This application claims priority to the following Chinese patent application, the disclosure of which is hereby expressly incorporated by reference herein in its entirety:
The present disclosure relates to a flow generating device for pool applications, and more particularly, to a hanging assembly for a flow generating device in pool applications.
Swimming pools may be equipped with a flow generating device to generate a current in the pool. In some applications, booster pumps positioned in the pool wall are used to generate flow in the pool. In household above ground pools, flow generating devices are used and generally hang from the sidewall of the pool. In this configuration, the water outlet and subsequent current generated by the flow generating device is generally limited to a single direction that is perpendicular to the sidewall of the pool. Improvements in the foregoing are desired to provide greater variability in the current direction.
The present disclosure provides a hanging assembly configured for use with a flow generating device that produces a current in a pool. The hanging assembly includes a back supporting plate coupled to a side supporting plate where a plate angle is formed between the back supporting plate and the side supporting plate. The plate angle is adjustable such that a current angle of the current relative to a sidewall of the pool can be varied based on user preferences.
In one form thereof, the present disclosure provides a hanging assembly for use with a flow generating device that produces a current in a pool. The hanging assembly includes a back supporting plate configured to support the flow generating device in the pool, a side supporting plate pivotably coupled to the back supporting plate such that an adjustable angle of at least about 90 degrees is formed between the back supporting plate and the side supporting plate, and a hanging unit coupled to at least one of the back supporting plate and the side supporting plate and configured to couple to a sidewall of the pool.
The adjustable angle between the back supporting plate and the side supporting plate may adjust a current angle of the current relative to the sidewall of the pool. The current angle may be adjustable from about 0 to about 90 degrees.
The side supporting plate and the back supporting plate may be coupled together by a hinged connector having a free configuration that allows movement between the side supporting plate and the back supporting plate, and a locked configuration that prevents movement between the side supporting plate and the back supporting plate. The hinged connector may include a first friction plate coupled to the back supporting plate, a second friction plate coupled to the side supporting plate, a pivot pin, and a nut threadably coupled to the pivot pin, wherein the nut releases the first and second friction plates in the free configuration and compresses the first and second friction plates in the locked configuration.
The hanging unit may be selectively coupled to the back supporting plate and the side supporting plate, such that, when the hanging unit is coupled to the back supporting plate, the back supporting plate is positioned adjacent to the sidewall of the pool and, when the hanging unit is coupled to the side supporting plate, the side supporting plate is positioned adjacent to the sidewall of the pool.
The hanging assembly may further include a pool supporting block selectively coupled to the back supporting plate and the side supporting plate, such that, when the hanging unit is coupled to the back supporting plate, the pool supporting block is positioned between the back supporting plate and the sidewall of the pool and, when the hanging unit is coupled to the side supporting plate, the pool supporting block is positioned between the side supporting plate and the sidewall of the pool.
In another form thereof, the present disclosure provides a hanging assembly including a back supporting plate configured to support a flow generating device that produces a current at a current angle relative to a sidewall of a pool, a hanging unit configured to couple to the sidewall of the pool, wherein the hanging assembly has a first configuration in which the back supporting plate is attached to the hanging unit and a second configuration in which the back supporting plate is pivotably coupled to the hanging unit to adjust the current angle. In the first configuration, the current angle may be about 90 degrees. In the second configuration, the current angle may be less than about 90 degrees.
The hanging assembly may further include a side supporting plate pivotably coupled to the back supporting plate by a hinged connector having a free configuration that allows movement between the side supporting plate and the back supporting plate and a locked configuration that prevents movement between the side supporting plate and the back supporting plate. The hinged connector may include a first friction plate coupled to the back supporting plate, a second friction plate coupled to the side supporting plate, a pivot pin, and a nut threadably coupled to the pivot pin, wherein the nut releases the first and second friction plates in the free configuration and compresses the first and second friction plates in the locked configuration.
A plate angle between the back supporting plate and the side supporting plate may be about 90 degrees or more.
The hanging assembly may further include a pool supporting block, wherein, in the first configuration, the pool supporting block is positioned between the back supporting plate and the sidewall of the pool and, in the second configuration, the pool supporting block is positioned between the side supporting plate and the sidewall of the pool.
In yet another form thereof, the present disclosure provides a hanging assembly including a hanging unit configured to couple to a sidewall of a pool, a back supporting plate configured to support a flow generating device that produces a current at a current angle relative to the sidewall of the pool, a side supporting plate configured to suspend from the hanging unit adjacent to the sidewall of the pool, the back supporting plate pivotably coupled to the side supporting plate to adjust the current angle.
The current angle may be adjustable from about 0 to about 90 degrees.
The side supporting plate and the back supporting plate may be coupled together by a hinged connector having a free configuration that allows movement between the side supporting plate and the back supporting plate and a locked configuration that prevents movement between the side supporting plate and the back supporting plate. The hinged connector may include a first friction plate coupled to the back supporting plate, a second friction plate coupled to the side supporting plate, a pivot pin, and a nut threadably coupled to the pivot pin, wherein the nut releases the first and second friction plates in the free configuration and compresses the first and second friction plates in the locked configuration. The hinged connector may be positioned along an edge of the flow generating device between a back surface and a side surface of the flow generating device.
The back supporting plate may be configured to suspend from the hanging unit adjacent to the sidewall of the pool. The current angle may be about 90 degrees when the back supporting plate is suspended from the hanging unit.
The above-mentioned and other features and advantages of this disclosure, and the manner of attaining them, will become more apparent and will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate exemplary embodiments of the invention and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings, which are described below. The embodiments disclosed below are not intended to be exhaustive or limit the invention to the precise form disclosed in the following detailed description. Rather, the embodiments are chosen and described so that others skilled in the art may utilize their teachings. It will be understood that no limitation of the scope of the invention is thereby intended. The invention includes any alterations and further modifications in the illustrative devices and described methods and further applications of the principles of the invention which would normally occur to one skilled in the art to which the invention relates.
Referring first to
As discussed further herein, the orientation of flow generating device 6 within pool 102 may be altered to provide different current 7 patterns within pool 102, specifically different current angles α between current 7 and the adjacent sidewall 106. Current angle α may be about 0 degrees to about 180 degrees, more specifically about 0 degrees to about 90 degrees. For example, in
Flow generating device 6 is coupled to sidewall 106 of pool 102. In particular, a hanging assembly 100 operably couples flow generating device 6 to sidewall 106 of pool 102. Referring now to
Hanging unit 1 is selectively coupled to back supporting plate 2 and side supporting plate 3 and functions to couple the desired plate 2 or 3 of hanging assembly 100 onto sidewall 106 of pool 102. The illustrative hanging unit 1 includes a hooking unit 11 that includes a recess 13 contoured to receive or hook onto the upper surface of sidewall 106 such that hanging unit 1 suspends from the upper surface of sidewall 106. However, it is contemplated that alternate configurations of hooking unit 11 may be used to couple hanging unit 1 to sidewall 106. Hanging unit 1 also includes connecting rods 12 that are coupled to hooking unit 11. As shown in
Back supporting plate 2 may be coupled to back surface 62 of flow generating device 6 using one or more fasteners 63. Back supporting plate 2 includes recesses 22 configured to optionally receive connecting rods 12 of hanging unit 1. Back supporting plate 2 further includes a first half of free hinge portion 40a also referred to as a connecting column 21 that enables coupling of back supporting plate 2 to a second half of free hinge portion 40a on side supporting plate 3 as discussed further herein. Connecting column 21 is positioned at a side edge of back supporting plate 2 and includes a plurality of protrusions 23 with corresponding gaps 24 interposed between protrusions 23 as shown in
Side supporting plate 3 can optionally abut or otherwise support a side surface 64 of flow generating device 6 depending on the configuration of hanging assembly 100 as discussed further herein. Similar to back supporting plate 2, side supporting plate 3 includes recesses 32 configured to optionally receive connecting rods 12 of hanging unit 1. Side supporting plate 3 further includes the second half of free hinge portion 40a also referred to as a connecting column 31 that enables a freely rotatable coupling of back supporting plate 2 to side supporting plate 3 as discussed further herein. Connecting column 31 is positioned at a side edge of side supporting plate 3 and includes a plurality of protrusions 33 with corresponding gaps 34 interposed between protrusions 33 as shown in
As shown in
The friction hinge portion 40b of connector 40 includes a first friction plate 41, a second friction plate 42, pivot pin 43, and a nut 44. First friction plate 41 and second friction plate 42 are coupled to back supporting plate 2 and side supporting plate 3, respectively. Similar to connecting columns 21, 31, first friction plate 41 and second friction plate 42 include hollow protrusions 41A, 42A that are spaced apart with gaps 41B, 42B therebetween, respectively. Also similar to protrusions 23 and 33, protrusions 41A, 42A are in substantial alignment with each other and with protrusions 23 and 33 such that pivot 43 can be fed through protrusions 41A, 42A as discussed further herein.
When coupling back supporting plate 2 to side supporting plate 3, friction plates 41, 42 interlock with each other such that protrusions 41A of first friction plate 41 can be received within gaps 42B of second friction plate 42 and protrusions 42A of first friction plate 41 can be received within gaps 41B of second friction plate 42. Similar to the engagement of protrusions 23, 33, the interlocking of protrusions 41A, 41B maintains the alignment among protrusions 41A, 41B. Furthermore, when coupling back supporting plate 2 to side supporting plate 3, protrusions 41A, 42A, 23, and 33 align to form a passage through which pivot pin 43 can be received.
Pivot pin 43 couples back supporting plate 2 to side supporting plate 3 when fed through the passage formed by the alignment of hollowed protrusions 41A, 42A, 23, and 33. An upper end of pivot pin 43 further includes threads 45 to threadingly engage with nut 44 to adjustably couple back supporting plate 2 and side supporting plate 3 as discussed further herein. For example, first friction plate 41, second friction plate 42, pivot pin 43, nut 44, or any combination thereof may form a biasing member 8 to adjustably couple back supporting plate 2 and side supporting plate 3 as discussed further herein.
As shown in
To set the plate angle θ of plates 2, 3, connector 40 is positioned in a locked configuration. In this locked configuration, screw nut 44 is tightened onto threads 45 of pivot pin 43 such that screw nut 44 moves downwardly along pivot pin 43 and engages with friction plates 41, 42. The bottom end of pivot pin 43 may be retained beneath plates 2, 3 with an enlarged head, a through-pin, or another suitable structure. Such engagement applies a compressive force onto friction plates 41, 42 such that protrusions 41A and 42A frictionally engage each other to resist or prevent movement of plates 2, 3 about axis A of pivot pin 43. That is, engagement of screw nut 44 onto friction plates 41, 42 provides enough friction between protrusions 41A and 42A to prevent substantial movement of back supporting plate 2 and side supporting plate 3 about pivot pin 43, thereby maintaining the plate angle θ between back supporting plate 2 and side supporting plate 3 and current angle α between current 7 and sidewall 106.
To adjust the plate angle θ of plates 2, 3, connector 40 is positioned in a free or unlocked configuration. In this free configuration, screw nut 44 is loosened from threads 45 of pivot pin 43 and moves upwardly along pivot pin 43, which releases the engagement of screw nut 44 with friction plates 41, 42 and reduces the frictional engagement between protrusions 41A, 42A of friction plates 41, 42, respectively. This reduced friction enables movement of plates 2, 3 about axis A (
Referring now to
Referring now to
Finally, referring back to
Advantageously, hanging assembly 100 provides for flexibility in assembly. By having recesses 22, 32 in both back supporting plate 2 and side supporting plate 3, hanging unit 1 can be coupled to either plate 2 or 3, and then the corresponding plate 2 or 3 can be coupled to sidewall 106 of pool 102. The ability to couple either plate 2 or 3 to the sidewall 106 allows the user to vary the configuration of flow generating device 6 within hanging assembly 100 and within pool 102, as shown in
While this invention has been described as having exemplary designs, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
Number | Date | Country | Kind |
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201720732625.6 | Jun 2017 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2018/054633 | 6/22/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/235054 | 12/27/2018 | WO | A |
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Endless Pools, “Fastlane Pool: Cost effective and easy to install for a quality swim, year-round,” available at http://www.endlesspools.com/fastlane-pool.php at least as early as Dec. 18, 2014, 1 page. |
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20200269114 A1 | Aug 2020 | US |