The present disclosure generally relates to pool suction outlet fittings, which also are commonly known in the art as pool drains or sumps, including sump basin fittings capable of allowing water to flow from the basin to a pump and filter for recirculation. More specifically, the present disclosure is directed to a recessed or inset system for draining or recirculating water in a water vessel or basin such as a spa, swimming pool, hot tub, garden bath, and the like. The present invention also is directed to the formation or insertion of a drainage/recirculation device into, or through, the side wall(s) or floor defining the water-containing portion of a spa, swimming pool, hot tub, garden bath, or the like.
Artificial bodies of water such as spas, swimming pools, hot tubs, garden baths, and the like derive benefits from the addition of both aesthetically pleasing features and safety features. Modern drain regulations for these artificial bodies of water, as well as modern developments in the art, make pool drains a perfect feature for pool and spa manufacturers to focus on in developing aesthetically pleasing drains that are safe for users.
For example, the common regulatory requirements for two pool drains structured so that a user likely would not become caught and stuck in the pool drain usually results in pool drains being configured as unsightly rectangular channels or high surface area grate drains. In particular, some of these grate drains usually take the form of rounded or circular drains with drain covers having recessed surfaces or openings. The recessed surface or opening being for the application of a “masking” or “hiding” agent being either of a material similar to the surrounding inner surface of the artificial body of water upon which the pool drain is defined, inset, or recessed, or being of the exact same material used during or after fabrication or laying of the artificial body of water. Some of these pool drains are comprised of multiple components glued or welded together creating a potential leak path.
Channel drains, which typically are linear in structure, require alignment to a wall or other pool feature during installation so as to be aesthetically pleasing. If even slightly misaligned, the misalignment can be noticeable. A circular drain structure has less need for alignment and therefore can be quicker and simpler to install.
As the market for spas, swimming pools, hot tubs, garden baths, and the like grows, users desire more, different, better, more interesting, and more aesthetically pleasing drainage systems and methods of draining to make, for example, their bathing experience more relaxing, more convenient, and safer. Further, professionals that build pools, spas, and the like, desire drainage systems that are more reliable, easier to install, and easier to maintain.
Accordingly, there is a need for new and different drainage devices and methods for draining artificial bodies of water and the like. There also is a need for a reliable, efficient, and effective pool drain fitting (“pool drain” or “sump basin” for simplicity, as used in the Detailed Description) that is minimalist in dimensions and materials, without sacrificing function, that is aesthetically pleasing and well hidden, and that has a design and shape to maximize the drainage function, yet still maintains an acceptable level of safety. It is to these needs and others that the present invention is directed.
Briefly, the present invention is for a pool drain or sump basin. In one exemplary embodiment, an injection-molded hollow drain has an elongated ring-shaped body, at least one, and preferably a plurality of, outlet ports about the ring-shaped body for allowing water to exit the drain, external peripheral flanges for mounting the drain, and an opening for allowing water to enter the drain.
In another exemplary embodiment, the ring-shaped body has an inner sidewall and outer sidewall with the topside of the body open. The bottom or floor of the body closes off the opposite side of the body, bridging the gap between the inner sidewall and the outer sidewall, and creating a drainage channel. The body may have an optional cover configured as a removable or replacement cover with openings, such as slits or holes or any other shape. Although the openings may be designed to reduce the passage of debris into the drainage channel, this is not necessarily a requirement in all applications of the invention.
In another exemplary embodiment, the outlet ports are situated about the ring-shaped body, and are in fluid communication with a corresponding number of cylindrical conduits for draining water from the drainage channel of the body. The drainage channel is defined by the inner sidewall, the outer sidewall, and the floor of the body.
In another exemplary embodiment, the area circumscribed by the inner wall of the ring-shaped body, external to the drainage channel, is a completely open center area that is devoid of any system components or structures, and is configured to receive a filler material to attractively blend the drain system with the pool wall(s) or floor.
In another exemplary embodiment, at least one bridging element is included to provide additional support for a grate cover for covering the drainage channel and provide support to the inner and outer sidewalls preventing the walls from deformation due to stresses incurred as the surrounding surface material (gunite, cement, concrete, shotcrete, plaster, Pebble Tech®, etc.) cures. The surface material will exert force on the walls of the drain as the material cures whereby the inner and outer sidewalls would be pushed toward each other making the top opening narrower. This condition can prevent any optional drain cover from being installed into the opening. The bridging element also interrupts or substantially interrupts, depending on the size and structure of the bridging element, the top opening of the drainage channel to as to affect the flow of water into the drainage channel.
In another exemplary embodiment, the bridging element has a flow regulating feature depending downward into the drainage channel. The flow regulating feature interrupts or substantially interrupts, depending on the design of the flow regulating feature, the flow of water within the drainage channel. The flow interruption can reduce turbulence in the flow of water within the drainage channel, which can help prevent hair entrapment, and also can trap debris that enters the drainage channel through the grate cover thus preventing such debris from traveling into the water pumping system.
These features, and other features and advantages of the present invention will become more apparent to those of ordinary skill in the relevant art when the following detailed description of the preferred embodiments is read in conjunction with the appended drawings in which like reference numerals represent like components throughout the several views.
In the figures, for reference numerals with letter character designations such as “102a” or “102b”, the letter character designations may differentiate two like parts or elements present in the same figure. Letter character designations for reference numerals may be omitted when it is intended that a reference numeral to encompass all parts having the same reference numeral in all figures.
For a further understanding of the nature, function, and objects of the present invention, reference should now be made to the following detailed description. While detailed descriptions of the preferred embodiments are provided herein, as well as the best mode of carrying out and employing the present invention, it is to be understood that the present invention may be embodied in various forms. Therefore, specific details disclosed herein are not to be interpreted as limiting, but rather as a basis for the claims and as a representative basis for teaching one skilled in the art to employ the present invention in virtually any appropriately detailed system, structure, or manner.
Embodiments and aspects of the present invention provide a device and a system for draining an artificial body of water or pool that is not susceptible to the limitations and deficiencies of the prior art. The inventive concepts described herein, in certain non-limiting embodiments, allow for the formation or insertion of a drainage device into a pool such that the drainage device functions as a sump basin and pool drain, and such that the drainage device is efficiently and effectively camouflaged or hidden from a user's view, and from contact with a user or pool equipment (e.g., a pool vacuum, an automatic pool cleaner).
The inventive concepts described herein also allow for inserting, embedding, recessing, and insetting, in certain non-limiting embodiments, a pool drain into, or through, the side wall(s) or floor defining the water-containing portion of an artificial body of water. The inventive concepts described herein also allow for a recessed or inset pool drain that is less susceptible to boundary cracking or fracturing and is less susceptible to manufacturing-, machining-, or joint-cracking or fracturing.
The inventive concepts described herein also allow for a pool drain that is efficient and effective, that is minimalist in dimensions and materials, without sacrificing function, that is aesthetically pleasing and well-hidden, and that facilitates different aesthetic designs and shapes to maximize the drainage function. For example, the inventive concepts described herein facilitate other parallel- or related-functions, such as facilitating installation or use of a hydrostatic relief valve (to relieve hydrostatic pressure acting on the interface of the artificial body of water and underlying substrate, for example), preventing or reducing the chance and/or extent of hair entrapment, and for regulating or affecting the flow of water within the pool drain. This allows for efficiencies in time, labor, and resources, in manufacturing and maintaining artificial bodies of water, and for a streamlining and simplifying of the types of systems/devices capable of solving the problems inherent in the prior art. This also allows for a drainage solution that more readily complies with modern regulatory standards.
As context, a sump or drainage basin generally is known as a low space in a defined body wherein the basin collects material from the broader body, usually via gravity, but in the case of pools also via suction. An artificial body of water or pool generally comprises a gunite (concrete), plaster, plastic, or fiberglass body, made up of sidewalls, edges, openings, conduits, filler, etc., defining a water-containing portion or vessel. A prior art pool drain generally comprises a plastic body component for the broader pool, usually installed along the floor or bottom of the pool, defining a sump or drainage basin into which waterflow from the pool is removed and recirculated via the pool's pump and filter.
At the most basic level, a pool drain comprises an opening, inlet, or intake that connects to an outlet, conduit, or pipe that is in fluid communication with a pool pump and filter. When installed onto a pool, such pool drains define an outlet port for the broader and complete artificial body of water. In one example, a pool drain is configured as an elongated or spread-out inlet/intake such that a single pool-user likely would not cover the entire inlet/intake or risk becoming trapped by the associated force of draining or suctioned water. Such pool drains are classified as “unblockable” drains in the industry as well by as the US Consumer Product Safety Commission (USCPSC) and governing bodies that regulate, certify and enforce pool/spa drain safety These pool drains often are configured as unsightly rectangular channels or high surface area grate drains with such features as multiple intake ports (distinct from multiple outlet ports), and being of a sufficient length that the additional multiple ports cannot be simultaneously blocked.
A problem with such pool drains, particularly elongated or high surface area drains, is that some of these drains have recessed surfaces, cavities, openings, nooks, or crannies for the application of a “masking”, “hiding”, filler, or bonding material. Over time, the material into which the pool drain is embedded forms cracks and fissures due to expansion and contraction, and natural erosive-forces like temperature, water, and chemical attack. In another example, the boundary where the pool drain and material meet is a junction prone to forming cracks, and a junction prone to fracturing away from the surrounding material. This is particularly problematic as water may seep into the surrounding material and then down into the supporting walls or floor of the pool, and/or surrounding substrate, which ultimately may cause further damage.
Another problem with such pool drains, particularly elongated or high-surface area drains, is that some of these drains rely on complicated plumbing pathways and conduit structures, that while seemingly solving the drainage hazard present in the prior art, lend themselves to more complicated manufacturing or machining designs and processes. In one example, an elongated and spread-out conduit portion of a pool drain, intended to solve the problems in the prior art, in actuality cannot be injection molded hollow, in one piece, with the rest of the pool drain body, thereby requiring the pool drain to be molded in separate casts and then joined together. This is particularly problematic as the manufacturing- or machining-joint(s) in these pool drains create a potential (and likely) leak path, which ultimately may cause further damage.
With the above context in mind, a first exemplary embodiment of the present invention provides an efficient, effective, safe, and versatile pool drain system for connecting to the pump and filter of a pool, wherein the drain system defines a ring-like inlet or intake opening and comprises at least one, and preferably two or more outlet ports, and wherein the drain system is efficiently and effectively camouflaged or hidden from a user's view, or from contact with a user or pool equipment, but whereby the drain system is configured for inserting, embedding, recessing, and insetting into, or through, the side wall(s) of floor defining the water-containing portion of the pool. The drain system is less susceptible to boundary cracking or fracturing, and less susceptible to manufacturing-, machining-, or joint-cracking or fracturing. The surrounding material meets the pool drain along a substantive component of the drain system, which is ideally injection-molded hollow or of unibody construction, and which has minimal manufacturing- or machining-joints.
A second exemplary embodiment of the present invention provides a pool drain comprising a ring-like body configured as a drainage channel, and having a corresponding ring-like inlet or intake opening accessible to the pool, wherein the drainage channel is in fluid communication with the pool, and is accessible from the pool via the ring-like inlet/intake opening on one side. The pool drain additionally comprises, on another side, two or more independent outlet ports for fluid communication with the pool's pump and filter and for channeling fluid from the drainage circuit. Each outlet port is separated from the other(s) by the maximum distance possible based on the ring-like inlet/intake opening. Further, the ring-like body defines an internal space or area, external to the drainage circuit, but internal to the body forming the drainage circuit, wherein a “masking”, “hiding”, filler, or bonding material can be placed so as to fill the internal space, whereby the pool drain attractively blends in with the pool wall(s) or floor.
A third exemplary embodiment of the present invention provides a pool drain system comprising an annular or ring-shaped body for embedding into, or through, the main body/side wall(s) or floor of a pool. The area or space circumscribed by the inner wall of the ring-shaped body, external to the drainage channel, defined by the walls of the ring-shaped body, is devoid of any system components or structures, and is configured to receive a filler material to attractively blend the drain system with the pool wall(s) or floor. The pool drain system additionally comprises two or more independent outlet ports, each equally separated from the other(s) about the ring-shaped body, the ring-shaped body being large enough such that a single pool-user would not cover the entire inlet/intake opening of the ring-shaped body, or risk becoming trapped by the associated force or suction. The use of two or additional ports will still allow the pulling of water to the pump in the event that one of the ports gets clogged with debris, or if a port should get blocked by a bather's hair. In this manner, the invention provides for a safety aspect (reducing or preventing the suction of hair) and a performance aspect (not starving the pump if one port is clogged). The pool drain additionally comprises an annular or ring-shaped grate cover, or cover with openings, corresponding to the opening of the ring-shaped drainage channel.
When a drain becomes obstructed (by a human body for example), the locations of the ports will not necessarily prevent the obstruction or entrapment. As long as the drain cover/opening is not completely blocked, water will be able to flow through any unobstructed portion into the channel and then into the outlet port, regardless of where the port(s) is/are on the channel. The suction force may be highest where the ports are located, but as long as there is some portion of the cover/opening unobstructed water will flow to the outlet(s). Thus, it is the size of the drain (diameter of the opening/cover) that makes the drain “unblockable” and prevents a single user from obstructing the entire drain. Under current safety regulations, if the drain cover/opening cannot be completely shadowed by an 18-inch by 23-inch element (with 4-inch radius corners), the drain is considered unblockable. The 18-inch by 23-inch size represents the torso of a 99th percentile male. Thus, the port quantity and location are independent of the “unblockability” of the drain. If the drain is made in a size that is too small to be considered unblockable, then it would be necessary to install multiple drains (e.g., at least two drains per pump) with each drain spaced at least three feet apart to avoid entrapment risk according to current drain regulations. Thus, the invention does not need to be unblockable per se by being of a certain size or larger, but being of an unblockable size has certain advantages as discussed above.
A fourth exemplary embodiment of the present invention provides a pool drain system comprising an annular or ring-shaped body for embedding into, or through, the floor of a pool. The area or space circumscribed by the inner wall of the ring-shaped body, external to the drainage channel, defined by the walls of the ring-shaped body, is devoid of any system components or structures, and is configured to receive a filler material to attractively blend the drain system with the pool floor. The pool drain system additionally comprises two or more independent outlet ports, each equally separated from the other(s) about the ring-shaped body. The pool drain additionally comprises an annular or ring-shaped grate cover, or cover with openings, corresponding to the opening of the ring-shaped drainage channel, and at least one bridging element to provide support for the sidewalls of the drainage channel and to provide additional support for the grate cover for covering the drainage channel. The bridging element also interrupts or substantially interrupts, depending on the size and structure of the bridging element, the top opening of the drainage channel to as to affect the flow of water into the drainage channel.
A fifth exemplary embodiment of the present invention provides a pool drain system comprising an annular or ring-shaped body for embedding into, or through, the floor of a pool. The area or space circumscribed by the inner wall of the ring-shaped body, external to the drainage channel, defined by the walls of the ring-shaped body, is devoid of any system components or structures, and is configured to receive a filler material to attractively blend the drain system with the pool floor. The pool drain system additionally comprises two or more independent outlet ports, each equally separated from the other(s) about the ring-shaped body. The pool drain additionally comprises an annular or ring-shaped grate cover, or cover with openings, corresponding to the opening of the ring-shaped drainage channel, and at least one bridging element to provide support for the sidewalls of the drainage channel and to provide additional support for the grate cover for covering the drainage channel. The bridging element has a flow regulating feature depending downward into the drainage channel that interrupts or substantially interrupts, depending on the design of the flow regulating feature, the flow of water within the drainage channel. The flow interruption can reduce turbulence in the flow of water within the drainage channel, reduce the risk of entrapment, and also can trap debris that enters the drainage channel through the grate cover thus preventing such debris from traveling into the water pumping system.
The drainage channel of the exemplary embodiment is defined by the inner wall, outer wall, and floor of the main body. When the pool drain system is installed into the pool wall(s) or floor, the opening of the drainage channel, with or without the cover, preferably is substantially flush with the pool wall(s) or floor. The pool drain system additionally comprises external flanges extending outward from (relative to the outer wall of the ring-shaped body) and inwards from (relative to the inner wall of the ring-shaped body) the opening of the drainage channel, to help prevent water from passing through the boundary between the main body and the surrounding material.
The drain 10 has a ring-shaped body 12, and two outlet ports 26a, 26b, with 26a situated antipodal 26b about the ring-shaped body 12, and external peripheral flanges 50, 60 with outward flange 60 and inward flange 50 extending from the outer side wall 16 proximal to the opening 18 of the body 12. In this specific embodiment, the body 12 is injection molded hollow as a single unibody component, therefore not requiring the body 12 to be molded in separate casts and joined, which avoids manufacturing- or machining-joints, and which ultimately may create potential leak paths.
The ring-shaped body 12 has an inner sidewall 14 and an outer sidewall 16. The topside of the body 12 is generally open, while the bottom or floor 17 of the body 12 closes off the opposite side of the body 12, bridging the gap between the inner sidewall 14 and the outer sidewall 16. At the top side of the body 12, however, the inner sidewall 14 and the outer sidewall 16 are spaced apart so as to define the annular or ring-shaped opening 18, which may be sized to receive a corresponding annular or ring-shaped cover 22. The cover 22 is configured as a removable or replacement cover with openings through which water can pass from the pool into the body 12. Optionally, the cover 22 may have other types of openings 216 that allow water to pass through while stopping larger debris. The cover 22 may comprise an overhanging flange that completely covers the body 12; leaving no visible seam when installed. The body 12 and cover 22 may be made of polyvinyl chloride (PVC), acrylonitrile butadiene (ABS), or other similar materials. The cover 22 alternatively may be made of brass, stainless steel, or other similar materials as well.
In an exemplary embodiment, the body 12 is about 20 inches in outer diameter as measured to the outer sidewall 16. However, depending on the circumstances, such as pool size and type, the body 12 may range from about 8 inches to about 24 inches in outer diameter. For example, various configurations of circular drains can call for an 8-inch diameter, a 10-inch diameter, a 12-inch diameter, a 16-inch diameter, or a 24-inch diameter. Thus, the present invention is not limited to any particular size.
The two independent outlet ports 26a, 26b are situated antipodal about the ring-shaped body 12, are in fluid communication with cylindrical drainage conduits 28a, 28b, respectively, and are for draining water from the drainage channel 20 of the body 12. The drainage channel 20 is the volume within the body 12 defined by the inner sidewall 14, the outer sidewall 16, and the floor 17 of the body 12. The longitudinal axes of the drainage conduits 28a, 28b are preferably orientated perpendicular (usually vertical or substantially vertical, in practical applications on the floor 82 of a pool) to the open side of the ring-shaped body 12 (usually situated horizontal or substantially horizontal, in practical applications on the floor 82 of a pool), and are for fluidly connecting the drain 10 into the pool's pump and filter system.
Within the space circumscribed by the inner wall 14 of the ring-shaped body 12, external to the drainage channel 20, is a completely open center area 30 that is devoid of any system components or structures, and is configured to receive a filler material 80 to attractively blend the drain system with the pool wall(s) or floor 82. The open center area 30 may be filled with plaster, aggregate, epoxy, tile, plastic, fiberglass, vinyl, acrylic, etc. An embodiment is envisioned that includes additional screws, mounting ring, gasket, etc. to mount in a vinyl liner pool. The drainage conduits 28a, 28b, in their perpendicular orientation relative to the ring-shaped body 12, have a portion of their circular cross section protruding from the ring-shaped body 12 into the center area 30. This keeps the visible drain profile narrow while allowing larger plumbing conduits and pipes to be attached for increased flow through the drain 10.
In an exemplary embodiment, the drainage conduits 28a, 28b preferably are cylindrical in structure, sized on the inside to accept standard Schedule 40 pipe used in many pool installations, and sized on the outside to accept a Schedule 40 coupling one size larger (by 0.5 inches, for example) than the inside (e.g., a Socket×Spigot connection). The drainage conduits 28a, 28b may be configured as a 2 inch socket×2.5 inch spigot, a 1.5 inch socket×2 inch spigot, or a 2.5 inch socket×3.0 inch spigot. However, again depending on the circumstances, such as pool size and type, the drainage conduits 28a, 28b may be of a different Schedule size, such as thicker-walled Schedule 80 pipes. Thus, the present invention is not limited to any particular size.
The drainage conduits 28a, 28b are threaded 32a, 32b, respectively, along their inside socket connection region, at the top of the cylindrical conduit, where the inside conduit wall meets the ring-shaped drainage channel 20. The threading 32a, 32b facilitates secure socket-type connections with the drainage conduit 28a, 28b, respectively, as well as facilitates installation of maintenance or analysis equipment (a hydrostatic relief valve, for example). The threading 32a, 32b also facilitates plugging of the ports 26a, 26b, respectively.
Generally, both ports 26a, 26b operate to drain water; however, at lower flow rates through the drainage channel 20 and out through the ports 26a, 26b and into the drainage conduits 28a, 28b, one port 26a, 26b may be used for flow to the pump and one port 26a, 26b may be used to install the hydrostatic relief valve 92 or other equipment like the optional collection tube 94. In this embodiment, there is no need for the complication of having a separately dedicated access port(s) that certain prior art devices include or require. Ports 26a, 26b also allow for more flow than a single port, and two or more ports means that if one port gets blocked, water can still flow through the other ports to avoid starving the pump. In certain embodiments, flow amongst the various ports may be balanced by plumbing to a tee 96 going into a main plumbing line, for example, to the pump (the main plumbing line may be of a larger size diameter than the ports 26a, 26b off of the drainage channel 20). Both ports 26a, 26b, may be plugged with a threaded plug 90, which is complementary of the threading 26a, 26b of the drainage conduits 28a, 28b, for pressure testing, as is typically performed on every pool prior to plastering, to check for leaks in the plumbing joints.
When the pool drain system 10 is installed into the pool wall(s) or floor 82 (embedded into, or through, the main body/side wall(s) or floor 82 of a pool), the outward external flange 60 (relative to the outer wall 16 of the ring-shaped body 12) and inward external flange 50 (relative to the inner wall 14 of the ring-shaped body 12) help prevent water from passing through the boundary between the main body 12 and any surrounding material (the gunite or concrete of which the pool is constructed, for example). The outward external flange 60 and the inward external flange 50 are configured as a curved water stop extending outward and upward from the drainage channel 20 to prevent leaks and anchor the surrounding plaster, for example, against the pool drain body 12.
When the pool drain system 10 is installed into the pool wall(s) or floor 82, the opening 18 of the body 12, with or without the cover 22, preferably is substantially flush with the pool wall(s) or floor 82 when installed and embedded into the pool. Cover 20 can be flushly mounted within the body 12, or can extend upwardly into the pool volume a desired distance. In this way, the pool drain 10 is efficiently and effectively camouflaged or hidden from a user's view, or from contact with a user or pool equipment (e.g., a pool vacuum, an automatic pool cleaner). In some embodiments, the plaster, aggregate, gunite, shotcrete, etc. used to build-up the pool walls or floor 82 can flow around the body 12 and can be poured into the center opening 30.
The drain 100, like drain 10, has a ring-shaped body 12, two drainage conduits 28a, 28b, with 28a situated antipodal 28b about the ring-shaped body 12, and an outward flange 60 and an inward flange 50. The drain 100 also has a cover 122 configured as a removable or replacement cover with openings through which water can pass from the pool into the body 12, and an overhanging flange 196 that completely covers the body 12; leaving no visible seam when installed. The cover 122 comprises a rib 198 situated at the semicircular protrusion of the ring-shaped cover 122. The rib 198 is configured to correspond to the conduit 28a to provide strength and/or to facilitate engagement when the cover 122 is engaged onto the ring-shaped body 12.
As disclosed herein, generally, both ports 26a, 26b operate to drain water; however, at lower flow rates through the drainage channel 20 and out through the ports 26a, 26b and into the drainage conduits 28a, 28b, one port 26a, 26b may be used for flow to the pump and one port 26a, 26b may be used to install the hydrostatic relief valve 92 or other equipment like the optional collection tube 94. The flow regulating devices 220 can be sized to reduce the flow within the drainage channel 20 whereby only one port 26a or 26b and one drainage conduit 28a or 28b, respectively, is necessary for draining water from the pool. To assist in accomplishing this, at least one of the flow regulating elements 220 can be a solid feature blocking or substantially blocking the drainage channel 20 and thus directing water to the port 26a, 26b and drainage conduit 28a, 28b being used to conduct water to the pool pumping system.
As shown, the bridging elements 200 and flow regulating elements 220 can be a single feature or multiple features around the drainage channel 20. These features can help prevent the opening 18 from deforming or collapsing as the plaster/concrete cures. As the cover 22, 122 fits into the opening 18, it would be difficult or impossible to attach the cover 22, 122 if the opening 18 were deformed. This phenomenon is seen in channel drains. The bridging element 200 and flow regulating element 220 features can be molded into the pool drain 10 or they can be made as a separate piece and glued, snapped, heat welded, ultrasonic welded, attached with screws, etc., in place. If a large bridging element 200 and/or flow regulating element 200 is molded in, the outside of the pool drain 10 can be contoured, notched, or cored out to maintain an even wall thickness (inner sidewall 14, outer sidewall 16, floor 17) throughout the pool drain 10.
The various components of the invention can be manufactured from relatively inexpensive materials. Preferably, the components are molded or formed from a material that will not corrode or be adversely affected from the exposure to water, particularly chlorinated water, and other chemicals present in a pool setting. Such materials are known in the art
The foregoing detailed description of the preferred embodiments and the appended figures have been presented only for illustrative and descriptive purposes and are not intended to be exhaustive or to limit the scope and spirit of the invention. The embodiments were selected and described to best explain the principles of the invention and its practical applications. One of ordinary skill in the art will recognize that many variations can be made to the invention disclosed in this specification without departing from the scope and spirit of the invention.
This patent application claims priority on and the benefit of U.S. Provisional Patent Application No. 62/868,142 having a filing date of 28 Jun. 2019.
Number | Date | Country | |
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62868142 | Jun 2019 | US |