Underwater pool lights are used in swimming pools, wading pools, fountains, and spas for illumination under the surface of the water. Conventional underwater lighting systems use a lens to direct the light emitted from a light source, such as an incandescent lamp. However, in underwater applications, when the only mechanism used for managing light distribution is lensing, light can be ineffectively dispersed. This is because the index of refraction of the lens is more like that of water than that of air. Thus, although lensed underwater lights are useful in many applications, lensing has inherent shortcomings including limited beam angles, flare, spherical and chromatic aberrations, etc.
In some cases, conventional underwater lens lighting can achieve some light distribution management by including an air gap between the light source and the back of the lens. However, the air gap insulates the heat generated by the lamp, which may introduce other challenges.
Some embodiments provide an underwater light that includes a lamp assembly, a tube assembly coupled to the lamp assembly, and a printed circuit board (PCB) assembly. The lamp assembly can include a housing and a lamp, the lamp having a plurality of lighting elements. The tube assembly can have a substantially hollow interior. The PCB assembly can be mechanically coupled to the tube assembly and electrically coupled to the lamp assembly. Each of the plurality of lighting elements can correspond to a window, and the windows can be arranged on the lamp assembly in a plurality of non-parallel planes. In some instances, each of the windows is arranged on a plane that is not parallel with the plane on which any of the other windows are arranged. In other instances, each of the windows is arranged on a plane that is not coplanar and is not parallel with the plane on which any of the other windows are arranged.
An underwater light designed to project light onto a surface is provided. The light includes a housing defining a cavity therein and a first circuit board including a first plurality of rows of light-emitting diodes (LEDs). The first circuit board is located within the cavity defined by the housing. The light further includes a first refractor assembly including a first plurality of rows of refractors, the first refractor assembly being coupled to the first circuit board. The underwater light is configured to produce a first light distribution on a first region of the surface having a first red-green-blue (RGB) ratio, and a second light distribution on a second region of the surface having a second RGB ratio.
In another embodiment, an underwater light includes a housing having a substantially dome shaped lens coupled to a back housing through a sealing gasket, the housing defining a cavity therein. A first circuit board including a first plurality of rows of light-emitting diodes (LEDs) is provided and is located within the cavity defined by the housing. A second circuit board having a second plurality of rows of LEDs is also provided and is located within the cavity defined by the housing and is electrically coupled to the first circuit board. A third circuit board having a third plurality of rows of LEDs is further provided and is located within the cavity defined by the housing and is electrically coupled to the first circuit board. The light also includes a first refractor assembly including a first plurality of rows of refractors, the first refractor assembly located adjacent to the first circuit board, a second refractor assembly having a second plurality of rows of refractors located adjacent to the second circuit board, and a third refractor assembly having a third plurality of rows of refractors located adjacent to the third circuit board. The underwater light is configured to produce a first light distribution on a first region of a surface having a first red-green-blue (RGB) ratio, a second light distribution on a second region of the surface having a second RGB ratio, and a third light distribution on a third region of the surface having a third RGB ratio.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
The following discussion is presented to enable a person skilled in the art to make and use embodiments of the invention. Various modifications to the illustrated embodiments will be readily apparent to those skilled in the art, and the generic principles herein can be applied to other embodiments and applications without departing from embodiments of the invention. Thus, embodiments of the invention are not intended to be limited to embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The following detailed description is to be read with reference to the figures, in which like elements in different figures have like reference numerals. The figures, which are not necessarily to scale, depict selected embodiments and are not intended to limit the scope of embodiments of the invention. Skilled artisans will recognize the examples provided herein have many useful alternatives and fall within the scope of embodiments of the invention.
As best seen in
The lamp housing 22 can also include the lamp attachment fitting 32. The lamp attachment fitting 32 is provided in the form of a ring 33 that is designed to mechanically couple the lamp assembly 12 to a niche or other underwater lighting or plumbing fixture of a pool, spa, or other body of water, such as a return fitting. In some applications, the lamp attachment fitting 32 and the integrating disc 26 each include a rotatable coupling structure designed to interact with each other. During installation, the lamp attachment fitting 32 and the integrating disc 26 can, therefore, be rotatably secured to an underwater lighting fixture and provide rotational positioning during installation. It is generally known that conventional pool and spa lighting fixtures installed during pool construction, for example, may have non-ideal rotational positioning. Due to the directional lighting features of the present invention, the integrating disc 26 and the lamp attachment fitting 32 allow for rotational movement until the underwater light 10 is secured into its final position.
Referring next to the lamp 24, the lamp 24 includes a plurality of lighting elements 30, each having a window 34. Each of the lighting elements 30 preferably includes at least one light emitting diode (“LED”). In some instances, the lighting elements 30 are spatially arranged such that none of the windows 34 are coplanar. Further, as shown in
In some embodiments, each of the lighting elements 30 includes a circuit having at least one LED. For protection and optimal light transmission, each lighting element 30 can be arranged within a LED carrier 36 formed in a generally cuboid shape, as shown in
The LED carriers 36 are exposed to the underwater environment and are designed to protect the internal circuitry of the underwater light 10 from water exposure. Accordingly, the circuit of the lighting element 30 can be mechanically coupled to the respective LED carrier 36 in a variety of ways to create a substantially waterproof barrier between the lighting element 30 and the wet environment. In some forms, printed circuit boards are fully encapsulated within the respective LED carrier 36 by a single or multiple-layer material, such as, for example, thermoplastic, and are affixed directly to the internal side of the window 34 of the respective LED carrier 36. The LED carriers 36, thus, provide mechanical, thermal, and electrical protection of the lighting elements 30 while simultaneously enabling transmission of light with varying wavelength and chromaticity. In other forms, printed circuit boards are affixed to a portion of the tube assembly 14. The tube assembly 14 can provide mechanical, thermal, and electrical protection for the lighting elements 30.
The lighting elements 30 can be configured to produce a variety of light intensities, colors, sequences, and patterns. For example, the underwater light 10 can produce light consisting of one of five different fixed colors. In some forms, the underwater light 10 can produce one of seven pre-programmed color shows by selectively energizing one or multiple LEDs at a specified time with a specified drive current. The lighting elements 30 can be grouped into channels designated for a specific color such as red, green, blue, and white. In some forms, when configured as a white-only unit, the device can produce light consisting of one chromaticity and three different intensity levels. In some embodiments, the white-only unit can produce monochromatic “cool white” light (e.g., generally known as about 6500K color temperature). In some embodiments, the white-only unit may employ LEDs producing monochromatic “warm white” light (e.g., generally known as about 2700K color temperature). In some embodiments, the underwater light 10 can employ LEDs producing monochromatic orange light (e.g., about 560 nm wavelength or greater) suitable for some applications.
Referring next to the tube assembly 14 of the underwater light 10, the tube assembly 14 (see
Overheating during use can be a concern for lighting systems in general. Here, heat generated by the PCBA 44 is dissipated to the surrounding environment by various transfer mechanisms including one or more of convection, conduction, and radiation. In some instances, heat dissipation can be improved by employing a thermally conductive filler within the tube assembly 14 that encompasses the PCBA 44. Some embodiments further contemplate the use of a heat sink. The PCBA 44 can also include a two-terminal solid state thermally sensitive transducer, e.g. a thermistor, which can be used to detect temperature changes within the circuit. The integration of a thermistor may help address concerns of overheating during use. In some embodiments, the tube housing 40 is formed with specific geometry, such as the inclusion of cooling fins to improve heat transfer from the housing to the environment. Likewise, conduction through the housing to the environment may be improved by employing a polymeric housing material boasting higher thermal conductivity.
The tube housing 40 and the end cap 42 can be formed from a suitable polymeric material, such as thermoplastic, and an elastomeric material, such as rubber, to create a substantially water proof barrier between the electronics of the underwater light 10 (e.g. the lighting elements 30 and the PCBA 44) and the underwater environment. As described above with respect to the lamp assembly 12 and the tube assembly 14, the tube housing 40 and the end cap 42 can be connected by joining methods, such as, for example, ultrasonic, vibratory, hot plate, or laser welding, or by a mechanical coupling such as a one-way annular snap joint. Also, a sealing element, such as epoxy, can be used to create a fluid tight barrier in the bore 48 through which the wiring extends out of the tube assembly 14. In this way, the electronics within the underwater light 10 can be protected from the underwater environment. In some instances, a sealing grommet 522 (shown in
When connected, the lamp housing 122 and tube assembly 114 form a mushroom shape, with the tube assembly 114 forming the mushroom stem and the lamp housing 122 forming the mushroom head. A top surface 140 of the lamp housing 122 includes a plurality of raised, concentric ridges 142, and a plurality of the windows 134 are positioned on the top surface 140, radially outward from the center of the top surface 140. A plurality of windows 134 are also positioned on the downward sloping outside face defined by a housing skirt 144. Further, a plurality of the pairs of windows 134 can be formed onto a raised surface 146, such that the raised surface 146 is tilted at an angle from the plane of the top 140 of the lamp housing 122 to protrude outwardly from the top surface 140. Some of the raised surfaces 146 can be tilted toward the center of the top surface 140, and some can be tilted away from the center of the top surface 140. The positioning of the lighting elements 130 provides an array of directional lighting sources that when energized, provide a highly uniform distribution of lighting intensity and chromaticity across illuminated pool and spa surfaces.
Each lighting element 330 is either formed integrally with (via thermoplastic encapsulation), or pressed against, or adjacent to, the interior wall of the windows 334. In some instances, the lighting element 330 is positioned directly adjacent (e.g., in direct contact with) the interior wall of the windows 334. The positioning minimizes the travel of light from the lighting elements 330 through the air before traveling to the water. In other instances, the lighting element 330 is not positioned directly adjacent to the interior wall of the windows 334 and there is a substantial air gap that provides enough space to utilize lensing to enhance the performance of the lighting element 330. The windows 334 are configured on the face plate 326 such that none of the lighting elements 330 of one window 334 are coplanar with the lighting elements 330 of another window 334.
As with the lamp and tube construction, heat dissipation in the single housing may further utilize heat sinks, thermally conductive fillers, or the like. Additionally, the rear housing 412 includes a bore 417 through which the electrical wiring extends out of the rear housing 412. Similar to other embodiments, a sealing element, such as epoxy, can be used to further create a fluid tight barrier. The front housing 411 may be multi-faceted so as to provide a plurality of substantially planar sections 418, or “windows”, which correspond to individual arrays of one or more LEDs 416 oriented to provide multi-directional lighting. The windows can utilize lensing techniques and may employ selective levels of opacity to provide light diffusion, similar to methods described for the underwater lights 10, 110. In some forms, the underwater light 410 includes an intermediate shell 419 that is designed to act as a visual barrier to conceal the PCBAs of the LED circuits 414 and the LED driver circuits 415 and improve visual appeal. The shell 419 may be produced from a polymeric or metallic material with selective reflective properties and of a type and color to minimize stray lighting effects due to internal reflection off of rear housing 412 and the PCBAs of the lighting and driver circuits 414, 415. Additionally, the shell 419 may also further camouflage the underwater light 410 and improve visual integration into the overall pool construction.
Referring to
The thermal pad 670 can be produced from a selective polymeric material boasting elevated thermal conductivity. Functionally, the thermal pad 670 can act as a heat sink or a thermal filler within the housing. The back housing 680 can be produced from a highly-corrosion resistant metal, such as stainless steel. The thermal pad 670 and the back housing 680 together provide a thermal pathway for heat generated by the circuit board with LEDs 660 to be dissipated to the environment via one or more of direct conduction, convection, and radiation.
One or more circuit boards having LEDs 660 can be provided as lighting elements for the underwater light 610. The circuit boards with LEDs 660 can be provided in the form of a conductive material, such as steel, copper, or aluminum. Moreover, one or more refractor assemblies 650 can be fitted over the circuit boards 660 to provide optical manipulations to the lights emitted from the circuit boards 660. It is to be appreciated that the LEDs 660 can be integrated with the circuit boards, or the LEDs 660 can be electrically coupled to the circuit boards without being integrated thereto.
The underwater light 610 is shown in more detail in
When using more than one circuit board 660, individual circuit boards 660 can be electrically coupled to one another via wires 662. In an alternative embodiment, only one circuit board 660 is used and the single circuit board 660 can be made out of flexible materials so that the single circuit board 660 can be bent or folded to provide light at different angles. When more than one circuit board 660 is used, each individual circuit board 660 can have a corresponding refractor assembly 650 fitted over it as shown in
Referring to
In another example, six red LED's may be distributed in different positions in the top two rows, whereas three blue and three green LED's may be provided in alternative positions in the top two rows. Other arrangements of LEDs 664 can also be used depending on the desired lighting distribution. Further, the specific arrangement of the LEDs 664 can also depend on other factors such as the number of LEDs 664 and whether the LEDs 664 are driven at the same or different power levels.
Referring to
In an exemplary embodiment, angles a, c, and e can be about 15 degrees, angles b, and d can be about 41 degrees, and angle f can be about 90 degrees. Using the example in connection with
In further embodiments, the angles a, c, and e can be between about 5 degrees to about 35 degrees (or between 5 degrees and 35 degrees), and angles b, and d can be between about 25 degrees and about 60 degrees (or between 25 degrees and 60 degrees). In other embodiments, the angles b, d, and f can be at least twice of angles a, c, and e. Moreover, the angles a, c, and e can be the same or substantially the same, but in some embodiments, the angles a, c, and e can differ from one another. In yet another embodiment, two of the angles a, c, and e, can be the same or substantially the same while the remaining angle is different. Likewise, the angles b, d, and f can be the same or substantially the same, but in some embodiments, the angles b, d, and f can differ from one another, or two of the angles can be the same while the remaining one differs.
In general, as light travels a distance through water, the red wavelengths decrease in intensity more than the blue or the green affecting the color temperature observed depending on the distance the light travels in water. In a pool or a spa, the floor of such floor is generally closer to where an underwater light is normally positioned than the opposite or side walls. Further, the distance from a light source to a spot on the floor or adjacent wall increases rapidly as the angle between the light source and the spot increases. Thus, uniform color in the pool or the spa can be achieved by sending different ratios of red to green and blue light depending on the angle of the light from the source, with less red light directed pointing straight down and straight to the sides and gradually increasing as the angle increases.
Referring to
Turning to
Similar to the main circuit board 660A, a refractor assembly 650 having one or more refractors 652 can be fitted over the side circuit board 660B. Referring to
An additional side reflector 654 can also be used for the side circuit boards 660B to prevent light from shining backward as shown in
Referring to
Thus, an improved underwater light is provided by this disclosure. The disclosed underwater light is expected to have improved resistance to impact, improved reliability, and more uniform dissipation of heat generated by lighting elements during operation.
It will be appreciated by those skilled in the art that while the invention has been described above in connection with particular embodiments and examples, the invention is not necessarily so limited, and that numerous other embodiments, examples, uses, modifications and departures from the embodiments, examples and uses are intended to be encompassed by the claims attached hereto. The entire disclosure of each patent and publication cited herein is incorporated by reference, as if each such patent or publication were individually incorporated by reference herein. Various features and advantages of the invention are set forth in the following claims.
This Application claims priority to U.S. Provisional Patent Application Ser. No. 62/705,660, filed on Jul. 9, 2020, entitled “Underwater Light Assembly and Method”, and U.S. patent application Ser. No. 17/305,558 filed on Jul. 9, 2021, the entire disclosures of which is incorporated herein by reference.
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20230213178 A1 | Jul 2023 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 17305558 | Jul 2021 | US |
Child | 18183904 | US |