Underwater Light Having a Replaceable Light-Emitting Diode (LED) Module and Cord Assembly

TECHNICAL FIELD

The present disclosure relates generally to the field of underwater lights for pools and spas. More specifically, the present disclosure relates to an underwater light having a replaceable light-emitting diode (LED) module and a cord assembly.

RELATED ART

In the underwater lighting field, submersible luminaires are known and commonly used. These devices are conventionally made from a combination of metal, plastic, and glass. The various electrical components within a submersible luminaire housing generate heat. A difference between the temperature of the air within the submersible luminaire housing and the temperature of pool water around the submersible luminaire can cause the formation of condensation on an interior portion of a submersible luminaire lens. Condensation on the interior portion of the submersible luminaire lens can cause a degradation in luminaire luminosity and can damage the electrical components or luminaire. As a result of the foregoing, it would be desirable to provide a submersible luminaire lens constructed of a material which prevents the formation of condensation on the interior portion of the submersible luminaire lens and is electrically insulative.

In addition, the various electrical components within the submersible luminaire housing require adequate heat dissipation through the use of heat sinks. A heat sink may draw heat away from the electrical components and dissipate it, thereby preventing any damage to the electrical components or luminaire. Metal components are often utilized for a heat sink due to their high thermal conductivity compared to plastics, glass, and other materials. However, a metal heat sink is also electrically conductive.

In submersible luminaires, the exposed metal portions of the luminaire, as well as components external to the luminaire housing (e.g., the luminaire cord and a niche), require safe electrical grounding. This requires significant design efforts and expense to assure the safety of the device. Indeed, a critical interface must be provided between the metal components of the luminaire and the niche into which the luminaire is installed, to allow for adequate grounding. Such an interface facilitates the safe grounding and bonding of the metal components. Due to the complexity of such interfaces and the necessity for a luminaire and niche to create a safe interface, Underwriter's Laboratories has required that luminaires and niches be fabricated by the same manufacturer. As a result of the foregoing, it would be desirable to provide a submersible luminaire housing constructed of a material which is thermally conductive yet electrically insulative. It would also be desirable to provide components external to the luminaire housing (e.g., the luminaire cord) which are also electrically insulative.

Thermally conductive and electrically insulative polymer materials are known. These materials allow for the dissipation of heat while restricting the conduction of electricity therethrough, making them ideal for a situation in which thermal energy must be transferred yet electrical energy must be insulated.

In submersible luminaires, one or more light-emitting elements (e.g. light emitting diodes (LEDs)) mounted on a printed circuit board (PCB) within the submersible luminaire housing may become inoperable due to extended use or for other reasons. Conventional luminaires are hermetically sealed and therefore must be replaced when LEDs are inoperable (e.g., when LEDs burn out). As a result of the foregoing, it would be desirable to provide a submersible luminaire with a replaceable PCB to avoid replacing a luminaire in its entirety when LEDs mounted on the PCB are inoperable.

Accordingly, the underwater light of the present disclosure addresses these and other needs.

SUMMARY

The present disclosure relates to underwater light having a replaceable light-emitting diode (LED) module and cord assembly. The underwater light includes a lens, a bezel, a screw, a cable attachment assembly, a mounting flange, a rear housing, a fastening assembly, an internal lens, a printed circuit board (PCB) including light-emitting diodes (LEDs) mounted thereon, a heat sink, and an electronics assembly. The lens surface comprises a glass layer configured to prevent the formation of condensation on an interior portion of the lens. The glass layer thermally insulates the underwater light and thereby prevents the formation of condensation caused by a difference between the temperature of the air within the underwater light and the temperature of pool water around the underwater light. The assembly of the underwater light provides for the dissipation of heat away from the PCB thereby cooling the LEDs and electronic components mounted thereon. The electrically non-conductive nature of the exterior components of the underwater light (i.e., the lens, the bezel, the mounting flange and the rear housing) permit the underwater light to be installed in any location in a pool or spa without requiring specific approval of Underwriters Laboratories (UL). Further, since the exterior of the underwater light is electrically non-conductive, no specific bonding or grounding of the underwater light is necessary. Also, an optically-transparent potting compound encapsulating the PCB and the LEDs and electronic components mounted thereon in addition to the ability to remove the rear housing or the coupled lens and rear housing of the underwater light provide for the safe replacement of the PCB mounted within the underwater light when an LED mounted thereon is inoperable.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing features of the present disclosure will be apparent from the following Detailed Description of the Invention, taken in connection with the accompanying drawings, in which:

FIG. 1 is a perspective view of the underwater light of the present disclosure;

FIG. 2 is a side view of the underwater light of FIG. 1;

FIG. 3 is an exploded view of the underwater light of FIG. 2;

FIG. 4 is a perspective view of the lens of the underwater light of the present disclosure;

FIG. 5 is a bottom view of the lens of the underwater light of FIG. 4;

FIG. 6 is a perspective view of the bezel of the underwater light of the present disclosure;

FIG. 7 is a perspective view of the mounting flange of the underwater light of the present disclosure;

FIG. 8 is an exploded perspective view of the internal lens, the printed circuit board (PCB) and the heat sink of the underwater light of the present disclosure;

FIG. 9 is a perspective view of the PCB of FIG. 8;

FIG. 10 is a perspective view of the rear housing of the underwater light of the present disclosure;

FIG. 11 is a perspective view of the cable attachment assembly for providing a watertight connection between a power and/or communications cord and the underwater light of the present disclosure;

FIG. 12 is an exploded view of the underwater light of the present disclosure showing assembly of the lens, the bezel, the mounting flange and the rear housing;

FIG. 13a is a perspective view of another embodiment of the underwater light of the present disclosure;

FIG. 13b is a perspective view of the lens of the underwater light of FIG. 13a;

FIG. 14 is a bottom view of the lens of the underwater light of FIG. 13a;

FIG. 15 is a perspective view of a rear housing plate of the underwater light of FIG. 13a;

FIG. 16 is a perspective view of the rear housing of the underwater light of FIG. 13a;

FIG. 17 is a perspective view of the front of the heat sink of the underwater light of FIG. 13a;

FIG. 18 is a perspective view of the rear of the heat sink of the underwater light of FIG. 13a;

FIG. 19 is a perspective view of the electronics assembly of the underwater light of FIG. 13a;

FIG. 20 is a perspective view of the cable attachment assembly for providing a watertight connection between a power and/or communications cord and the underwater light of FIG. 13a; and

FIG. 21 is an exploded view of the underwater light of FIG. 13a showing assembly of the lens, the rear housing plate and the rear housing.

FIG. 22 is a perspective view of another embodiment of the underwater light of the present disclosure;

FIG. 23 is a side view of the underwater light of FIG. 22;

FIG. 24 is a rear view of the underwater light of FIG. 22

FIG. 25 is an exploded view of the underwater light of FIG. 22;

FIG. 26 is an exploded perspective view of the underwater light of FIG. 22;

FIG. 27 is a perspective view of the bezel of the underwater light of FIG. 22;

FIG. 28 is a perspective view of the lens of the underwater light of FIG. 22;

FIG. 29 is a perspective view of the rear housing plate of the underwater light of FIG. 22;

FIG. 30 is a perspective view of the printed circuit board (PCB) and the heat sink of the underwater light of FIG. 22;

FIG. 31 is a perspective view of the rear housing of the underwater light of FIG. 22;

FIG. 32 is a perspective view of the electronics assembly of the underwater light of FIG. 22;

FIG. 33 is a perspective view of the mounting flange of the underwater light of FIG. 22;

FIG. 34 is a perspective view of the underwater light of FIG. 22, showing assembly of the bezel, the lens, the rear housing and the mounting flange;

FIG. 35 is a perspective view of the underwater light of FIG. 22, showing assembly of the bezel, the lens coupled to the rear housing and the mounting flange;

FIG. 36 is an exploded perspective view of the positioning assembly of the underwater light of FIG. 22;

FIG. 37 is a cross sectional view of the underwater light of FIG. 22;

FIG. 38 is a perspective view of the cable attachment assembly for providing a watertight connection between a power and/or communications cord and the underwater light of the present disclosure; and

FIG. 39 is an exploded perspective view of the cable attachment assembly of FIG. 38.

DETAILED DESCRIPTION

The present disclosure relates to an underwater light having a replaceable light-emitting diode (LED) module and cord assembly, as described in detail below in connection with FIGS. 1-39.

Turning to the drawings, FIG. 1 is a perspective view showing the underwater light 10 of the present disclosure. The underwater light 10 may include a lens 12 having a central portion 12a and a peripheral region including an annular wall 12b (see FIG. 4), a bezel 14 including a screw aperture 14a and a plurality of peripheral recesses 14b, and a cable attachment assembly 18. The term “lens,” as used herein, refers not only to an optical component which can focus light (as in a conventional lens), but also to components which are merely transparent and do not focus light, such as a transparent and/or translucent cover. The bezel 14 is received by and couples to a mounting flange 20 (see FIG. 3). The bezel 14 is positioned about the central lens portion 12a. The underwater light 10 can be positioned such that the aperture 14a can be rotated up to 360 degrees from the typical 12 o'clock position of existing underwater lights. This allows the lens 12 to be positioned to direct light in a preferred direction in a pool or spa, and to accommodate installation of the light 10 in niches having various orientations.

FIG. 2 is a side view showing the underwater light 10 of the present disclosure. As mentioned above, the bezel 14 is received by and couples to the mounting flange 20. In addition, a rear housing 22 couples to a rear of the mounting flange 20. The lens 12 is received by and couples to the rear housing 22 such that the lens 12 is in watertight communication with the rear housing 22. The rear housing 22 includes a raised portion 24 having a recess 24a (see FIG. 3). The recess 24a is configured to couple to the cable attachment assembly 18 to allow external power to be supplied to the electrical components of the underwater light 10 by way of a power cable (not shown) and/or control/communications cables (not shown) and to create a watertight seal with such components.

FIG. 3 is an exploded view of the underwater light 10 of FIG. 2. As shown in FIG. 3, the underwater light 10 comprises a plurality of components including the lens 12; the bezel 14; a screw 16; the cable attachment assembly 18; the mounting flange 20; the rear housing 22; an internal lens 26; a printed circuit board 28; a heat sink 30; an electronics assembly 32; and a fastening assembly 36. The components are discussed in further detail below.

FIG. 4 is a perspective view of the lens 12 of the underwater light 10 of the present disclosure. As mentioned above, the lens 12 includes a central lens portion 12a, an annular wall 12b, a plurality of tabs 12c and a recess 12d. The annular wall 12b and the lens portion 12 together define the recess 12d. As discussed in further detail below, the recess 12d receives a rear housing annular projection 22a. In addition, the plurality of tabs 12c are configured to engage a rear housing plurality of notches 22b such that the lens 12 is in water tight communication with the rear housing 22.

The lens 12 could be formed using a suitable manufacturing process (e.g., injection molding, compression molding, thermoforming, etc.). The lens 12 could be formed from any suitable, electrically-insulating material, such as glass or a polymeric material (e.g., plastic). Such a material could include, but is not limited to, amorphous transparent copolymer having a cyclic olefin copolymer copolymerized from norbornene and ethylene using a metallocene catalyst and possessing properties important in optical components such as lenses. Such material possesses properties including, but not limited to, high transparency, low birefringence, high flowability for precision molding, high heat resistance and negligible water absorption. The lens 12 may also be formed from an unbreakable transparent plastic which allows for a light curing adhesive to be utilized for bonding the lens 12 to the rear housing 22.

FIG. 5 is a bottom view of the lens 12 of the underwater light 10 of FIG. 4. The outer surface of the lens 12 has a silicon dioxide (SiO₂) coating or layer G configured to prevent the formation of condensation on an interior portion of the lens 12. The coating or layer G may be deposited by chemical vapor deposition. Alternatively the coating or layer G may be formed within the lens 12 or deposited on the interior portion of the lens 12. The coating or layer G insulates the underwater light 10 and thereby prevents the formation of condensation caused by a difference between the temperature of the air within the underwater light 10 and the temperature of pool water around the underwater light 10. It is noted that the lens 12 need not include the annular wall 12b. In such circumstances, the lens 12 could be shaped as a conventional lens for an underwater pool light, e.g., in the shape of a convex disc, and the lens 12 could be held in watertight position against the rear housing 22, e.g., by the bezel 14, or by other means.

FIG. 6 is a perspective view of the bezel 14 of the underwater light 10 of the present disclosure. The bezel 14 includes the screw aperture 14a, the plurality of peripheral recesses 14b and an annular projection 14c. As discussed in further detail below, the annular projection 14c, positioned on an interior of the bezel 14, is received by the mounting flange central aperture 20c. In addition, the bezel 14 couples to the mounting flange 20 via a plurality of mounting flange tabs 20b and a plurality of mounting flange fingers 20d which respectively engage the plurality of peripheral recesses 14b and a plurality of tabs (not shown) positioned on an interior of the bezel 14.

The aperture 14a could be elongate in shape to receive the screw 16 (see FIG. 3) in various positions to accommodate niches or recesses of a pool or spa of various diameters, thus allowing the underwater light 10 to be installed in multiple locations and without requiring modification of the underwater light 10. Additionally, a plurality of round apertures could be provided, extending outwardly from the center of the underwater light 10 and toward the periphery of the underwater light 10 to accommodate multiple screw positions.

The bezel 14 could be sized and shaped so as to cover niches or recesses of pools or spas having different diameters, or it could be over sized so as to cover a plurality of different diameters. The bezel 14 could be constructed of a thermally conductive and electrically insulative polymer material (e.g. plastic). In addition, the bezel could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 7 is a perspective view of the mounting flange 20 of the underwater light 10 of the present disclosure. The mounting flange 20 includes at least one aperture 20a, a plurality of tabs 20b, a central aperture 20c, and a plurality of fingers 20d. The central aperture 20c is configured to receive the bezel annular projection 14c. In addition, the plurality of tabs 20b are configured to respectively engage the plurality of bezel peripheral recesses 14b to couple the bezel 14 to the mounting flange 20. Also, the plurality of fingers 20d are configured to respectively engage the plurality of tabs positioned on the interior portion of the bezel 14 to couple the bezel 14 to the mounting flange 20.

The mounting flange 20 could be constructed of a thermally conductive and electrically insulative polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive materials (e.g., plastic). In addition, the mounting flange 20 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 8 is an exploded perspective view of an internal lens 26, a printed circuit board (PCB) 28 and a heat sink 30 of the underwater light 10 of the present disclosure. The PCB 28 includes a plurality of light-emitting diodes (LEDs) 28a and an electrical component or a plurality of electrical components 28b. The heat sink 30 includes an inner surface 30a and is positioned on a central inner surface of the rear housing 22.

The internal lens 26 can be positioned between the lens 12 and the PCB 28 to direct or focus light generated by the LEDs 28a. The internal lens 26 could be a collimator lens for producing parallel beams of light from the light generated by the LEDs 28a, or other desired types of lenses. Also, the collimator lens could be used in conjunction with a spreader lens.

In addition to the LEDs 28a, the PCB 28 may include several electronic components 28b including, but not limited to, controllers, transistors, resistors, wiring harnesses, microprocessors, etc. The PCB 28 is affixed to the inner surface 30a of the heat sink 30 such that the PCB 28 is enclosed by the internal lens 26 and the heat sink 30. The PCB 28 could be bonded to the heat sink inner surface 30a by means of a thermally conductive material, such as a thermally-conductive grease, adhesive or potting compound. The thermally-conductive adhesive could include thermally-conductive, fiberglass-reinforced, pressure-sensitive adhesive tape, or a thermally-conductive, filled polymer composite interface including an adhesive layer. The application of thermally conductive material allows for the PCB 28 to be in thermal communication with the heat sink 30 and subsequently the rear housing 22. This allows for the transfer of heat from the LEDs 28a and the electronic components 28b of the PCB 28, through the thermally conductive material, to the heat sink 30 and the exterior of the rear housing 22. It is also noted that a separate layer (or plate) of thermally conductive material could be positioned between the PCB 28 and the heat sink inner surface 30a. Such a separate layer (or plate) could be attached to the PCB 28 and the heat sink inner surface 30a using a thermally-conductive adhesive.

The heat sink 30 is constructed of thermally conductive and electrically insulative material and is positioned on a central inner surface of the rear housing 22. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the heat sink 30 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. The presence of the heat sink 30 on the inner surface of the rear housing 22 allows for heat to be properly dissipated away from the PCB 28 thereby cooling the LEDs 28a and the electrical components 28b. The heat sink 30 could also be molded to the rear housing 22 during its fabrication or may be attached through a suitable means (e.g. at least one screw or an adhesive).

FIG. 9 is a perspective view of the PCB 28 of FIG. 8. The PCB 28 may include LEDs 28a in addition to several electronic components 28b including, but not limited to, controllers, transistors, resistors, etc. The PCB 28 is affixed to the inner surface 30a of the heat sink 30 such that the PCB 28 is enclosed by the internal lens 26 and the heat sink 30. Various optical and/or dielectric components could be used within the underwater light 10 in addition the internal lens 26 to enhance lighting, and to promote added safety.

For example, the underwater light 10 could include a plurality of light culminators to respectively be in optical communication with the plurality of LEDs 28a. The light culminators collect light generated by the LEDs 28a to provide high intensity output. Also, optical light “pipes” could be used in place of the culminators, the pipes being made from a solid plastic or glass material and transmitting light from the LEDs 28a directly to an outer surface(s) of the underwater light 10 (e.g., to the lens 12).

It is noted the underwater light 10 could be utilized in horticultural applications. For example, the underwater light 10 could be utilized in underwater vertical farms to cultivate seaweed, rice, wasabi, water chestnut, etc. Accordingly, the respective colors of the LEDs 28a could be specified to target the wavelengths at which various chlorophyll pigments in plants absorb light to enable photosynthesis. For example, the LEDs 28a could be a variation of blue to target a wavelength spectrum of 400 nm to 500 nm and/or a variation of red to target a wavelength spectrum of 600 nm to 700 nm at which each of chlorophyll A and chlorophyll B absorb light. The LEDs 28a could also be a variation of white (e.g., magenta and light green) to provide for visual inspection of plant growth and/or harvest. In addition, the respective colors of the LEDs 28a could be modified according to the various stages of plant growth (seedlings, flowering, harvest, etc.) to promote an efficient plant growth cycle and a greater plant yield.

Also an optically transparent potting compound could be used to encapsulate the LEDs 28a, as well as the PCB 28 to which the LEDs 28a are mounted and portions of the culminators. The potting compound could encapsulate the LEDs 28a and the PCB 28 if the culminators are not provided. The potting compound protects the LEDs 28a and the PCB 28 from exposure to water in the event that the underwater light 10 is no longer watertight, thereby protecting against electrical shock and promoting safety. Also, the optically transparent potting compound encapsulating the PCB 28 and the LEDs 28a mounted thereon in addition to the ability to remove the rear housing 22 of the underwater light provide for the safe replacement of the PCB 28 mounted within the underwater light 10 when one of the LEDs 28a is inoperable.

FIG. 10 is a perspective view of the rear housing 22 of the underwater light 10 of the present disclosure. The rear housing 22 includes an annular projection 22a, a plurality of notches 22b and the heat sink 30. As mentioned above, the heat sink 30 may be molded to the rear housing 22 during its fabrication or may be coupled to the rear housing 22 through a suitable means (e.g. at least one screw or an adhesive). The rear housing 22 may be overmolded over the electronics assembly 32. In addition, an optically transparent potting compound could be used to encapsulate the electronics assembly 32. The annular projection 22a is received by the lens recess 12d formed by the lens annular wall 12b. The plurality of notches 22b respectively engage the plurality of lens tabs 12c to couple the lens 12 to the rear housing 22. In addition, the annular projection 22a could be bonded with the lens recess 12d through a light curing adhesive, or any other suitable adhesive, to provide a watertight seal for the underwater light 10. The positons of the annular projection 22a and the lens recess 12d could be reversed such that the annular projection 22a could be provided on the lens 12, and the recess 12d could be provided on the rear housing 22.

Also, it is noted that the annular projection 22a need not be provided to facilitate the coupling of the lens 12 to the rear housing 22. Indeed, the lens 12 and the rear housing 22 could be coupled to each other by way of corresponding flat annular surfaces which are coupled to each other by gluing, bonding, etc., to create a watertight seal. Further, a gasket or O-ring could be used to create a watertight seal between the lens 12 and the rear housing 22. Still further, the lens 12 could be coupled to the rear housing 22 by way of a watertight threaded connection, i.e., the lens 12 could be threaded onto the rear housing 22 and vice versa. Also, the lens 12 could be coupled to the rear housing 22 by way of adhesives, sonic welding, etc.

The rear housing 22 is constructed of a thermally conductive and electrically insulative polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the rear housing 22 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. It is noted that the entirety of the rear housing 22 need not be formed of a thermally-conductive polymeric material. Rather, only a desired portion of the housing wall 18 could be formed from such material, in locations where significant amount of heat are generated. In such circumstances, the remainder of the rear housing 22, as well as the bezel 14, could be formed by a non-thermally-conductive polymeric material, and the thermally-conductive portion could be coupled to the non-thermally-conductive portion by way of insert molding, overmolding, sonic welding, adhesives, etc.

FIG. 11 is a perspective view of the cable attachment assembly 18 for providing a watertight connection between a power and/or communications cord and the underwater light 10 of the present disclosure. The cable attachment assembly 18 includes a PCB adapter 18a having apertures 34, a base connector 18b, a cap connector 18c, a plug nut 18d and a cord 18c which houses a power/and or communications cord (not shown). Each of the apertures 34 of the PCB adapter 18a are configured to receive a terminal post (not shown) electrically coupled to the PCB 28 and the electronics assembly 32. For example, each terminal post could be soldered to one or more conductor traces of the PCB 28 and the electronics assembly 32. The terminal posts project through the base connector 18b. The threaded plug nut 18d is threaded onto a threaded aperture formed by a coupling of the base connector 18b and the cap connector 18c. The threaded plug nut 18d forms a watertight seal with the coupled base connector 18b and cap connector 18c via an O-ring or other sealing means. In addition, the threaded plug nut 18d receives, in watertight communication (e.g., by epoxy, gluing, etc.), the cord 18e which houses the power/and or communications cord. Each conductor of the power and/or communications cord is coupled to respective projections of the terminal posts, thereby completing electrical connection of the power and/or communications cord to the PCB 28 and electronics assembly 32. It is noted that the terminal posts and terminal post projections could be encapsulated with a potting compound.

FIG. 12 is an exploded perspective view of the underwater light 10 of the present disclosure showing an assembly of the lens 12, the bezel 14, the mounting flange 20 and the rear housing 22. The rear housing annular projection 22a is received by the lens recess 12d formed by the lens annular wall 12b. The plurality of rear housing notches 22b respectively engage the plurality of lens tabs 12c to couple the lens 12 to the rear housing 22. The mounting flange central aperture 20c is configured to receive the bezel annular projection 14c (not shown). In addition, the plurality of mounting flange tabs 20b are configured to respectively engage the plurality of bezel peripheral recesses 14b to couple the bezel 14 to the mounting flange 20. The plurality of mounting flange fingers 20d are configured to respectively engage the plurality of tabs (not shown) positioned on the interior portion of the bezel 14 to couple the bezel 14 to the mounting flange 20. The bezel aperture 14a could be elongate in shape to receive the screw 16 (not shown) such that a projection of the screw 16 may be received by the mounting flange aperture 20a.

Advantageously, the electrically non-conductive nature of the exterior components of the underwater light 10 of the present disclosure (i.e., the lens 12, the bezel 14, the mounting flange 20 and the rear housing 22) permit the underwater light 10 to be installed in any location in a pool or spa without requiring specific approval of Underwriters Laboratories. Further, since the exterior of the underwater light 10 is electrically non-conductive, no specific bonding or grounding of the underwater light 10 is necessary. It is also noted the rear housing 22 prevents contact with high voltage components of the underwater light 10 such as power supply components, line-level (AC) power, etc. In addition, the optically transparent potting compound encapsulating the PCB 28 and the LEDs 28a and electronic components 28b mounted thereon and the ability to remove the rear housing 22 of the underwater light 10 provide for the safe replacement of the PCB 28 mounted within the underwater light 10 when an LED 28a mounted thereon is inoperable.

FIG. 13a is a perspective view showing the underwater light 100 of the present disclosure. The underwater light 100 may include a lens 120 having a central portion 120a and a peripheral region including an annular wall 120b (see FIGS. 13a and 14), a bezel 140 including a screw aperture 140a and a plurality of peripheral recesses 140b, and a cable attachment assembly 180 (see FIG. 20). The term “lens,” as used herein, refers not only to an optical component which can focus light (as in a conventional lens), but also to components which are merely transparent and do not focus light, such as a transparent and/or translucent cover. The bezel 140 is received by and couples to a mounting flange 200 (not shown). The mounting flange 200 can be similar to the mounting flange 20 of FIG. 7 such that the bezel 140 may be received by and couples to the mounting flange 20. The bezel 140 is positioned about the central lens portion 120a. The underwater light 100 can be positioned such that the aperture 140a can be rotated up to 360 degrees from the typical 12 o'clock position of existing underwater lights. This allows the lens 120 to be positioned to direct light in a preferred direction in a pool or spa, and to accommodate installation of the underwater light 100 in niches having various orientations.

FIG. 13b is a perspective view of the lens 120 of the underwater light 100 of FIG. 13a. The lens 120 includes a central lens portion 120a, an annular wall 120b, a plurality of slots 120c and a recess 120d. The annular wall 120b and the lens portion 120 together define the recess 120d. As discussed in further detail below, the recess 120d receives the rear housing 220. In addition, the plurality of slots 120c are configured to engage a rear housing plurality of hooks 220a such that the lens 120 is in water tight communication with the rear housing 220.

The lens 120 could be formed using a suitable manufacturing process (e.g., injection molding, compression molding, thermoforming, etc.). The lens 120 could be formed from any suitable, electrically-insulating material, such as glass or a polymeric material (e.g., plastic). Such a material could include, but is not limited to, amorphous transparent copolymer having a cyclic olefin copolymer copolymerized from norbornene and ethylene using a metallocene catalyst and possessing properties important in optical components such as lenses. Such a material possesses properties including, but not limited to, high transparency, low birefringence, high flowability for precision molding, high heat resistance and negligible water absorption. The lens 120 may also be formed from an unbreakable transparent plastic which allows for a light curing adhesive to be utilized for bonding the lens 120 to the rear housing 220.

FIG. 14 is a bottom view of the lens 120 of the underwater light 100 of FIG. 13a. The outer surface of the lens 120 has a silicon dioxide (SiO₂) coating or layer G configured to prevent the formation of condensation on an interior portion of the lens 120. The coating or layer G may be deposited by chemical vapor deposition. Alternatively the coating or layer G may be formed within the lens 120 or deposited on the interior portion of the lens 120. The coating or layer G insulates the underwater light 100 and thereby prevents the formation of condensation caused by a difference between the temperature of the air within the underwater light 100 and the temperature of pool water around the underwater light 100. It is noted that the lens 120 need not include the annular wall 120b. In such circumstances, the lens 120 could be shaped as a conventional lens for an underwater pool light, e.g., in the shape of a convex disc, and the lens 120 could be held in watertight position against the rear housing 220, e.g., by the bezel 140, or by other means.

FIG. 15 is a perspective view of a rear housing plate 400 of the underwater light 100 of the present disclosure. The rear housing plate 400 includes a plurality of notches 400a and an annular projection 400b and can be positioned between the lens 120 and the rear housing 220. The annular projection 400b is received by the lens recess 120d formed by the lens annular wall 120b. The plurality of notches 400a engage the rear housing 220 such that the rear housing plate 400 is in water tight communication with the rear housing 220. In addition, the annular projection 400b could be bonded with the lens recess 120d through a light curing adhesive, or any other suitable adhesive, to provide a watertight seal for the underwater light 100. The positons of the annular projection 400b and the lens recess 120d could be reversed such that the annular projection 400b could be provided on the lens 120, and the recess 120d could be provided on the rear housing plate 400.

Also, it is noted that the annular projection 400b need not be provided to facilitate the coupling of the lens 120 to the rear housing plate 400. Indeed, the lens 120 and the rear housing plate 400 could be coupled to each other by way of corresponding flat annular surfaces which are coupled to each other by gluing, bonding, etc., to create a watertight seal. Further, a gasket or O-ring could be used to create a watertight seal between the lens 120 and the rear housing plate 400. Still further, the lens 120 could be coupled to the rear housing plate 400 by way of a watertight threaded connection, i.e., the lens 120 could be threaded onto the rear housing plate 400 and vice versa. Also, the lens 120 could be coupled to the rear housing plate 400 by way of adhesives, sonic welding, etc.

The rear housing plate 400 could be constructed of an electrically insulative and thermally conductive polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the rear housing plate 400 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 16 is a perspective view of the rear housing 220 of the underwater light 100 of the present disclosure. The rear housing 220 includes a plurality of hooks 220a. The heat sink 300 may be molded to the rear housing 220 during its fabrication or may be coupled to the rear housing 220 through a suitable means (e.g. at least one screw or an adhesive). The rear housing 220 may be overmolded over the electronics assembly 320 including a control board 320a and a network board 320b. In addition, an optically transparent potting compound could be used to encapsulate the electronics assembly 320.

As mentioned above, the rear housing plate 400 includes a plurality of notches 400a and an annular projection 400b and can be positioned between the lens 120 and the rear housing 220. The plurality of notches 400a engage the rear housing 220 such that the rear housing plate 400 is in water tight communication with the rear housing 220. The annular projection 400b is received by the lens recess 120d formed by the lens annular wall 120b. In addition, the plurality of rear housing hooks 220a respectively engage the plurality of lens slots 120c to couple the lens 120 to the rear housing 220.

The rear housing 220 is constructed of a thermally conductive and electrically insulative polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the rear housing 220 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. It is noted that the entirety of the rear housing 220 need not be formed of a thermally-conductive polymeric material. Rather, only a desired portion of the rear housing wall could be formed from such material, in locations where significant amount of heat are generated. In such circumstances, the remainder of the rear housing 220 could be formed by a non-thermally-conductive polymeric material, and the thermally-conductive portion could be coupled to the non-thermally-conductive portion by way of insert molding, overmolding, sonic welding, adhesives, etc.

FIG. 17 is a perspective view of the front of the heat sink 300 of the underwater light 100 of the present disclosure and FIG. 18 is a perspective view of the rear of the heat sink 300 of the underwater light 100 of the present disclosure. The heat sink 300 includes an inner surface 300a and is positioned on a central inner surface of the rear housing 220. The heat sink 300 also includes a plurality of fins 300b located on the rear of the heat sink 300 to promote heat dissipation. The plurality of fins 300b may be rectangular or trapezoidal in shape, continuous or segmented, and/or arranged in a vertical, horizontal or intersecting pattern.

The heat sink 300 is constructed of thermally conductive and electrically insulative material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the heat sink 300 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. The presence of the heat sink 300 on the inner surface of the rear housing 220 allows for heat to be properly dissipated away from the PCB 280 (not shown) thereby cooling the LEDs 280a (not shown) and the electrical components 280b (not shown). The heat sink 300 could also be molded to the rear housing 22 during its fabrication or may be attached through a suitable means (e.g. at least one screw or an adhesive).

FIG. 19 is a perspective view of the electronics assembly 320 of the underwater light 100 of the present disclosure. As mentioned above, the electronics assembly 320 may include a control board 320a and a network board 320b. The control board 320a may be configured to control a display of the underwater light 100 and the network board 320b may be configured to communicate with a wireless terminal (e.g., a remote control, tablet, laptop, etc.).

FIG. 20 is a perspective view of the cable attachment assembly 180 for providing a watertight connection between a power and/or communications cord and the underwater light 100 of the present disclosure. The cable attachment assembly 180 includes a PCB adapter 180a having apertures 340, a base connector 180b, a cap connector 180c, a plug nut 180d and a cord 180c which houses a power/and or communications cord (not shown). It is noted that the PCB adapter 180a could have a plurality of shapes. For example, the PCB adapter 180a could be a plurality of shapes, including but not limited to, triangular, circular, square and hexagonal.

Each of the apertures 340 of the PCB adapter 180a are configured to receive a terminal post (not shown) electrically coupled to the PCB 280 and the electronics assembly 320. For example, each terminal post could be soldered to one or more conductor traces of the PCB 280 and the electronics assembly 320. The terminal posts project through the base connector 180b. The threaded plug nut 180d is threaded onto a threaded aperture formed by a coupling of the base connector 180b and the cap connector 180c. The threaded plug nut 180d forms a watertight seal with the coupled base connector 180b and cap connector 180c via an O-ring or other scaling means. In addition, the threaded plug nut 180d receives, in watertight communication (e.g., by epoxy, gluing, etc.), the cord 180e which houses the power/and or communications cord. Each conductor of the power and/or communications cord is coupled to respective projections of the terminal posts, thereby completing electrical connection of the power and/or communications cord to the PCB 280 and electronics assembly 320. It is noted that the terminal posts and terminal post projections could be encapsulated with a potting compound.

FIG. 21 is an exploded view of the underwater light 100 of FIG. 13a showing assembly of the lens 120, the rear housing plate 400 and the rear housing 220. As mentioned above, the rear housing plate 400 includes a plurality of notches 400a and an annular projection 400b and can be positioned between the lens 120 and the rear housing 220. The plurality of notches 400a engage the rear housing 220 such that the rear housing plate 400 is in water tight communication with the rear housing 220. The annular projection 400b is received by the lens recess 120d formed by the lens annular wall 120b. In addition, the plurality of rear housing hooks 220a respectively engage the plurality of lens slots 120c to couple the lens 120 to the rear housing 220.

Advantageously, the electrically non-conductive nature of the exterior components of the underwater light 100 of the present disclosure permit the underwater light 100 to be installed in any location in a pool or spa without requiring specific approval of Underwriters Laboratories. Further, since the exterior of the underwater light 100 is electrically non-conductive, no specific bonding or grounding of the underwater light 100 is necessary. In addition, the rear housing 220 prevents contact with high voltage components of the underwater light 100 such as power supply components, line-level (AC) power, etc. In addition, the rear housing plate 400 and the optically transparent potting compound encapsulating the PCB 280 (not shown) and the LEDs 280a (not shown) and electronic components 280b (not shown) mounted thereon and the ability to remove the rear housing 220 of the underwater light 100, provide for the safe replacement of the PCB 280 mounted within the underwater light 100 when an LED 280a mounted thereon is inoperable.

FIG. 22 is a perspective view showing another embodiment of the underwater light 500 of the present disclosure. The underwater light 500 includes a lens 512 having a central portion 512a and a peripheral region including an annular wall 512b (see FIG. 28), a bezel 514 including a screw aperture 514a and a plurality of peripheral recesses 514b, and a cable attachment assembly 518. The term “lens,” as used herein, refers not only to an optical component which can focus light (as in a conventional lens), but also to components which are merely transparent and do not focus light, such as a transparent and/or translucent cover. The bezel 514 is received by and couples to a mounting flange 520 (see FIG. 23). The bezel 514 is positioned about the central lens portion 512a. The underwater light 500 can be positioned such that the aperture 514a can be rotated up to 360 degrees from the typical 12 o'clock position of existing underwater lights. This allows the lens 512 to be positioned to direct light in a preferred direction in a pool or spa, and to accommodate installation of the light 500 in niches having various orientations.

FIG. 23 is a side view showing the underwater light 500 of FIG. 22. As mentioned above, the bezel 514 is received by and couples to the mounting flange 520. A screw 506 may be received by the screw aperture 514a to couple the bezel 514 to the mounting flange 520. In addition, a rear housing 522 couples to a rear of the mounting flange 520. The lens 512 is received by and couples to the rear housing 522 such that the lens 512 is in watertight communication with the rear housing 522. The rear housing 522 includes a recessed portion configured to couple to the cable attachment assembly 518 to allow external power to be supplied to the electrical components of the underwater light 500 by way of a power cable (not shown) and/or control/communications cables (not shown) and to create a watertight seal with such components. A positioning assembly 510 provides for the vertical movement of the underwater light 500 within an underwater niche during installation of the underwater light 500 such that the underwater light 500 can be accommodated and installed in underwater niches of different sizes. This allows the underwater light 500 to be positioned in a preferred vertical orientation in a pool or spa underwater niche.

FIG. 24 is a rear view of the underwater light 500 of FIG. 22. As mentioned above, the underwater light 500 may include the positioning assembly 510, the cable attachment assembly 518, the mounting flange 520 and the rear housing 522.

FIG. 25 is an exploded view of the underwater light 500 of FIG. 22. As shown in FIG. 25, the underwater light 500 comprises a plurality of components including the bezel 514; the lens 512; an O-ring 508; a rear housing plate 526; a printed circuit board (PCB) 528; a PCB back plate 529; a heat sink 530; the rear housing 522; an electronics assembly 532; and the mounting flange 520. FIG. 26, is an exploded perspective view of the underwater light 500 of FIG. 22. The components are discussed in further detail below.

FIG. 27 is a perspective view of the bezel 514 of the underwater light 500 of the present disclosure. The bezel 514 includes the screw aperture 514a, the plurality of peripheral recesses 514b and an annular projection 514c. As discussed in further detail below, the annular projection 514c, positioned on an interior of the bezel 514, is received by the mounting flange central aperture 520c. In addition, the bezel 514 couples to the mounting flange 520 via a plurality of mounting flange fingers 520b which engage the plurality of peripheral recesses 514b positioned on the bezel 514.

The aperture 514a could be elongate in shape to receive the screw 506 (see FIG. 23) in various positions to accommodate niches or recesses of a pool or spa of various diameters, thus allowing the underwater light 500 to be installed in multiple locations and without requiring modification of the underwater light 500. Additionally, a plurality of round apertures could be provided, extending outwardly from the center of the underwater light 500 and toward the periphery of the underwater light 500 to accommodate multiple screw positions.

The bezel 514 could be sized and shaped so as to cover niches or recesses of pools or spas having different diameters, or it could be over sized so as to cover a plurality of different diameters. The bezel 514 could be constructed of a thermally conductive and electrically insulative polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the bezel 514 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 28 is a perspective view of the lens 512 of the underwater light 500 of the present disclosure. As mentioned above, the lens 512 includes a central lens portion 512a, an annular wall 512b, a plurality of tabs 512c and a recess 512d. The annular wall 512b and the lens portion 512 together define the recess 512d. As discussed in further detail below, the recess 512d receives a rear housing plate annular projection 526b. In addition, the plurality of tabs 512c are configured to engage a rear housing plurality of notches 522a such that the lens 512 is in water tight communication with the rear housing 522.

The lens 512 could be formed using a suitable manufacturing process (e.g., injection molding, compression molding, thermoforming, etc.). The lens 512 could be formed from any suitable, electrically-insulating material, such as glass or a polymeric material (e.g., plastic). Such a material could include, but is not limited to, amorphous transparent copolymer having a cyclic olefin copolymer copolymerized from norbornene and ethylene using a metallocene catalyst and possessing properties important in optical components such as lenses. For examples, TOPAS COC possess properties including, but not limited to, high transparency, low birefringence, high flowability for precision molding, high heat resistance and negligible water absorption. The lens 512 may also be formed from an unbreakable transparent plastic which allows for a light curing adhesive to be utilized for bonding the lens 512 to the rear housing 522.

The outer surface of the lens 512 may have a silicon dioxide (SiO₂) coating configured or layer to prevent the formation of condensation on an interior portion of the lens 512. The coating or layer may be deposited by chemical vapor deposition. Alternatively the coating or layer may be formed within the lens 512 or deposited on the interior portion of the lens 512. The coating or layer insulates the underwater light 500 and thereby prevents the formation of condensation caused by a difference between the temperature of the air within the underwater light 500 and the temperature of pool water around the underwater light 500.

FIG. 29 is a perspective view of a rear housing plate 526 of the underwater light 500 of FIG. 22. The rear housing plate 526 includes a plurality of notches 526a, an annular projection 526b and an internal lens 526c. The rear housing plate 526 can be positioned between the lens 512 and the rear housing 522. The internal lens 526 can be positioned between the lens 512 and the PCB 528 to direct or focus light generated by the LEDs 528a. The internal lens 526 could be a collimator lens for producing parallel beams of light from the light generated by the LEDs 528a, or other desired types of lenses. Also, the collimator lens could be used in conjunction with a spreader lens.

The annular projection 526b is received by the lens recess 512d formed by the lens annular wall 512b. The plurality of notches 526a engage the rear housing 522 such that the rear housing plate 526 is in water tight communication with the rear housing 522. In addition, the annular projection 526b could be bonded with the lens recess 512d through a light curing adhesive, or any other suitable adhesive, to provide a watertight seal for the underwater light 500. The positions of the annular projection 526b and the lens recess 512d could be reversed such that the annular projection 526b could be provided on the lens 512, and the recess 512d could be provided on the rear housing plate 526.

Also, it is noted that the annular projection 526b need not be provided to facilitate the coupling of the lens 512 to the rear housing plate 526. Indeed, the lens 512 and the rear housing plate 526 could be coupled to each other by way of corresponding flat annular surfaces which are coupled to each other by gluing, bonding, etc., to create a watertight seal. Further, a gasket or O-ring 508 could be used to create a watertight seal between the lens 512 and the rear housing plate 526. Still further, the lens 512 could be coupled to the rear housing plate 526 by way of a watertight threaded connection, i.e., the lens 512 could be threaded onto the rear housing plate 526 and vice versa. Also, the lens 512 could be coupled to the rear housing plate 526 by way of adhesives, sonic welding, spin welding, etc.

The rear housing plate 526 could be constructed of an electrically insulative and thermally conductive polymer material. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the rear housing plate 526 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 30 is an exploded perspective view of the printed circuit board (PCB) 528, the PCB back plate 529 and a heat sink 530 of the underwater light 500 of the present disclosure. The PCB 528 includes a plurality of light-emitting diodes (LEDs) 528a and an electrical component or a plurality of electrical components 528b. The heat sink 530 includes an inner surface 530a and a plurality of fins 300b and is positioned on a central inner surface of the rear housing 522. In addition to the LEDs 528a, the PCB 528 may include several electronic components 528b including, but not limited to, controllers, transistors, resistors, wiring harnesses, microprocessors, etc. The PCB 528 is affixed to the inner surface 530a of the heat sink 530 via the PCB back plate 529 such that the PCB 528 is enclosed by the internal lens 526c of the rear housing plate 526 and the heat sink 530. Various optical and/or dielectric components could be used within the underwater light 500 in addition the internal lens 526c to enhance lighting, and to promote added safety.

For example, the underwater light 500 could include a plurality of light culminators to respectively be in optical communication with the plurality of LEDs 528a. The light culminators collect light generated by the LEDs 528a to provide high intensity output. Also, optical light “pipes” could be used in place of the culminators, the pipes being made from a solid plastic or glass material and transmitting light from the LEDs 528a directly to an outer surface(s) of the underwater light 500 (e.g., to the lens 512).

It is noted the underwater light 500 could be utilized in horticultural applications. For example, the underwater light 500 could be utilized in underwater vertical farms to cultivate seaweed, rice, wasabi, water chestnut, etc. Accordingly, the respective colors of the LEDs 528a could be specified to target the wavelengths at which various chlorophyll pigments in plants absorb light to enable photosynthesis. For example, the LEDs 528a could be a variation of blue to target a wavelength spectrum of 400 nm to 500 nm and/or a variation of red to target a wavelength spectrum of 600 nm to 700 nm at which each of chlorophyll A and chlorophyll B absorb light. The LEDs 528a could also be a variation of white (e.g., magenta and light green) to provide for visual inspection of plant growth and/or harvest. In addition, the respective colors of the LEDs 528a could be modified according to the various stages of plant growth (seedlings, flowering, harvest, etc.) to promote an efficient plant growth cycle and a greater plant yield.

Also an optically transparent potting compound (e.g., formed from a thermally conductive and electrically insulative material) could be used to encapsulate the LEDs 528a, as well as the PCB 528 to which the LEDs 528a are mounted and portions of the culminators. The potting compound could encapsulate the LEDs 528a and the PCB 528 if the culminators are not provided. The potting compound protects the LEDs 528a and the PCB 528 from exposure to water in the event that the underwater light 10 is no longer watertight, thereby protecting against electrical shock and promoting safety. Also, the optically transparent potting compound encapsulating the PCB 528 and the LEDs 528a mounted thereon in addition to the ability to remove the rear housing 522 of the underwater light provide for the safe replacement of the PCB 528 mounted within the underwater light 500 when one of the LEDs 528a is inoperable.

The PCB 528 is affixed to the PCB back plate 529. The PCB back plate 529 is affixed to the inner surface 530a of the heat sink 530 such that the PCB 528 is enclosed by the internal lens 526c of the rear housing plate 526 and the heat sink 530. The PCB back plate 529 is a separate layer (or plate) of thermally conductive material positioned between the PCB 528 and the heat sink inner surface 530a. The PCB back plate 529 could be attached to the PCB 528 and the heat sink inner surface 530a using a thermally-conductive adhesive.

For example, the PCB backplate 529 could be bonded to the heat sink inner surface 530a by means of a thermally conductive material, such as a thermally-conductive grease, adhesive or potting compound. The thermally-conductive adhesive could include thermally-conductive, fiberglass-reinforced, pressure sensitive adhesive tape, or a thermally-conductive, filled polymer composite interface including an adhesive layer. The application of thermally conductive material allows for the PCB 528 to be in thermal communication with the heat sink 530 and subsequently the rear housing 522. This allows for the transfer of heat from the LEDs 528a and the electronic components 528b of the PCB 528, through the PCB backplate 529 and the thermally conductive material, to the heat sink 530 and the exterior of the rear housing 522.

The heat sink 530 includes an inner surface 530a and is positioned on a central inner surface of the rear housing 522. The heat sink 530 also includes a plurality of fins 530b located on the rear of the heat sink 530 to promote heat dissipation. The plurality of fins 530b may be rectangular or trapezoidal in shape, continuous or segmented, and/or arranged in a vertical, horizontal or intersecting pattern. The heat sink 530 is constructed of thermally conductive and electrically insulative material and is positioned on a central inner surface of the rear housing 522. Such a material could include, but is not limited to, electrically insulative and thermally conductive material (e.g., plastic). In addition, the heat sink 530 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. The presence of the heat sink 530 on the inner surface of the rear housing 522 allows for heat to be properly dissipated away from the PCB 528 thereby cooling the LEDs 528a and the electrical components 528b. The heat sink 530 could also be molded to the rear housing 522 during its fabrication or may be attached through a suitable means (e.g. at least one screw or an adhesive).

FIG. 31 is a perspective view of the rear housing 522 of the underwater light 500 of FIG. 22. The rear housing 522 includes a plurality of notches 522a. The heat sink 530 may be molded to the rear housing 522 during its fabrication or may be coupled to the rear housing 522 through a suitable means (e.g. at least one screw or an adhesive) such that the rear housing 522 is molded to receive the plurality of fins 530b of the heat sink 530. The rear housing 522 may be overmolded over the electronics assembly 532 including control electronics and network electronics. In addition, an optically transparent potting compound (e.g., formed from a thermally conductive and electrically insulative material) could be used to encapsulate the electronics assembly 532.

As mentioned above, the rear housing plate 526 includes a plurality of notches 526a and an annular projection 526b and can be positioned between the lens 512 and the rear housing 522. The plurality of notches 526a engage the rear housing 522 such that the rear housing plate 526 is in water tight communication with the rear housing 522. The annular projection 526b is received by the lens recess 512d formed by the lens annular wall 512b. In addition, the plurality of rear housing notches 522a respectively engage the plurality of lens tabs 512c to couple the lens 512 to the rear housing 522.

The rear housing 522 is constructed of a thermally conductive and electrically insulative polymer material. In addition, the rear housing 522 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide. It is noted that the entirety of the rear housing 522 need not be formed of a thermally-conductive polymeric material. Rather, only a desired portion of the rear housing wall could be formed from such material, in locations where significant amount of heat are generated. In such circumstances, the remainder of the rear housing 522 could be formed by a non-thermally-conductive polymeric material, and the thermally-conductive portion could be coupled to the non-thermally-conductive portion by way of insert molding, overmolding, sonic welding, adhesives, etc.

Advantageously, the electrically non-conductive nature of the exterior components of the underwater light 500 of the present disclosure permit the underwater light 500 to be installed in any location in a pool or spa without requiring specific approval of Underwriters Laboratories. Further, since the exterior of the underwater light 500 is electrically non-conductive, no specific bonding or grounding of the underwater light 500 is necessary. In addition, the rear housing 522 prevents contact with high voltage components of the underwater light 500 such as power supply components, line-level (AC) power, etc.

FIG. 32 is a perspective view of the electronics assembly 532 of the underwater light 500 of FIG. 22. As mentioned above, the electronics assembly 532 may include control and network electronics. The control electronics may be configured to control a display of the underwater light 500 and the network electronics may be configured to communicate with a wireless terminal (e.g., a remote control, tablet, laptop, etc.).

FIG. 33 is a perspective view of the mounting flange 520 of the underwater light 500 of FIG. 22. The mounting flange 520 includes at least one aperture 520a, a plurality of fingers 520b and a central aperture 520c. The central aperture 520c is configured to receive the bezel annular projection 514c. In addition, the plurality of fingers 520b are configured to respectively engage the plurality of bezel peripheral recesses 514b to couple the bezel 514 to the mounting flange 520.

The mounting flange 520 could be constructed of a thermally conductive and electrically insulative polymer material (e.g., plastic). In addition, the mounting flange 520 could also be constructed of a chemical resistant material including, but not limited to, urethane, thermoplastic elastomer (TPE) overmolding, silicone or polyamide.

FIG. 34 is an exploded perspective view of the underwater light 500 of FIG. 22, showing an assembly of the lens 512, the bezel 514, the mounting flange 520 and the rear housing 522. The rear housing plate annular projection 522a is received by the lens recess 512d formed by the lens annular wall 512b. The plurality of rear housing notches 522a respectively engage the plurality of lens tabs 512c to couple the lens 512 to the rear housing 522. The mounting flange central aperture 520c is configured to receive the bezel annular projection 514c. In addition, the plurality of mounting flange fings 520b are configured to respectively engage the plurality of bezel peripheral recesses 514b to couple the bezel 514 to the mounting flange 520. The bezel aperture 514a could be elongate in shape to receive the screw 506 (not shown) such that a projection of the screw 506 may be received by the mounting flange aperture 520a.

Advantageously, the electrically non-conductive nature of the exterior components of the underwater light 500 of the present disclosure (i.e., the lens 512, the bezel 514, the mounting flange 520 and the rear housing 522) permit the underwater light 500 to be installed in any location in a pool or spa without requiring specific approval of Underwriters Laboratories. Further, since the exterior of the underwater light 500 is electrically non-conductive, no specific bonding or grounding of the underwater light 500 is necessary. It is also noted the rear housing 522 prevents contact with high voltage components of the underwater light 500 such as power supply components, line-level (AC) power, etc. In addition, the optically transparent potting compound encapsulating the PCB 528 and the LEDs 528a and electronic components 528b mounted thereon and the ability to remove the coupled lens 512 and the rear housing 522 of the underwater light 500 provide for the safe replacement of the PCB 528 mounted within the underwater light 500 when an LED 528a mounted thereon is inoperable. Specifically, the assembly of the lens 512, the bezel 514, the mounting flange 520 and the rear housing 522 of the underwater light 500 allow for the coupled lens 512 and rear housing 522 to be removed from the front of the underwater light 500 after removal of the bezel 514.

FIG. 35 is a perspective view of the underwater light 500 of FIG. 22, showing assembly of the bezel, the coupled lens and rear housing and the mounting flange. As mentioned above, the assembly of the lens 512, the bezel 514, the mounting flange 520 and the rear housing 522 of the underwater light 500 allow for the coupled lens 512 and rear housing 522 to be removed from the front of the underwater light 500 after removal of the bezel 514. The bezel 514 may be keyed to facilitate the removal thereof from the assembled underwater light 500.

The rear housing plate annular projection 522a is received by the lens recess 512d formed by the lens annular wall 512b. The plurality of rear housing notches 522a respectively engage the plurality of lens tabs 512c to couple the lens 512 to the rear housing 522. The space between the lens 512 and the rear housing 522 is pressurized when the lens 512 is pressed onto the rear housing 522. Specifically, the O-ring 508, positioned along the periphery of the rear housing plate 526, seals the coupling between the lens 512 and the rear housing 522 such that the lens 512 and the rear housing 522 are in watertight communication. An optically transparent potting compound may encapsulate the PCB 528 and the LEDs 528a and electronic components 528b. Alternatively, silica packets may be positioned in the pressurized space between the lens 512 and the rear housing 522.

FIG. 36 is an exploded perspective view of the positioning assembly 510 of the underwater light 500 of FIG. 22. The positioning assembly 510 includes a connector 510a, a nut 510d, a screw 510c and a clip 510f. The connector 510a includes a circular aperture 510b that is configured to receive the coupled screw 510e and nut 510d. The connector 510 also includes rectangular apertures 510c configured to respectively receive the prongs 510g of the clip 510f. The clip 510f coupled to the connector 510a allows for the vertical movement of the underwater light 500 within an underwater niche. The connector 510a coupled to the screw 510c and nut 510d allows for fixing a position of the underwater light 500 within the underwater niche by tightening the screw 510c. As such, the positioning assembly 510 allows for the vertical movement of the underwater light 500 within an underwater niche during installation of the underwater light 500 such that the underwater light 500 can be accommodated and installed in underwater niches of different sizes. This allows the underwater light 500 to be positioned and fixed in a preferred vertical orientation in a pool or spa underwater niche. FIG. 37 is a cross sectional view illustrating the vertical movement provided by the positioning assembly 510.

FIG. 38 is a perspective view of the cable attachment assembly 518 of the underwater light 500 for providing a watertight connection between a power and/or communications cord and the underwater light 500 of the present disclosure. The cable attachment assembly 518 includes a PCB adapter 518a having apertures (not shown), a housing 518b, a plug nut 518c and a cord 518d which houses a power/and or communications cord (not shown). It is noted that the PCB adapter 518a could have a plurality of shapes. For example, the PCB adapter 518a could be a plurality of shapes, including but not limited to, triangular, circular, square and hexagonal.

FIG. 39 is an exploded perspective view of the cable attachment assembly 518 of FIG. 38. The cable attachment assembly 518 may include a PCB adapter 518a; a cap housing 518b; and plug nut 518c; a cord 518d; a base connector 518e; a cap connector 518f; terminals posts 518g and screw assembly 518h. Each aperture of the PCB adapter 518a is configured to receive a terminal post 518g electrically coupled to the PCB 528 and the electronics assembly 532. For example, each terminal post 518g could be soldered to one or more conductor traces of the PCB 528 and the electronics assembly 532. The terminal posts 518g project through the base connector 518c. The threaded plug nut 518c is threaded onto a threaded aperture formed by a coupling of the base connector 518e and the cap connector 518f. The coupled base connector 518c and the cap connector 518f are accommodated within the cap housing 518b. The threaded plug nut 518c forms a watertight seal with the coupled base connector 518e and the cap connector 518f via an O-ring or other sealing means. In addition, the threaded plug nut 518c receives, in watertight communication (e.g., by epoxy, gluing, etc.), the cord 518d which houses the power/and or communications cord. Each conductor of the power and/or communications cord is coupled to respective projections of the terminal posts 518g via the screw assembly 518h, thereby completing electrical connection of the power and/or communications cord to the PCB 528 and electronics assembly 532. It is noted that the terminal posts 518g could be encapsulated with a potting compound.

Having thus described the present disclosure in detail, it is to be understood that the foregoing description is not intended to limit the spirit or scope thereof.

	Number	Date	Country
Parent	17436514	Sep 2021	US
Child	18800524		US

Underwater Light Having a Replaceable Light-Emitting Diode (LED) Module and Cord Assembly

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RELATED APPLICATIONS

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