This invention relates to lighting systems and more particularly to adjustable, single-housing recessed lighting systems.
In order to meet fire and other regulatory codes, recessed lighting systems conventionally include a “can” containing a light source module for mounting into an opening in a ceiling or wall and a separate, insulated driver housing to contain a driver of the lighting system. A trim is generally assembled to the can through the opening in the ceiling or wall. However, because such systems require two separate housings (i.e. the can and the driver housing) they are typically large and lack adjustability. Thus, due to their size and lack of adjustability, installation locations for conventional recessed lighting systems are restricted to larger, more open portions of the ceiling or wall that afford sufficient space and accessibility. In addition, the size and complexity of such systems increases cost of both the hardware of the lighting system and the labor required to install it.
Provided herein are adjustable, single-housing recessed lighting systems for installation in a ceiling or wall.
In one aspect a recessed lighting system is provided. The recessed lighting system includes a housing having a closed rear face, an opposing open face, and a sidewall extending between the closed rear face and the opposing open face to define an interior cavity. The recessed lighting system also includes a light emitting module positioned inside the interior cavity of the housing. The light emitting module includes a heat sink. The light emitting module also includes a circuit board stacked on the heat sink. The light emitting module also includes a light source mounted at a center of the circuit board on a side of the circuit board opposite the heat sink. The light emitting module also includes driver circuitry mounted on a portion of the circuit board surrounding the light source, the driver circuitry configured for powering the light source. The light emitting module also includes a cover stacked on the circuit board including a channel sized and positioned to enclose the driver circuitry and defining an opening sized and positioned such that the light source is not covered by the cover. The recessed lighting system also includes a trim assembly installed in the housing through the open face. The trim assembly includes a reflector. The trim assembly also includes a trim having a light guide portion fastened to the reflector and a decorative trim extending radially outward from a base of the light guide portion. The trim assembly also includes a plurality of interface elements extending from an exterior surface of the reflector or an exterior surface of the light guide portion of the trim, the interface elements configured to exert a radial force on an interior surface of sidewall of the housing to retain the trim assembly in the housing.
In another aspect a recessed lighting system is provided. The recessed lighting system includes a housing assembly. The housing assembly includes a housing having a closed rear face, an opposing open face, and a sidewall extending between the closed rear face and the opposing open face to define an interior cavity. The housing assembly also includes first and second brackets engaged with opposing exterior sides of the housing, the first and second brackets each configured to selectively slide along a vertical axis of the housing to permit adjustment of a height of the brackets relative to the housing. The recessed lighting assembly also includes a light emitting module positioned inside the cavity of the housing. The recessed lighting assembly also includes a trim assembly installed in the housing through the open face. The trim assembly includes a reflector. The trim assembly also includes a trim fastened to the reflector. The recessed lighting assembly also includes a length-adjustable hanger bar for suspending the housing between two structural building elements, the length-adjustable hanger bar extending through first and second slots formed, respectively, in an end of each of the first and second brackets proximate the closed rear face of the housing, wherein a position of the housing can be adjusted laterally relative to an opening in a ceiling or wall by sliding the housing, through the slots, along the length-adjustable hanger bar, and wherein a position of the housing can be adjusted vertically relative to the opening in the ceiling or wall by adjusting a height of the brackets relative to the housing.
In another aspect, a lighting enclosure is provided. The lighting enclosure includes a fire-rated housing having a closed rear face, an opposing open face, and a sidewall extending between the closed rear face and the opposing open face to define an interior cavity. The lighting enclosure also includes a light emitting module installed in the fire-rated housing. The lighting enclosure also includes an aperture formed in the sidewall proximate the closed rear face, the aperture sized to permit exterior access to a portion of the interior cavity defined between the light emitting module and the closed rear face. The lighting enclosure also includes a door hingeably attached to the sidewall, the door sized and positioned to cover the aperture in a closed position of the door.
In some embodiments, the fire-rated housing is a junction box. In some embodiments the fire-rated housing is constructed of at least one of aluminum, steel, stainless steel, cast iron, a metallic alloy, plastic, PVC, fiberglass, or combinations thereof. In some embodiments, the lighting enclosure also includes a latch configured to selectively retain the door in a closed position of the door. In some embodiments, the latch is a rotatable element attached to the sidewall and positioned to rotate between a retention position wherein the latch covers a portion of the door in the closed position of the door and a release position wherein the latch does not cover the door in the closed position of the door.
In some embodiments, the light emitting module includes a heat sink. In some embodiments, the light emitting module also includes a circuit board stacked on the heat sink. In some embodiments, the light emitting module also includes a light source mounted at a center of the circuit board on a side of the circuit board opposite the heat sink. In some embodiments, the light emitting module also includes driver circuitry mounted on a portion of the circuit board surrounding the light source, the driver circuitry configured for powering the light source. In some embodiments, the light emitting module also includes a cover stacked on the circuit board including a channel sized and positioned to enclose the driver circuitry and defining an opening sized and positioned such that the light source is not covered by the cover.
In some embodiments, the lighting enclosure also includes a trim assembly installed in the fire-rated housing through the open face. In some embodiments, the trim assembly includes a reflector. In some embodiments, the trim assembly also includes a trim fastened to the reflector. In some embodiments, the trim assembly also includes a plurality of interface elements extending from an exterior surface of the reflector or an exterior surface of the light guide portion of the trim, the interface elements configured to exert a radial force on an interior surface of the housing to retain the trim assembly in the housing.
In another aspect, a light emitting module is provided. The light emitting module includes a heat sink. The light emitting module also includes a circuit board stacked on the heat sink. The light emitting module also includes a light source mounted at a center of the circuit board on a side of the circuit board opposite the heat sink. The light emitting module also includes driver circuitry mounted on a portion of the circuit board surrounding the light source, the driver circuitry configured for powering the light source. The light emitting module also includes a cover stacked on the circuit board including a channel sized and positioned to enclose the driver circuitry and defining an opening sized and positioned such that the light source is not covered by the cover.
In some embodiments, the light source includes at least one LED. In some embodiments, the heat sink includes at least one heat dissipating element formed thereon on a side of the heat sink opposite the circuit board. In some embodiments, the light emitting module also includes a housing having a closed rear face and an opposing open face and defining a cavity, wherein the heat sink, the circuit board, the light source, and the cover are positioned within the housing such that the light source faces the opposing open face. In some embodiments, the light emitting module also includes a trim assembly installed in the housing through the open end. In some embodiments the trim assembly includes a reflector. In some embodiments, the trim assembly also includes a trim fastened to the reflector. In some embodiments, the trim assembly also includes a plurality of interface elements extending from an exterior surface of the reflector or an exterior surface of the light guide portion of the trim, the interface elements configured to exert a radial force on an interior surface of the housing to retain the trim assembly in the housing.
In another aspect, a recessed lighting system is provided. The recessed lighting system includes a housing assembly. The housing assembly includes a fire-rated housing having a closed rear face, an opposing open face, and a sidewall extending between the closed rear face and the opposing open face to define an interior cavity. The housing assembly also includes an aperture formed in the sidewall proximate the closed rear face, the aperture sized to permit exterior access to a portion of the interior cavity defined between the light emitting module and the closed rear face. The housing assembly also includes a door hingeably attached to the sidewall, the door sized and positioned to cover the aperture in a closed position of the door. The housing assembly also includes first and second brackets engaged with opposing exterior sides of the housing, the first and second brackets each configured to selectively slide along a vertical axis of the housing to permit adjustment of a height of the brackets relative to the housing. The housing assembly also includes a light emitting module positioned inside the interior cavity of the housing. The light emitting module includes a heat sink. The light emitting module also includes a circuit board stacked on the heat sink. The light emitting module also includes a light source mounted at a center of the circuit board on a side of the circuit board opposite the heat sink. The light emitting module also includes driver circuitry mounted on a portion of the circuit board surrounding the light source, the driver circuitry configured for powering the light source. The light emitting module also includes a cover stacked on the circuit board including a channel sized and positioned to enclose the driver circuitry and defining an opening sized and positioned such that the light source is not covered by the cover. The recessed lighting system also includes a trim assembly installed in the housing through the open end. The trim assembly includes a reflector including at least one reflective surface positioned to direct light from the light source toward a lens. The trim assembly also includes the lens positioned between the reflector and a trim. The trim assembly also includes the trim. The trim includes a light guide portion extending from the lens through the open end of the housing to a base of the light guide portion. The trim also includes a decorative trim extending radially outward from the base of the light guide portion. The trim also includes a plurality of interface elements extending from an exterior surface of the reflector or an exterior surface of the light guide portion of the trim, the interface elements configured to exert a radial force on an interior surface of the housing to retain the trim assembly in the housing. The recessed lighting system also includes a length-adjustable hanger bar for suspending the housing between two structural building elements, the length-adjustable hanger bar extending through first and second slots formed, respectively, in an end of each of the first and second brackets proximate the closed rear face of the housing, wherein a position of the housing can be adjusted laterally relative to an opening in a ceiling or wall by sliding the housing, through the slots, along the length-adjustable hanger bar, and wherein a position of the housing can be adjusted vertically relative to the opening in the ceiling or wall by adjusting a height of the brackets relative to the housing.
Embodiments of the present disclosure will now be described, by way of example only, with reference to the attached Figures, wherein:
The disclosure and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments and examples that are described and/or illustrated in the accompanying drawings and detailed in the following description. It should be noted that the features illustrated in the drawings are not necessarily drawn to scale, and features of one embodiment may be employed with other embodiments, as the skilled artisan would recognize, even if not explicitly stated herein.
Descriptions of well-known components and processing techniques may be omitted to not unnecessarily obscure the embodiments of the disclosure. The examples used herein are intended merely to facilitate an understanding of ways in which the disclosure may be practiced and to further enable those of skill in the art to practice the embodiments of the disclosure. Accordingly, the examples and embodiments herein should not be construed as limiting the scope of the disclosure. Moreover, it is noted that like reference numerals represent similar parts throughout the several views of the drawings.
Provided herein are an adjustable, single-housing recessed lighting systems for use in connection with the installation of recessed lighting in both new construction and remodeling applications. Although shown and described herein as being installed in a ceiling, it will be apparent in view of this disclosure that the adjustable, single-housing recessed lighting systems provided herein can also be installed in walls and/or floors in connection with various embodiments.
Referring now to
The hanger bar 100 can include a first and second slideable elements 101a, 101b configured to slideably expand and contract the hanger bar 100 along a longitudinal axis thereof in order to fit within a space for mounting. In some embodiments, as best shown in
Still referring to
Referring now to
The housing 201 and vertical brackets 203 can be made of any suitable material according to a weight of the system 10 and any applicable electrical or fire rating requirements. Such materials can include metallic materials (e.g., aluminum, steel, including stainless steel, cast iron), non-metallic materials (e.g., plastic, PVC, fiberglass), or combinations thereof. For example, the housing 201 and vertical brackets 203 shown in
The housing 201 can be slideably assembled to the brackets 203 via bracket slots 206 and vertical slots 208 so as to be vertically repositionable (i.e. repositionable along an axis substantially perpendicular to the longitudinal axis of the hanger bar 100) relative to a ceiling C or wall and/or the hanger bar 100. The bracket slot 206 can generally protrude outward from the housing 201 perpendicular to a corresponding suspension slot 204 and be sized to permit the vertical bracket 203 to pass therethrough. The vertical slots 208 can be formed in the vertical brackets 203 as generally elongated holes. In order to provide a second retention point for each vertical bracket 203 on the housing 201 and to facilitate vertical repositioning of the housing 201 relative to the hanger bar 100 and the ceiling C or wall, a positioning screw 207a can extend through both the vertical slot 208 and the housing 201. As shown in
To achieve a desired height of the housing 201 relative to a wall or ceiling C, as shown, for example, in
The vertical adjustment discussed above is generally useful for achieving proper alignment between the housing 201 and the ceiling C or wall so that proper mating with the trim 400 (see
Referring now to
In use, the access door 211 can advantageously provide exterior access to the upper portion of the interior of the housing 201 even when the light emitting module 300 is pre-assembled into the housing 201 before being wired into mains. Importantly, the ability to pre-assemble the lighting module prior to wiring permits the lighting system 10 to be shipped from the manufacturer pre-assembled, reducing the number of separate parts to be shipped and assembled, thereby facilitating faster, less complex installation of the recessed lighting system 10 at the jobsite and reducing packaging required to ship the system 10, which, in turn, reduces the installed cost of the lighting system 10.
In some embodiments, the housing 201 and the access door 211 can form a fire-rated junction box. “Fire-rated”, as used herein, refers to a junction box or other housing 201 meeting or exceeding the fire resistance requirements of at least one industry, regulatory, statutory, or other standard associated with junction boxes. Such housings may include, for example, housings 201 capable of meeting UL514A, PH120, E30, E60, E90, or any other standard.
As shown in
As best shown in
In addition, to the extent that additional cooling or heat-transferring performance is desirable, the heat sink 301 can be configured to include one or more heat dissipating elements. Such heat dissipating elements can generally be formed on an opposite surface of the heat sink 301 from the stacked circuit board 303. The heat dissipating elements can take any desired form suitable for increasing the cooling performance of the heat sink. For example, in some embodiments, as shown in
Referring again to
The cover 305, can generally be constructed of a thermally and/or electrically insulating material such as, for example, glass, plastic, PVC, fiberglass, or any other suitable such material. The cover 305 can include a channel 306 extending around the cover 305 sized and shaped to enclose the electronic components 309 within the channel 306 of the cover 305 when the cover 305 is assembled into the light module. In this manner, the cover protects a user or installer from electrical shock from direct physical contact with the electrical components 309. In addition, the channel 306 of the cover 305 separates the LEDs 307 from the other electronic components 309. In this manner, the LEDs 307 are at least partially thermally insulated from the other electronic components 309 by the cover 305, thereby improving performance and increasing the useful life of the LEDs 307. Accordingly, the conventional need for a separate housing for the driver is obviated because the heat from the driver has less impact on the LEDs 307.
The cover 305 can also define an opening at a center portion thereof such that the LEDs 307 are not covered by the channel 306 or the cover 305. However, by not covering the LEDs 307, the risk of electrical shock from contact with the exposed LEDs 307 must be mitigated in order to meet the requirements of electrical and fire codes. The present invention avoids this challenge because the LEDs 307 are selected such that the light emitting portion of the LEDs 307 covers the live electrical connectors (solder pads) on which they are mounted. Those LEDs 307 are then concentrated at the center of the circuit board 303 closely together enough that the live connectors are substantially covered and shielded by the light emitting portions of the LEDs 307 themselves from contact by the user or installer.
This uncovered configuration advantageously increases the amount of light transmissible from the LEDs 307 into the space to be illuminated. In particular, in a conventional lighting system the entire circuit board, including LEDs, would need to be covered by the cover in order to prevent the risks of electric shock and fire. However, even transparent covers result in a loss of about 7% of the light passing therethrough. Therefore, an immediate 7% increase in the amount of light transmissible into the space to be lighted is achieved by configuring the light emitting module 300 as described herein to leave the LEDs 307 uncovered. This increase in transmissible light permits the lighting system 10 described herein to provide better illumination while consuming less power than a conventional recessed lighting system.
Referring now to
The reflector 401 can include a hollow, frustoconical (e.g., as shown in
In accordance with various embodiments, a frustum and a base of the reflector 401 can have any suitable shape including, for example, square, rectangular, hexagonal, octagonal, elliptical, or combinations thereof. In addition, it will be apparent in view of this disclosure that the shape of the frustum of the reflector 401 can, in some embodiments, match a cross-sectional shape of at least one of the housing 201, the heat sink 301, or the trim 405 or may be a different shape. In addition, it will be apparent in view of this disclosure that the frustum and the base of the reflector 401 may have a same shape or a different shape. The base of the reflector 401, in some embodiments, can include a base flange 402 to facilitate assembly to the lens 403 and the trim 405 (e.g., to frustum flange 404) as described in greater detail below.
The reflector 401 can be constructed of any suitable material including, for example, metallic materials (e.g., aluminum, steel, including stainless steel, cast iron, bronze, brass), non-metallic materials (e.g., plastic, PVC, fiberglass), or combinations thereof. An interior surface of the reflector 401 can generally be configured as a reflective surface 401a. The reflective surface 401a can be configured to reflect light. In some embodiments, the reflective surface 401a can be constructed from the same material as the reflector 401 more generally and polished or burnished to increase reflectivity (e.g., polished aluminum, steel, or stainless steel). In other embodiments, a reflective coating can be applied to the reflector 401 in order to render the reflective surface 401a more reflective. Such coatings can include any suitable reflective coating, including, for example, silver, Mylar®, aluminum foil, reflective paint, or combinations thereof.
The lens 403 can be any optical medium through which light emitted by the LEDs 307 can be transmitted. For example, the lens 403 can be constructed of any transparent or translucent material such as, for example, acrylic, polycarbonate, glass, other transparent or translucent materials, or combinations thereof. The lens 403 can also be clear, white, or any other desired color. The lens 403 can also be configured to shape and/or distribute the light emitted by the LEDs 307 and lighting system 10 more generally. Accordingly, the lens 403 can be, for example, flat, concave, convex, Fresnel, compound, or any other suitable shape. In addition, the lens 403, as used herein, can also include diffusers, prismatic lenses, and louvers. Furthermore, although uncommon, it will be apparent in view of this disclosure that some trim assemblies 400 may not include a lens 403, such that the light emitted from the LEDs 307 passes directly through the reflector 401 and the trim 405 into the space to be illuminated.
The trim 405 can be configured for decorative purposes in order to cover the opening in the ceiling in which the housing 201 is suspended. The trim 405 can generally be a single piece including a light guide 405a and a decorative trim 405b. The trim 405 can be constructed of any suitable material including, for example, metallic materials (e.g., aluminum, steel, including stainless steel, cast iron, bronze, brass), non-metallic materials (e.g., plastic, PVC, fiberglass), or combinations thereof. In accordance with various embodiments, the trim 405 can be constructed of same and/or different materials than the reflector 401 and lens 403.
The light guide 405a can preferably be constructed as an extension of the reflector 401 in that it can be at least partially inserted into the housing 201 and can include a hollow, frustoconical (e.g., as shown in
An interior surface of the light guide 405a, in some embodiments, can be configured as a reflective surface and/or a non-reflective decorative surface. Where the interior surface is reflective, it can be configured to reflect light and, similar to the reflective surface 401a of the reflector 401, the interior surface of the light guide 405a can be constructed from the same material as trim more generally and polished or burnished to increase reflectivity (e.g., polished aluminum, steel, or stainless steel). In other embodiments, a reflective coating can be applied to the interior surface of the light guide 405a in order increase reflectivity. Such coatings can include any suitable reflective coating, including, for example, silver, Mylar®, aluminum foil, reflective paint, or combinations thereof.
Where the interior surface of the light guide 405a is non-reflective, the interior surface can be any suitable color, tone, or texture as desired for decorative purposes. In some embodiments, the color, tone, and texture can match a color, tone, or texture or the decorative trim 405b or can be different than the color, tone, or texture of the decorative trim 405b. In that regard, in various embodiments the interior surface of the light guide 405a can include bare material, polished material, burnished material, painted, powder coated, oiled (e.g., as in oil rubbed bronze), painted (e.g., as in antique bronze, brass, or copper), textured, or any other feature affecting a color, tone, or texture of the interior surface of the light guide.
The decorative trim 405b can extend radially outward from the base of the light guide 405a, substantially parallel to the ceiling C or wall in order to cover/hide the opening in the ceiling C or wall in which the housing 201 is suspended. The decorative trim 405b can extend to any diameter, in any desired decorative shape although, as noted above, preferably, the diameter and shape of the decorative trim 405b are sufficient to cover/hide the opening in the ceiling C or wall in which the housing 201 is suspended. Consistent with the decorative nature of the decorative trim 405b, in various embodiments the interior surface of the light guide 405a can be any material tone, texture, or color, including, for example, bare material, polished material, burnished material, painted, powder coated, oiled (e.g., as in oil rubbed bronze), painted (e.g., as in antique bronze, brass, or copper), textured, or any other feature affecting a color, tone, or texture of the interior surface of the light guide.
In some embodiments, the decorative trim 405b can also include a lip 406 extending substantially perpendicular to an outer edge of the decorative trim 405b toward the ceiling C or wall. The lip 406 can be configured to contact the ceiling C or wall, thereby creating an impression to a viewer inside the space to be illuminated of a visually appealing, substantially gap-free interface between the decorative trim 405b and the ceiling C or wall while maintaining a space between the ceiling C or wall and the decorative trim 405b. The spacing created by the lip 406 advantageously prevents unsightly gaps between the decorative trim 405b and the ceiling C or wall. In particular, for example, where the housing 201 may be installed imperfectly such that it protrudes slightly below the ceiling C or wall and into the space to be illuminated, the spacing created by the lip 406 accommodates the protruding housing 201 without creating gaps in the fit between the ceiling C or wall. Conversely, were the decorative trim 405b designed to achieve a flush fit with the ceiling C or wall and the housing 201 protruded below the ceiling C or wall, the protruding housing 201 would create a gap between the decorative trim 405b and the ceiling C or wall.
The trim assembly 400 can be assembled, in some embodiments, by sandwiching an outer perimeter of the lens 403 between at least a portion of the base flange 402 of the reflector 401 and at least a portion of the frustum flange 404 of the light guide 405a portion of the trim 405. The base flange 402, frustum flange 404, and lens 403 can be removably or permanently fastened together by any suitable means including, for example, bolting, clamping, taping, gluing or other adhesive bonding, welding, combinations thereof.
The trim assembly 400 can also include a plurality of interface elements 407. Interface elements 407 can be mounted on an exterior surface of the light guide 405a portion of the trim 405 and/or an exterior surface of the reflector 401. The interface elements 407, as shown in
Referring now to
In some embodiments (e.g., where the lighting system 10 is being used for a remodel, rather than new construction) it is desirable to install a new lighting system 10 in a pre-existing opening in the ceiling or wall. However, in such applications, access to structural elements such as studs or joists may not be available, thus eliminating the option of using a hanger bar 100. Referring now to
While the foregoing description of the invention enables one of ordinary skill to make and use what is considered presently to be the best mode thereof, those of ordinary skill will understand and appreciate the existence of variations, combinations, and equivalents of the specific embodiments and examples herein. The above-described embodiments of the present invention are intended to be examples only. Alterations, modifications and variations may be effected to the particular embodiments by those of skill in the art without departing from the scope of the invention, which is defined solely by the claims appended hereto. The invention is therefore not limited by the above described embodiments and examples.
The present application claims the priority of U.S. Provisional Application No. 63/263,146 filed Oct. 27, 2021, the disclosure of which is incorporated herein by reference.
Number | Date | Country | |
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63263146 | Oct 2021 | US |