-by-side, in rows or in other configurations with respect to one another. In addition, each manifold 402 may include one or more water pumps 412 that may control the water pressure and flow rate of water into and out of individual water delivery devices 404 or groups of water delivery devices 404. As such, it can be seen that the shapes and other water characteristics of water flowing out of water delivery devices 404 (in this example, water holes 404a-404d) may be controlled individually or in groups in real time. Given this, different varying flow patterns on the front surfaces 304 of the wall 302 may be created across the wall 302. It is important to note that all of this may be controlled manually or by a controller, such as a computer, that may be running software. The software may control the water flow and output pressure in choreographed sequences such that the water patterns and shapes across the wall may be orchestrated to dance across the wall 302. Music may also be played and the orchestrated flow patterns may move in time with the music producing a dramatic water display effect. It should also be noted however that the water flow pattern across the wall 302 may also be an even expression.
In another embodiment as depicted in
In yet another embodiment, water manifold 402 may be configured with water fall device 418 as depicted in
It should be noted that with respect to all of the embodiments described above, while
In another embodiment as depicted in
In addition, similar to water manifold 402, water manifold 424 may be configured with water delivery devices 422 that may include water holes, water droppers, water shooters, water nozzles, water sprayers, water fall delivery devices, water misters, and other types of water delivery devices.
Water may fall from water manifold 424 downward through the air and into water pool 432. In addition, pool 432 may include a water uptake (not shown) that may receive the water from water manifold 424 and return it to the manifold 424 to be recycled. Also, water receiving device 428 may also be positioned beneath the path of the emitted water from water manifold 424 to receive the emitted water and to regulate the water flow out of the manifold 424. For example, water receiving device 428 may include sensors that may measure or otherwise keep track of the water flow rate received by the water receiving device 428 such that the device 428 may relay this information to a controller that may use the data to control and regulate the water pressure and flow rate of water entering into and out of water manifold 424.
As described above, water display 10 may also including lighting assembly 500 that may be configured to illuminate water wall 302 and the water as it flows down the wall 302 or as it falls through the air in close proximity to the wall 302. Lighting assembly may comprise flood lights, LEDs, optical fibers or other types of light sources that may be aimed onto the wall 302 or onto the water that is emitted by water manifolds 402 and/or 428 and the associated water delivery devices 404. In addition, the light sources may be generally positioned above wall 302 as depicted in
Although certain presently preferred embodiments of the invention have been described herein, it will be apparent to those skilled in the art to which the invention pertains that variations and modifications of the described embodiments may be made without departing from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 62/296,577, filed Feb. 17, 2016, the contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
2034792 | Bergman | Mar 1936 | A |
4955540 | Fuller | Sep 1990 | A |
5067653 | Araki | Nov 1991 | A |
5234728 | Chiang | Aug 1993 | A |
5899634 | Lochtefeld | May 1999 | A |
6135604 | Lin | Oct 2000 | A |
6261186 | Henry | Jul 2001 | B1 |
6276612 | Hall | Aug 2001 | B1 |
6611114 | Yen | Aug 2003 | B1 |
6921023 | Bright | Jul 2005 | B1 |
7775457 | Schnuckle | Aug 2010 | B2 |
8225539 | Beebe | Jul 2012 | B2 |
8333331 | Fuller | Dec 2012 | B1 |
8511828 | Fuller | Aug 2013 | B2 |
8813765 | Petit | Aug 2014 | B2 |
9427763 | Fuller | Aug 2016 | B2 |
20030094509 | Venuto, Sr. | May 2003 | A1 |
20060208369 | Hayden | Sep 2006 | A1 |
20070205300 | Plut | Sep 2007 | A1 |
20080135639 | Winters | Jun 2008 | A1 |
20080217424 | Yang | Sep 2008 | A1 |
20100187325 | Houstoun | Jul 2010 | A1 |
20140240958 | Fuller | Aug 2014 | A1 |
20140312139 | Fuller | Oct 2014 | A1 |
20150041554 | Aguilera Sanchez | Feb 2015 | A1 |
20170232464 | Fuller | Aug 2017 | A1 |
Number | Date | Country | |
---|---|---|---|
20170232464 A1 | Aug 2017 | US |
Number | Date | Country | |
---|---|---|---|
62296577 | Feb 2016 | US |