A lighting fixture is a ubiquitous device that provides artificial lighting in various indoor and outdoor settings. Conventional lighting fixtures reliant on incandescent or compact fluorescent lamp (CFL) lighting have typically used replaceable bulbs where the bulb contains the components to receive an electrical input and to emit light. More recently, light emitting diode (LED)-based lighting fixtures have utilized lighting modules that contain LEDs and corresponding driver electronics to manage and control electrical inputs received by the lighting fixture. The lighting module, which in some implementations may be in the form of a bulb, provides users a convenient form to install and/or replace light emitting components in a lighting fixture.
The Inventors, via previous innovative designs for lighting modules, have recognized and appreciated lighting modules with a light source, a driver, and a standardized connector packaged into a single device generally simplifies the installation of the lighting module into a lighting fixture. However, the Inventors have also recognized the integration of these various components and the resultant size and/or shape of the packaging may prevent conventional lighting modules from being installed into ceiling, wall, and/or floor spaces with limited interior space.
In particular, multi-family housing and commercial spaces often include limited ceiling and/or wall space separating different floors and/or rooms. For example, the distance between adjoining floors and/or rooms may be less than 4 inches, which may preclude the installation of some conventional lighting modules especially if the lighting module is installed as part of a recessed lighting fixture. The amount of space available within a ceiling and/or wall space for the lighting module may be further reduced by the presence of other structures and/or materials disposed within the ceiling and/or wall. For example, the ceiling and/or wall space typically contains wiring, thermal insulation, sound insulation, and building support structures (e.g., wood/metal joists, t-bars).
In some jurisdictions, a separate enclosure (e.g., a junction box, a luminaire housing) may also be required to physically separate the lighting module from the other structures and materials disposed within the ceiling and/or wall space. The shape and/or dimensions of the enclosure may be constrained by the limited space in the ceiling and/or wall. For example, an enclosure may have a depth of about 2.25 inches and a characteristic width of about 4 inches. The enclosure may also house one or more wires/cables together with the lighting module to supply and/or receive electrical power to and/or from the lighting module. In some implementations, the lighting module may also include wires/cables providing a dimmer signal (e.g., a 0-10V signal). The combination of the enclosure and the wiring may further limit the space available for the lighting module.
In recognizing the limitations of conventional lighting modules, the Inventors have further recognized several challenges associated with miniaturizing a lighting module that retains a light source, a driver, and a standardized connector within a single package. First, the lighting module should provide sufficient space to house and package various components including, but not limited to the light source, the driver, an optical element (e.g., a reflector, an optical lens), a ground connection, and/or an electrically insulating enclosure to insulate the driver while maintaining a sufficiently small envelope so that the lighting module may fit within the limited space of the ceiling/wall space and/or the enclosure.
Second, the limited interior space of the ceiling and/or wall space within which the lighting module is deployed may appreciably hinder the dissipation of heat generated by the light source and/or the driver. Specifically, the small amount of air surrounding the lighting module may be heated more rapidly and to higher temperatures, thus limiting the extent the lighting module is cooled by the air within the ceiling and/or wall space. The limited heat dissipation may be further exacerbated if the lighting module is inserted into an enclosure due, in part, to the further reductions to the amount of air surrounding the lighting module and the possibility that enclosure may be formed of a thermally insulating material.
In view of the foregoing, the present disclosure is directed to various inventive implementations of a lighting module with a light source, a driver, and a standardized connector assembled in a sufficiently small package to enable installation into a limited enclosed space (e.g., a ceiling, wall, or floor space, an enclosure). The lighting module may include a heat sink that houses various components of the lighting module. The heat sink may include a partition that defines, in part, two cavities. The lighting module may include a light source and an optical element (e.g., a reflector, an optical lens) disposed within one cavity. The lighting module may further include a retaining ring to cover and enclose the cavity containing the light source. The lighting module may further include a driver, which supplies electrical power to the light source, disposed in the other cavity. In this manner, the partition may provide a barrier that physically separates the light source and the driver, which may reduce the risk of electrical shock (e.g., when a user is accessing the first cavity to replace the optical element and/or the light source).
In some implementations, the lighting module may further include a driver enclosure to contain the driver, thus providing an electrically insulating barrier separating the driver from other electrically conducting materials in the lighting module (e.g., the heat sink). In some implementations, the lighting module may include an electrical connector electrically coupled to the driver via one or more wires where the electrical connector extends out from the heat sink to connect to an external power source. In some implementations, an electrical connector may be directly integrated into the driver enclosure to remove any dangling wires extending from the lighting module. In some implementations, a ground cable may be disposed in one or both of the cavities to electrically ground the heat sink, a trim coupled to the heat sink, and/or the driver to an external ground. In some implementations, the lighting module may further include a selectable switch electrically coupled to the driver to enable user to adjust a power level, lumen output, and/or a color temperature of the light emitted by the light source. The switch may be supported by the driver enclosure. In some implementations, the lighting module may also include a trim used, in part, to cover the exposed edges of an opening in a ceiling, wall, or floor and/or an enclosure.
In one aspect, the lighting module may be configured to fit into a space having a width as small as 2.4 inches, a height less than 2.25 inches, and/or a volume as small as 18 cubic inches. This may be achieved, in part, by reducing the exterior dimensions of the lighting module. In some implementations, the exterior dimensions of the lighting module may be determined primarily by the heat sink. The heat sink may have an exterior width less than about 3 inches and/or an exterior height less than about 1.6 inches. The heat sink may further include one or more keyed features that reduces the width of at least part of the heat sink such that the heat sink is able to fit into a space having a width less than 2.4 inches. It should be appreciated that the lighting module described herein may be installed into larger spaces as well. For example, different-sized trims may be coupled to the lighting module with attachment mechanisms (e.g., a metal clip) arranged to facilitate installation to a particular-sized enclosure. In another example, the trim may include attachment mechanisms (e.g., a spring clip) to facilitate installation of the lighting module directly onto a ceiling or wall space without the use of an enclosure.
Generally, the lighting module may be installed into a ceiling, wall, or floor space or an enclosure disposed within the ceiling, wall, or floor space. In some implementations, the enclosure may be a 3/0 or 4/0 standard electrical junction box or a 4-10 inch recessed lighting fixture. In implementations where the lighting module is inserted into an enclosure, the enclosure may include one or more tabs and/or posts disposed within a cavity of the enclosure. The tabs and/or posts may provide at least one opening. The lighting module and, in particular, the heat sink may include corresponding opening(s) (e.g., a hole or a slot on a flange of the heat sink) that align with the opening(s) of the enclosure. A fastener may thus be inserted through the respective openings of the lighting module and the enclosure to attach the lighting module to the enclosure.
Due to the dimensional constraints imposed on the overall size of the lighting module, the lighting module and, in particular, the heat sink may include a sidewall with the one or more keyed features to provide sufficient clearance for the lighting module to be inserted into the enclosure without being obstructed by the one or more tabs and/or posts. For example, the enclosure may include a pair of posts and the heat sink may include two curved portions as the keyed features. The curved portions may be disposed diametrically opposite with respect to one another along the sidewall and extend into one or both cavities of the heat sink in order to provide a groove that allows the heat sink to be inserted between the pair of posts. The keyed features may be disposed near the opening(s) of the heat sink used to couple the lighting module to the enclosure. In some implementations, the pair of posts may be separated by a distance of about 2.4 inches.
In another aspect, the heat sink may include a flange that provides an interface to attach the trim to the heat sink. Specifically, the flange may include one or more receptacles that may each receive a connector on the trim. In some implementations, the receptacles may be disposed along an annular portion of the flange such that the receptacles do not intersect an outer edge or outer periphery of the flange. The receptacles, however, may be disposed along an inner edge of the annular portion of the flange. In some implementations, the receptacles may be shaped to form either a snap-fit connection or a twist-and-lock connection with the connectors of the trim. In some implementations, the connectors of the trim may each be a metal clip that is coupled to a base section of a main body of the trim using, for example, a fastener. The metal clip may include a first connecting end that is insertable into the receptacles of the heat sink to facilitate attachment of the trim to the heat sink. The metal clip may also include a second connecting end to couple the trim to a surface of an enclosure (e.g., the second connecting end functions as a friction clip).
In some implementations, the heat generated by the light source and/or the driver may be dissipated to the ambient environment primarily via the trim. In particular, the heat generated by the light source and/or the driver may be transferred to the partition and/or the sidewall of the heat sink where the heat may then conduct towards the flange. The annular portion of the flange may physically contact the base section of the trim, thus enabling the heat to transfer directly to the trim via heat conduction. Once the heat is transferred to the trim, the heat may be dissipated to the ambient environment via convection. In some implementations, the annular portion of the flange and the base section may be shaped and/or dimensioned to provide a sufficiently large contact area to transfer heat so that the light source may maintain a temperature below 125° C. The receptacle(s) and the connector(s) may also be shaped such that the heat sink and the trim are pressed against one another when the connector is secured to the receptacle. In some implementations, the contact between the heat sink and the trim may be sufficient such that the temperature drop from the heat sink to the trim is less than or equal to 20° C. to provide sufficient heat flow from the heat sink to the trim and from the trim to the ambient environment (e.g., air). The contact force may reduce the thermal contact resistance between the annular portion of the flange and the base section of the trim, thus increasing the rate of heat transfer from the heat sink to the trim. The trim and the heat sink may also be formed of a thermally conductive material, such as aluminum to further improve cooling of the lighting module.
It should be appreciated, however, that in other implementations the heat generated by the light source and/or the driver may be partially dissipated from the sidewall of the heatsink and into the surrounding air within the enclosure and/or the ceiling or wall space. For example, the lighting module may be installed into a sufficiently large enclosure and/or a sufficiently large ceiling or wall space such that cooling of the lighting module may be achieved via heat conduction to the trim and convection or thermal radiation from the heat sink to the surrounding space within the enclosure and/or the ceiling or wall space.
In some implementations, the contact between the heat sink and the trim may also electrically ground the trim to the heat sink. For example, the heat sink and the trim may each be formed of an electrically conductive material (e.g., aluminum). A portion of the receptacle (e.g., a ledge forming part of a snap-fit connection or twist-and-lock connection with the connector of the trim) may expose the electrically conductive material. This portion of the receptacle may physically contact the connector of the trim (e.g., a metal clip), thus forming an electrical connection that grounds the trim to the heat sink. In some implementations, the heat sink may be painted (e.g., with a black paint) and/or coated (e.g., anodized) with the exception of the portion of the receptacle that contacts the connector of the trim as described above.
In another aspect, the driver enclosure, which may generally be formed of an electrically insulating material, may be implemented in several way to electrically insulate the driver. In one example, the driver enclosure may include a driver cover with a base and a sidewall defining a cavity to contain the driver. The driver cover may be oriented such that the cavity containing the driver and the driver enclosure is substantially covered and enclosed. The driver may be disposed within the cavity of the driver cover and suspended near the partition of the heat sink without physically contacting the partition. In some implementations, an electrically insulating film may be placed onto the partition to separate the driver from the heat sink. In some implementations, the cavity of the driver cover may be filled with a potting compound that encapsulates the driver.
In another example, the driver enclosure may include a driver housing with a base and a sidewall defining the cavity of the driver enclosure. The base of the driver housing may rest on the partition of the heat sink. In this example, the driver cover may be shaped as a lid to cover and enclose the driver housing. Thus, the driver cover and the driver housing may form a substantially enclosed cavity to contain the driver. In some implementations, the driver cover and the driver housing may be assembled using tool-less coupling mechanisms (e.g., snap-fit connectors). However, it should be appreciated that in other implementations the driver cover and the driver housing may be assembled using other coupling mechanisms that involve use of a tool, such as a screw fastener or a bolt fastener. In yet another example, the driver enclosure may include two driver casings that each form part of the cavity of the driver enclosure. The driver casings may each have a sidewall that contacts one another along a parting line. Once assembled, the driver casings may form a substantially enclosed cavity to contain the driver.
As described above, the lighting module may also include an electrical connector that is integrated into the driver enclosure. In some implementations, the driver enclosure may be configured to electrically isolate the driver and the electrical connector such that the lighting module may safely operate without a separate ground connection. The exclusion of a ground cable may simplify the installation of the lighting module. With this arrangement, the driver may also be qualified as a class II power unit according to, for example, the standards set forth by the International Electrotechnical Commission (IEC).
In some implementations, the driver enclosure may also be shaped to substantially fill one of the cavities of the heat sink. For example, the driver enclosure may also include keyed features that align and conform with respective keyed features on the heat sink as described above. In some implementations, the driver enclosure may be fully disposed within the cavity of the heat sink such that no portion of the driver enclosure extends out from the envelope of the heat sink. For example, a top side of the driver enclosure may be substantially flush with the an opening of the cavity.
In another aspect, the lighting module described herein may also be “universal” where the lighting module is deployable in different types of lighting fixtures (e.g., in terms of one or more of form factor, size, electrical connection requirements) for different lighting applications. Said in another way, the lighting module may be interchangeable between lighting fixtures of different types and/or sizes to facilitate easy installation and replacement by those who are not experienced electrical contractors or lighting designers (e.g., homeowners, do-it-yourself enthusiasts, etc.). In this manner, a single type of lighting module may be used in different lighting fixtures across different built environments, thus simplifying installation and maintenance.
The lighting modules described herein may have a sufficiently compact form factor that enables the lighting module to fit into various types of lighting fixtures or other enclosures for the lighting module; examples of such containers/enclosures or lighting fixtures include, but not limited to, various types of electrical junction boxes, a recessed lighting fixture (e.g., a “can” housing of a recessed lighting fixture, a down light fixture), a wall sconce lighting fixture, under cabinet lighting, a cylinder light fixture, a surface mount lighting fixture, a pendant lighting fixture, a floodlight fixture, an outdoor lighting fixture (e.g., a tree lighting fixture, a step lighting fixture, a ground or pathway lighting fixture, a garden lighting fixture, a landscape lighting fixture), and a security lighting fixture.
In one exemplary implementation, a lighting module includes a heat sink with a sidewall defining a first cavity with an open end and a flange coupled to the sidewall and disposed along the open end of the first cavity having an annular portion with an outer edge and one or more receptacles, disposed on the annular portion without intersecting the outer edge, to receive one or more connectors of a trim when the trim is coupled to the heat sink. The lighting module further includes a driver, coupled to the heat sink, to receive an electrical power input from an external power source and to supply an electrical power output and a light source, disposed within the first cavity, to emit light based on the electrical power output.
In another exemplary implementation, a lighting module includes a heat sink comprising a rear end face, a sidewall coupled to the rear face and defining an interior cavity where the sidewall has at least one exterior width dimension such that at least a portion of the sidewall proximate to the rear face fits into a space having a width of less than 2.4 inches, a front end face that surrounds an aperture of the interior cavity and at least one connecting mechanism to couple a trim to the front end face of the heat sink. The lighting module further includes a light source positioned inside the interior cavity of the heat sink and including at least one light emitting diode (LED) and a driver, positioned inside the interior cavity of the heat sink, to receive electrical energy and supply regulated electrical energy to power the light source.
In another exemplary implementation, a lighting module includes a heat sink having a rear end face, a sidewall, and a front end face, the sidewall having at least one exterior width dimension such that at least a portion of the sidewall fits into a space having a width of less than 2.4 inches. The lighting module further includes a light source inside the heat sink, a driver, inserted through the rear end face of the heat sink, to power the light source where the driver is insulated from the heat sink and coupled to the heat sink using a connecting mechanism, one of a reflector or optical lens inside the heat sink to direct light produced by the light source out of the heat sink and into an area surrounding the lighting module, a retaining ring having a flat portion with a front surface, wherein at least a portion of the front surface of the retaining ring is substantially coplanar with an exterior surface of the front end face of the heat sink, and at least one connecting mechanism to couple a trim to the front end face of the heat sink.
In another exemplary implementation, a lighting module includes a heat sink comprising a sidewall and a partition coupled to the sidewall where the sidewall and the partition together define a first cavity and a second cavity. The lighting module further includes a driver enclosure coupled to the heat sink so as to substantially enclose the first cavity where the driver enclosure is formed of an electrically insulating material, a driver, disposed within the first cavity, to receive an electrical power input from an external power source and to supply an electrical power output, a light source, disposed in the second cavity, to emit light based on the electrical power output, and a switch, at least partially disposed in the first cavity and electrically coupled to the driver, to adjust a power output of the light emitted by the light source.
In another exemplary implementation, a lighting module includes a heat sink comprising a sidewall (1130) defining a first cavity with an open end and a flange coupled to the sidewall and disposed along the open end of the first cavity. The lighting module further includes a light source, disposed within the first cavity, to emit light and a trim, directly coupled to the flange of the heat sink, to cover an opening of a ceiling or wall space when the lighting module is installed into the ceiling or wall space. The heat sink and the trim are each formed of an electrically and thermally conductive material, the heat sink is thermally coupled to the trim such that heat generated by the light source is dissipated primarily to the trim through the flange of the heat sink, and the trim is electrically grounded to the heat sink.
In another exemplary implementation, a lighting module includes a heat sink comprising a sidewall, a partition coupled to the sidewall where the sidewall and the partition together define a first cavity and a second cavity, and a flange coupled to the sidewall and disposed along an open end of the first cavity, having a flat portion with an outer edge and one or more receptacles, disposed on the flat portion without intersecting the outer edge, to receive corresponding connectors of a trim when the trim is coupled to the heat sink where the one or more receptacles form a portion of at least one of a snap-fit connector or a twist-and-lock connector. The lighting module further includes a driver enclosure, fully disposed within the first cavity, defining a substantially enclosed driver cavity where the driver enclosure is formed of an electrically insulating material. The driver enclosure comprises a driver cover having a driver sidewall separating the driver cavity from the sidewall of the heat sink and a driver base covering the first cavity of the heat sink and the driver cavity and an insulating film, disposed on the partition of the heat sink and abutting the driver sidewall, to separate the driver cavity from the partition of the heat sink. The lighting module further includes a driver, disposed within the driver cavity, to receive an electrical power input and to supply an electrical power output, a light source, disposed in the second cavity and electrically coupled to the driver, to emit light based on the electrical power output, and at least one switch, at least partially disposed in the first cavity and electrically coupled to the driver, to adjust one of a power output, a lumen output, or a color temperature of the light emitted by the light source.
It should be appreciated that all combinations of the foregoing concepts and additional concepts discussed in greater detail below (provided such concepts are not mutually inconsistent) are contemplated as being part of the inventive subject matter disclosed herein. In particular, all combinations of claimed subject matter appearing at the end of this disclosure are contemplated as being part of the inventive subject matter disclosed herein. It should also be appreciated that terminology explicitly employed herein that also may appear in any disclosure incorporated by reference should be accorded a meaning most consistent with the particular concepts disclosed herein.
The skilled artisan will understand that the drawings primarily are for illustrative purposes and are not intended to limit the scope of the inventive subject matter described herein. The drawings are not necessarily to scale; in some instances, various aspects of the inventive subject matter disclosed herein may be shown exaggerated or enlarged in the drawings to facilitate an understanding of different features. In the drawings, like reference characters generally refer to like features (e.g., functionally similar and/or structurally similar elements).
Following below are more detailed descriptions of various concepts related to, and implementations of, lighting modules with compact dimensions to facilitate installation into ceiling, wall, or floor spaces and/or enclosures with limited interior space and exemplary lighting fixtures incorporating one or more lighting modules. It should be appreciated that various concepts introduced above and discussed in greater detail below may be implemented in multiple ways. Examples of specific implementations and applications are provided primarily for illustrative purposes so as to enable those skilled in the art to practice the implementations and alternatives apparent to those skilled in the art.
The figures and example implementations described below are not meant to limit the scope of the present implementations to a single embodiment. Other implementations are possible by way of interchange of some or all of the described or illustrated elements. Moreover, where certain elements of the disclosed example implementations may be partially or fully implemented using known components, in some instances only those portions of such known components that are necessary for an understanding of the present implementations are described, and detailed descriptions of other portions of such known components are omitted so as not to obscure the present implementations.
In the discussion below, various examples of inventive lighting modules are provided, wherein a given example or set of examples showcases one or more particular features of a heat sink, a driver enclosure, a light source, a driver, an optical element (e.g., a reflector, an optical lens), a retaining ring, a trim. It should be appreciated that one or more features discussed in connection with a given example of a driver enclosure, a heat sink, a light source, a reflector, an optic, and a retaining ring may be employed in other examples of lighting modules according to the present disclosure, such that the various features disclosed herein may be readily combined in a given lighting module according to the present disclosure (provided that respective features are not mutually inconsistent).
A Lighting Module with an Integrated Connector and a Reflector
The lighting module 1000a may be compact in size to facilitate installation into lighting systems of various types and sizes. For example, the overall width of the lighting module 1000a (e.g., the outer diameter w of the heat sink 1100a) may be less than about 3 inches. The overall height of the lighting module 1000a (e.g., the height h of the heat sink 1100a) may be less than about 1.6 inches. In some implementations, the lighting module 1000a may fit into a space having a height dimension less than about 2.25 inches and a width dimension of about 4 inches. The enclosure may further include one or more posts within a cavity separated by a distance of about 2.4 inches (see, for example, the enclosure 2100b of
As shown in
The driver 1202 may include electronic circuitry to convert an electrical input from an external power source (e.g., an AC power supply in a building) into a desired form (e.g., a DC current) with a desired voltage and/or current to power the light source 1300. The driver 1202 may receive AC and/or DC currents to enable deployment of the lighting module 1000a in indoor and/or outdoor settings, respectively. For example, the lighting module 1000a may be used in an indoor lighting system (e.g., a recessed light, a cylinder light, a downlight), which typically uses AC current. In another example, the lighting module 1000a may be used in an outdoor lighting system (e.g., a landscape light, a flood light, an in-ground light), which typically uses DC current. Additionally, the driver 1202 may also be compatible with a range of operating voltages including, but not limited to low operating voltages (e.g., voltages less than 50V) and high operating voltages (e.g., voltages greater than 50V). The broad range of operating voltages supported by the driver 1202 may enable deployment of the lighting module 1000a in low voltage lighting systems (e.g., household lighting, landscape lighting, office lighting, and/or hospitality lighting using a 12V input) and/or high voltage lighting systems (e.g., security lighting, public lighting using a 120V line voltage input).
In some implementations, the driver 1202 may output DC current at voltages ranging between about 0V to about 10V. The light module 1000a may also generally support different arrangements of circuitry so long as the circuitry fits within the size constraints (e.g., the diameter, the height) imposed by the driver housing 1230 and/or the heat sink 1100. Various types of driver circuitry 1210 may be incorporated including, but not limited to a triode for alternating current (TRIAC) type driver, a digital addressable lighting interface (DALI) type driver, and a pulse width modulated (PWM) type driver.
The driver 1202 may also provide other functions for the lighting module 1000a including, but not limited to dimming the light source 1300 to control the light intensity, tuning the color of the light (e.g., changing a color temperature, switching between different preset colors of the light), and providing wireless communications (e.g., communicating with a remote device that controls the various settings of the lighting module 1000a).
The light source 1300 may be various types of electro-optical devices including, but not limited to, a light emitting diode (LED), an organic light emitting diode (OLED), and a polymer light emitting diode (PLED). In some implementations, the light source 160 may include one or more light emitting elements, e.g. multiple LEDs, OLEDs, or PLEDs, to increase light output and/or to alter the spectral characteristics of light emitted into the surrounding environment. For example, the light source 1300 may include LEDs with different wavelengths spanning the visible spectrum. The color of the light outputted by the lighting module 1000a may be tuned to have different color temperatures (e.g., white, yellow, orange).
The driver enclosure 1200a may be formed of an electrically insulating material to electrically isolate both the driver 1202 and the electrical connector 1210 from electrically conductive components, such as the heat sink 1100a. The electrical isolation of both the driver 1202 and the electrical connector 1210 enables the installation and operation of the lighting module 1000a without a separate ground wire.
The driver housing 1250a may also include a support structure 1254 and the driver cover 1230a may also include a tab 1232. The support structure 1254 and the tab 1232 together mechanically support the electrical connector 1210 to mechanically constrain the electrical connector 1210 after assembly of the driver enclosure 1200a.
The driver housing 1250a may be coupled to the driver cover 1230a via a snap-fit connection. For example,
The driver enclosure 1200a may be inserted into the first cavity 1110 of the heat sink 1100a as shown in
In some implementations, the snap-fit features (i.e., the snap-fit connectors 1240, 1260, 1262 and 1134) may be shaped and/or positioned to provide more space for the various components of the driver 1202 located in the cavity 1252. For example,
The sidewall 1251 of the driver housing 1250a may also include one or more keyed features 1256. The keyed feature 1256 may be a structural feature that breaks the radial symmetry of the sidewall 1251. The keyed feature 1256 may be shaped to align with corresponding keyed features 1132 of the heat sink 1100a, which allow the lighting module 1000a to fit inside an enclosure with tabs and/or posts, as discussed in more detail below. The keyed features 1256 and 1132 may align the driver enclosure 1200a to the heat sink 1100a and/or prevent unwanted rotation between the driver enclosure 1200a and the heat sink 1100a. The keyed feature 1256 may be a curved portion of the sidewall 1251 forming a concave surface with respect to the exterior of the sidewall 1251 that protrudes into the cavity 1252. The driver cover 1230a may also include keyed features 1236 that align with the keyed features 1256. During assembly, the keyed features 1236 and 1256 may align with corresponding keyed features 1132 on the heat sink 1100a to guide the insertion of the driver enclosure 1200a into the first cavity 1110 of the heat sink 1100a. In some implementations, the keyed features 1236 and 1256 of the driver enclosure 1200a may slide along an interior surface of the keyed features 1132 of the heat sink 1100a.
The driver housing 1250a may also include a base 1253 shaped to substantially conform with the shape of the partition 1104. For example, the base 1253 may include a recess 1255 that surrounds an island 1105 on the partition 1104 of the heat sink 1100a. In this manner, the base 1253 may also facilitate alignment between the driver enclosure 1200a and the heat sink 1100a (see
The recess 1255 may also be shaped to form a gap 1204 (also referred to herein as cavity 1204) between the driver enclosure 1200a and the island 1105 of the partition 1104 near the light source 1300. In other words, a portion of the bottom surface of the driver housing 1250a that includes the recess 1255 may not abut the partition 1104 of the heat sink 1100a, thus dividing the first cavity 1110 of the heat sink 1100a into a region occupied by the driver enclosure 1200a and the gap 1204. The gap 1204 may provide a higher thermal resistance between the driver enclosure 1200a and the partition 1104 so that the heat generated by the light source 1300 is primarily transported along the partition 1104 to a flange 1140 of the heat sink 1100a.
It should be appreciated, however, that in some implementations, the driver enclosure 1200a may not form the gap 1204 with the partition 1104. Instead, the driver enclosure 1200a may substantially conform with the partition 1104 after assembly. For example, at least a portion of the driver enclosure 1200a (e.g., the driver housing 1250a) may be formed as an overmold that covers the heat sink 1100a.
The driver 1202 may also generate heat during operation of the lighting module 1000a. The heat generated by the driver 1202 may be dissipated in several ways. In some implementations, the driver 1202 may be thermally coupled to the heat sink 1100a such that the heat generated by the driver 1202 is transferred to the heat sink 1100a. For example, the driver enclosure 1200a may be formed of a thermally conductive material to provide a heat conduction path between the driver 1202 and the heat sink 1100a. In some implementations, the driver 1202 may be thermally insulated from the heat sink 1100a (e.g., the driver enclosure 1200a is formed of a thermally insulating material) thus limiting the transfer of heat from the driver 1202 to the heat sink 1100a. For such cases, the driver 1202 may instead dissipate heat to the surrounding environment (e.g., the ceiling or wall space, the space within a cavity of a lighting fixture enclosure) via convection and/or radiation particularly if the surrounding environment is sufficiently large.
The driver enclosure 1200a may also include one or more selectable switches, such as switches 1220a and 1220b (collectively referred to herein as selectable switch 1220) electrically coupled to the driver 1202 and disposed along the top surface of the driver cover 1230a. The selectable switches 1220 may be various types of switches including, but not limited to linear, rotary, and dip switches. It should also be appreciated the positioning of the selectable switch 1220 is not limited to the driver cover 1230a, but instead may be disposed on other portions of the lighting module 1000a so long as the selectable switch 1220 is readily accessible by a user. The selectable switch 1220 may be partially inserted through openings in the driver cover 1230a (e.g., openings 1242a and 1242b) formed on the base 1235 to allow a user to manually select desired operating parameters of the lighting module 1000a. For example, the user may use the selectable switch 1220 to reconfigure the properties of the light outputted by the lighting module 1000a including, but not limited to a color temperature, a lumen output, and a power output of the light emitted by the light source 1300.
As shown in
The heat sink 1100a may include one or more keyed features 1132 to provide sufficient clearance for the lighting module 1000a to be inserted through an opening of an enclosure or a housing (not shown) that includes one or more tabs and/or posts disposed along the opening. For example, the enclosure may be a standard sized electrical junction box (e.g., a 3″ junction box, a 4″ junction box, a 3″/4″ combo junction box) with two tabs or posts that each include an opening (see, for example, the posts 2120a and 2120b and openings 2122a and 2122b in the enclosure 2100b of
The keyed feature 1132 may be a curved portion of the sidewall 1130 forming a concave surface with respect to the exterior of the sidewall 1130 and a convex surface with respect to the interior of the sidewall 1130. In some implementations, each keyed feature 1132 may be located along the sidewall 1130 proximate to one of the opening 1142 on the flange 1140. In this manner, the keyed feature 1132 may provide clearance for a corresponding tab) on an enclosure to slide along the length of the sidewall 1130 until contact is made with the flange 1140 when the lighting module 1000a is inserted into the enclosure. As described above, the tab may include an opening that aligns with the opening 1142. A fastener may be inserted through the respective openings 1142 of the lighting module 1000a and the openings of the enclosure for attachment. The keyed feature 1132 may further include different sized fins 1107 or no fins to ensure sufficient clearance for the tab/post of the enclosure.
As shown in
The reflector 1322 may be shaped to reflect light emitted by the light source 1300 with a desired angular and/or spatial distribution. For example, the reflector 1322 may be shaped to substantially collimate the light from the light source 1300. In another example, the reflector 1322 may be shaped such that the intensity of the light outputted by the lighting module 1000a is substantially uniform (i.e., there are no observable spots, rings, scalloping in the light). The reflector 1322 may reflect light specularly (e.g., the reflector 1322 has a mirrored surface) or diffusely (e.g., the reflector 1322 has a white, matte surface).
In some implementations, the lighting module 1000a may not include the reflector 1322. Instead, the interior surfaces of the second cavity 1120 of the heat sink 1100a may be configured to reflect the light from the light source 1300. In this manner, the number of parts in the lighting module 1000a may be reduced, thus simplifying assembly and/or decreasing costs. Additionally, the overall dimensions of the lighting module 1000a may also be reduced since the second cavity 1120 does not have to accommodate the reflector 1322.
In some implementations, the portion of the sidewall 1130, partition 1104, and/or flange 1140 forming the second cavity 1120 may be coated with a reflective coating. The reflective coating may be applied to at least a portion of the surfaces forming the second cavity 1120 so long as the portion of the surfaces with the reflective coating substantially surrounds the light source 1300. The reflective coating may provide a reflectance of at least about 75% within at least a desired wavelength range of interest. For example, the desired wavelength range of interest may correspond to the wavelength(s) of light emitted by the light source 1300. In another example, the desired wavelength range of interest may span the visible spectrum of light (e.g., about 400 nm to about 700 nm).
The reflective coating may be a paint that reflects light diffusely (e.g., a white matte paint), specularly (e.g., a mirror-finish paint), or some combination thereof. The reflective coating may also be applied using powder coating. In some implementations, a reflective film or sheet may be applied to the interior surfaces of the second cavity 1120. For example, a reflective film, such as a metallized mylar sheet or a white polymeric film, may be shaped to lie against and/or adhered to the various surfaces of the second cavity 1120. In some implementations, the respective surfaces of the second cavity 1120 may be polished to increase the reflectance of the second cavity 1120. For example, the heat sink 1100 may be formed of a metal, such as aluminum, which may be polished to have a sufficiently smooth surface (i.e., low surface roughness) to specularly reflect light from the light source 1300.
In some implementations, the various surfaces defining the second cavity 1120 may also be shaped to reflect the light with a desired intensity distribution along a desired direction. For example, the partition 1104 may be shaped to have a tapered and/or a curved wall and/or surface. The light emitted by the light source 1300 at large emission angles may reflect off the partition 1104 and towards the opening 1336 of the retaining ring 1330a where the emission angle is defined with respect to an optical axis of the light source 1300. It should be appreciated, however, that in other implementations the partition 1104 may be substantially flat with respect to one or both of the cavities 1110 and 1120.
The optic 1320 may be various types of optics including, but not limited to a diffusive element, a focusing optic, and a diverging optic. In some implementations, the optic 1320 may also filter a portion of the light such that a desired spectrum of light (e.g., a desired color) is outputted by the lighting module 1000a. In some implementations, the optic 1320 may be directly coupled to the retaining ring 1330a using various coupling mechanisms including, but not limited to a snap fit, a press fit, and an ultrasonic weld. In some implementations, the optic 1320 may be integrated together with the retaining ring 1330a. For example, the retaining ring 1330a may be formed of a transparent material without the opening 1336. The central portion of the retaining ring 1330a through which the light exits the lighting module 1000a may be shaped as a lens. Additionally, the surface finish of the central portion of the retaining ring 1330a may be configured to specularly or diffusely transmit light.
The reflector 1322 and/or the optic 1320 may generally be field replaceable. For example, a user wanting to modify the light output may remove the retaining ring 1330a by pressing respective snap-fit connectors (e.g., snap-fit connectors 1332) in order to swap out the reflector 1322 and/or the optic 1320. In another example, the snap-fit connectors 1332 may be sufficiently compliant such that a tool (e.g. a flat head screwdriver) can pry the retaining ring 1330a off the heat sink 1100a. In implementations where the retaining ring 1330a and the optic 1320 are integrated together as a single part, the user may replace the retaining ring 1330a for another retaining ring 1330a. In this manner, the retaining ring 1330a may function as a vehicle for mounting different optics 1320 into the lighting module 1000a.
The retaining ring 1330a may also include male snap-fit connectors 1332 that couple to corresponding female snap-fit receptacles 1136 in the heat sink 1100a. The female snap-fit receptacles 1136 may be collocated with the keyed feature 1132 and/or the opening 1142 on the flange 1140. As shown in
In some implementations, the female snap-fit receptacles 1136 on the heat sink 1100a may be disposed proximate to the openings 1142 on the flange 1140 as shown in
The potting material 1270 may generally be an electrically insulating material that electrically insulates the driver 1202 from its surroundings. In some implementations, the potting material 1270 may conformally coat the driver 1202. For example, the potting material 1270 may be applied as a liquid that then cures into a solid. The potting material 1270 may be formed from various materials including, but not limited to a thermosetting polymer, a silicone rubber, and epoxy resins.
A Lighting Module with an Integrated Connector and an Optical Lens
The base 1253 of the driver housing 1250c may be shaped to have a recess 1255 that substantially conforms with the shape of the partition 1104. The base 1253 may further include openings 1264 through which electrical wires from the driver may be fed through for connection with the light source 1300. The driver cover 1230d may include an opening 1242 for the selectable switch 1220 and an opening 1234 for the electrical connector 1210a formed on a base 1235. The driver cover 1230d may also include a lip 1233 disposed along the periphery of the base 1235 and the driver housing 1250c may include a support structure 1254 that together mechanically support and constrain the electrical connector 1210a. In some implementations, the base 1235 may be substantially flat. The driver housing 1250c and the driver 1230d may be further shaped such that the base 1235 is substantially flush with a top edge of the heat sink 1100b and/or substantially fills the first cavity 1110.
The heat sink 1100b may also include keyed features 1132 disposed along the sidewall 1130 that align with the keyed features 1256 and 1236 of the driver enclosure 1200e. As shown, the keyed features 1132 may also provide clearance for openings 1142 on the flange 1140 that are used to couple the lighting module 1000c to an external enclosure or housing (e.g., tabs on an electrical junction box). The female snap-fit receptacles 1136 may be formed as slots that extend along the interior surface of the sidewall 1130 through the partition 1104 and the flange 1140. In this manner, the female snap-fit receptacles 1136 may couple to the driver enclosure 1200e and respective male snap-fit connectors 1332 in the retaining ring 1330b.
In some implementations, the driver enclosure 1200e and the heat sink 1100b may be sized and shaped to enhance the heat dissipating characteristics of the lighting module 1000c. For example, the driver enclosure 1200e and the heat sink 1100b may be shaped such that the driver enclosure 1200e only physically contacts the heat sink 1100b where the driver enclosure 1200e is at a higher temperature than the heat sink 1100b during normal operating conditions of the lighting module 1000c (e.g., the lighting module 1000c is operating at steady-state and outputs light with a desired color temperature, lumen output, and/or power). For instance, the portion(s) of the driver enclosure 1200e that physically contact the heat sink 1100b may be located near portion(s) and/or element(s) of the driver 1202 that generate heat, such as a transformer or a diode. In this manner, the heat sink 1100b may more effectively dissipate heat generated by the driver 1202.
On the other hand, the driver enclosure 1200e and the heat sink 1100b may be shaped such that a gap is formed between the driver enclosure 1200e and the heat sink 1100b where the heat sink 1100b is at a higher temperature than the driver enclosure 1200e. The gaps may be filled with air, thus providing a thermally insulating barrier. In this manner, the heat sink 1100b may receive heat from other components of the lighting module 1000c, such as the light source 1300, and subsequently dissipate the heat to the surrounding environment instead of the driver enclosure 1200e to avoid raising the temperature of the components of the driver 1202 (e.g., a capacitor). For example,
Additionally, the driver enclosure 1200e and the heat sink 1100b may form a gap 1206 between a portion of the sidewall 1251 of the driver housing 1250c and a portion of the sidewall 1130 of the heat sink 1100b. As shown, the gap 1206 may extend from the top of the heat sink 1100b and/or the driver enclosure 1200e to the partition 1104 of the heat sink 1100b within the first cavity 1110 along certain portions of the first cavity 1110. The gap 1206 may similarly provide a higher thermal resistance compared to, for example, the thermal resistance associated with convective or radiative heat transfer from the heat sink 1100b to the environment in order for heat to be primarily dissipated to the environment.
The dimensions of the driver enclosure 1200e may also be reduced such that portions of the heat sink 1130e may be made thicker, which reduces the thermal resistance of the heat sink 1130e thereby enabling greater conductive heat transfer. For example, the overall height of the driver enclosure 1200e may be reduced allowing for a thicker partition 1104 without changing the overall dimensions of the lighting module 1000c. The driver housing 1250c, however, may still accommodate the electrical connector 1210a. This may be accomplished by including a protruding section 1272 in the driver housing 1250c to provide sufficient interior space to fully enclose the support structures 1254 and the electrical connector 1210a in the cavity 1252 (see
Furthermore, the overall size of the second cavity 1120 of the heat sink 1100b may be reduced in order to increase the size of the flange 1140. Similar to the improvements gained by a thicker partition 1104, a larger flange 1140 may also provide greater heat conduction further improving the heat dissipation characteristics of the lighting module 1000c.
As described above, the optical lens 1350 may be shaped and/or dimensioned to fit within the second cavity 1120 of the heat sink 1100b. For example, the optical lens 1350 may have a diameter that ranges between about 20 mm and about 60 mm. The optical lens 1350 may also have a height that is at least about 2 mm. In some implementations, the optical lens 1350 may substantially collimate the light such that the divergence angle of the light leaving the lighting module 1000c is less than about 10 degrees. In some implementations, the optical lens 1350 may output light having an angular distribution characterized by a full width half maximum (FWHM) that ranges between about 10 degrees and about 60 degrees. In some implementations, the optical lens 1350 may have a light coupling efficiency (i.e., the ratio of the luminous flux coupled out of the optical lens 1350 and into the environment and the luminous flux coupled into the optical lens 1350 from the light source 1300) that is at least about 70%.
In some implementations, the optical lens 1350 may redirect light at different wavelengths of interest in a substantially similar manner (i.e., the optical lens 1350 has low chromatic aberration). For example, the light source 1300 may include multiple light emitting elements that emit light at different wavelengths. The optical lens 1350 may be tailored to redirect the light at each wavelength such that the resulting spatial and angular distributions of light at each wavelength are substantially the same.
The optical lens 1350 may be various types of optics including, but not limited to a folded optical element (e.g., a total internal reflection (TIR) optic), a Fresnel lens, and a lens array (e.g., a substantially flat, transparent substrate with multiple lenses formed onto the substrate). The optical lens 1350 may be formed of various hard plastics and glasses including, but not limited to as polycarbonate, acrylic polymer, cyclo olefin polymer (Zeonex), polystyrene, silicate-based glasses.
In some implementations, the optical lens 1350 may be a TIR optic that redirects and outputs light from the light source 1300 with a desired angular and spatial distribution. The TIR optic may include surfaces configured to total internally reflect light in order to redirect light emitted over a broad range of emission angles (e.g., a 2π solid angle or a hemisphere) while maintaining a compact size. For example, the TIR optic may receive light from the light source 1300 and subsequently redirect the light via refraction, reflection, and transmission such that the light is outputted along a preferred direction without interacting with the interior surfaces of the second cavity 1120. In some implementations, the lighting module 1000c may not include the reflector 1322 in the lighting module 1000a.
In some implementations, the TIR optic may include a hollow core to receive light and subsequently redirect the light along a desired trajectory via refraction. The TIR optic may also include V-shaped grooves disposed along an outer surface to reflect light via total internal reflection. The TIR optic may be circular in shape and the V-shaped grooves may be oriented radially with respect to the center of the TIR optic.
In general, the lighting module 1000c may support various TIR optics so long as the dimensions of the TIR optic are suitable for the lighting module 1000c (i.e., the TIR optic fits in the second cavity 1120. For example, the TIR optic may have a diameter that ranges between about 20 mm and about 60 mm and a height less than about 20 mm.
In some implementations, the TIR optic may be a hybrid TIR optic that includes an integrated reflector to increase the light coupling efficiency of the optic (i.e., the luminous flux coupled out of the TIR optic divided by the luminous flux generated by the light source 1300). The integrated reflector may be coupled to a folded optic element to redirect light emitted at large emission angles that may otherwise be absorbed and/or scattered along an undesirable direction in the second cavity 1120. Examples of hybrid TIR optics may be found in U.S. application Ser. No. 16/831,322 (hereafter the '322 application), filed on Mar. 26, 2020, entitled, “FOLDED OPTICS METHODS AND APPARATUS FOR IMPROVING EFFICIENCY OF LED-BASED LUMINAIRES,” and International Application No. PCT/US20/39728 (hereafter the '728 application), filed on Jun. 26, 2020, entitled, “OPTICAL ELEMENT FOR IMPROVING BEAM QUALITY AND LIGHT COUPLING EFFICIENCY”. In some implementations, the TIR optic may be a smaller variant of the hybrid TIR optic in the '322 application or the '728 application that leverages the same operating principles.
As shown in
It should be appreciated, however, that in some implementations, the retaining ring 1330b may not include an opening 1336, but instead may be entirely solid. For such cases, the retaining ring 1330b may be formed of an optically transparent material that transmits light leaving the optical lens 1350 or directly from the light source 1300 if no optical lens 1350 is included. For example,
The flange 1334 may include a ledge 1338 so that the optical lens 1350 is recessed with respect to the retaining ring 1330b. The retaining ring 1330b may further include notches 1342 that align with and expose the openings 1142 of the heat sink 1100b when the retaining ring 1330b is coupled to the heat sink 1100b. The retaining ring 1330b may also include multiple male snap-fit connectors 1332 for insertion into the slots forming the female snap-fit receptacles 1136 in the heat sink 1100b. In some implementations, the male snap-fit connectors 1332 may be sufficiently compliant such that the retaining ring 1330b may be removed from the heat sink 1100b even if the male snap-fit connectors 1332 and/or the female snap-fit receptacles1136 are not directly accessible. For example, a user may use a tool (e.g., a flat head screwdriver) to pry the retaining ring 1330b off the heat sink 1100b by pressing the tool against the flange 1334 of the retaining ring 1330b and/or the flange 1140 of the heat sink 1100b.
A Lighting Module with a Partially Enclosed Driver Enclosure
In some implementations, the lighting module may include a driver enclosure that does not fully enclose and/or encapsulate the driver. Said in another way, the driver enclosure may not provide a barrier that physically separates the driver from other electrically conducting materials in the lighting module, such as the heat sink. Instead, the driver enclosure may suspend the driver above a portion of the heat sink to prevent the driver from physically contacting the heat sink.
For example,
The lighting module 1000e may include a driver enclosure 1200f having a driver cover 1230e shaped as a cup to contain the driver. As shown, the driver cover 1230e may have an open end that couples to a top edge of the module housing 1100c to enclose the first cavity 1110. The driver, which is disposed within the driver cover 1230e, may thus be suspended above the partition 1104 of the module housing 1100c. In some implementations, a connector 1210 may also be integrated into the lighting module 1000e and, in particular, supported by the driver cover 1230e. In some implementations, the connector 1210 may be substantially disposed in the first cavity 1110 such that only the receptacle of the connector 1210 is exposed to the surroundings. Said in another way, the connector 1210 may not protrude outwards from the driver cover 1230e. The connector 1210 may be electrically coupled to the driver to supply electrical power to the driver. In some implementations, the connector 1210 may be a standardized connector that couples to a corresponding connector originating from a building electrical supply system or another lighting module.
The lighting module 1000e may further include a light source holder 1310 disposed within the second cavity 1120 to mount and/or position the light source 1300 to the module housing 1100c for assembly. In some implementations, the lighting module 1000e may also include an optic 1360 to redirect the light emitted by the light source 1300 and an optic holder 1330d to retain the optic 1360 in the second cavity 1120 and/or to enclose the second cavity 1120. It should be appreciated the various features, structures, and materials described with respect to the lighting modules 1000a-1000d describes above may also be applied to the lighting module 1000e shown in
In some implementations, the lighting module 1000e may further include a switch 1220 disposed, in part, in the first cavity 1110 and supported by the driver cover 1230e. The switch 1220 may be electrically coupled to the driver and used to adjust the electric current supplied to the light source 1300, thus changing the power output and/or the lumen output of the light source 1300. The switch 1220 may also be used to adjust another property of the emitted light, such as the color temperature. In this manner, the power level of the lighting module 1000e and/or the spectral characteristics of the emitted light may be field changeable. In some implementations, the switch 1220 may allow a user to adjust the power output level of the light source 1300 without use of a tool. For example, the switch 1220 shown in
In some implementations, the lighting module 1000e may allow a user to adjust current level settings using a remote device (e.g., a smart phone, a tablet, a computer, a remote) communicatively coupled to the lighting module 1000e. For such cases, the lighting module 1000e may not include the switch 1220, but instead may rely upon the remote device to adjust the power levels of the light source 1300.
As before, the driver of the lighting module 1000e may receive a direct current (DC) and/or an alternating current (AC) as the electrical input. By supporting both DC and AC inputs, the lighting module 1000e may be deployed in both indoor and outdoor settings. For example, indoor lighting fixtures (e.g., a downlight, a recessed light, a cylinder light) typically use an AC connection and outdoor lighting fixtures (e.g., a landscape light, a flood light, an in-ground light) typically use a DC connection. The driver of the lighting module 1000e may also be configured to use DC and/or AC currents to supply power to the light source 1300, allowing the lighting module 1000e to be used in said various settings without modification. In some implementations, the driver may be compatible with a range of operating voltages including, but not limited to low operating voltages (e.g., voltages less than 50V) and high operating voltages (e.g., voltages greater than 50V). In particular, the driver may be configured to provide DC current at voltages ranging between about 0V to about 10V for some lighting applications.
In some implementations, the module housing 1100c may include a flange 1140 disposed at one end of the sidewall 1130 adjoining the second cavity 1120. The flange 1140 may provide an interface to mount a trim (not shown) to the module housing 1100c and/or to mount the lighting module 1000e to an enclosure. For instance,
In some implementations, the lighting module 1000e may be installed into an enclosure having posts and/or tabs with opening(s) disposed within a cavity of the enclosure. To ensure the lighting module 1000e and, in particular, the module housing 1100c has sufficient clearance for insertion into the cavity of the enclosure, the sidewall 1130 may include keyed features 1132 disposed proximate to the openings 1142. In this example, the keyed features 1132 may be formed as a gap between the fins 1107 as opposed to changing the shape of the sidewall 1130 as described above.
The light source 1300 may be disposed in the second cavity 1120 and oriented to emit light out of the second cavity 1120 of the module housing 1100. In some implementations, the light source 1300 may be a single chip on board (COB) light source disposed onto a center portion of the partition 1104 adjoining the second cavity 1120. The light source 1300 may be secured to the module housing 1100 via a light source holder 1310, which will be described in more detail below in relation to the lighting module 1000f. For example, the COB light source may be placed into a recess on the light source holder 1310 that prevents lateral movement of the light source 1300. In another example, the light source holder 1310 may include at least one snap fit connector to secure couple the light source 1300. The light source holder 1310 may then be coupled to the module housing 1100 using various coupling mechanisms including, but not limited to a fastener, a twist and lock connector, and a snap fit connector.
The light source holder 1310 may thus be used to improve ease of handling and alignment of the light source 1300 during assembly. Additionally, the light source holder 1310 may be removable, allowing replacement or swapping of the light source 1300 after the lighting module 1000e is installed. However, it should be appreciated that the light source 1300 may also be directly coupled to the module housing 1100 using various coupling mechanisms including, but not limited to an adhesive, a fastener, and a snap fit connector integrated into the module housing 1100 and/or light source 1300.
The lighting module 1000e may also include an optic 1360 to modify various aspects of the light output of the light source 1300 including, but not limited to the power output, angular distribution, spatial distribution, and spectral distribution of light emitted into an environment. The manner in which the optic 1360 modifies light from the light source 1300 may depend, in part, on the geometry and the material used to form the optic 1360. Additionally, the optic 1360 may include a coating to further modify the light output form the light source 1300. For example, the optic 1360 may include a laminated, diffuse optical structure (e.g., a Lambertian film). The diffuse optical structure may disperse light such that the internal components of the lighting module 1000e (e.g., the light source 1300, the light source holder 1310) are not readily observable externally (e.g., when a user is looking through the optic 1360 and into the second cavity 1120) or within the emitted light beam (e.g., the output light has a substantially uniform spatial and angular distribution).
The optic 1360 may be disposed in the second cavity 1120 and aligned to the light source 1300. In some implementations, the optic 1360 may have an integrated coupling mechanism (e.g., a snap fit connector) to directly couple the optic 1360 to the module housing 1100. In some implementations, the optic 1360 may be secured to the module housing 1100 using an optic holder 1330d (also referred to as a retaining ring 1330d). The optic holder 1330d may be shaped to allow the optic 1360 to fit within a recess or opening. For example, the optic 1360 may be inserted through an opening of the optic holder 1330d such that a flange 1362 on the optic 1360 abuts a ridge 1334 of the optic holder 1330d as shown in
In some implementations, the module housing 1100c and, in particular, the partition 1104 may include a tapered wall 1112 oriented at an oblique angle with respect to the center portion of the partition 1104 (or the surface of the partition 1104 abutting the first cavity 1110) and the side wall 1130 of the second cavity 1120. The angle of the tapered wall 1112 may be chosen to reflect light emitted by the light source 1300 along a preferred direction through the optic 1360. In some implementations, the tapered wall 1112, the back wall, and/or the sidewall of the second cavity 1120 may have a coating to increase the reflection of light emitted by the light source 1300. For example, the coating may be a diffuse reflective coating (e.g., white paint) or a specular reflective coating (e.g., a polished metallic coating).
As described above, the lighting modules described herein may be installed in a variety of lighting fixtures. In one example,
In some implementations, the luminaire housing 2100a may be used as an electrical junction box to contain one or more electrical wires and/or electrical wire splices. For example, the luminaire housing 2100a may include at least one knockout through which a wire from a building electrical supply system or another downlight (e.g., a second downlight fixture 2000) may be inserted to supply electrical power to the lighting module 1000e.
In some implementations, the luminaire housing 2100a may be mounted to a support structure of a building (e.g., a T-bar, a joist, a stud) via a mounting bracket or a set of adjustable hanger bars. In some implementations, the luminaire housing 2100a may be coupled to a substantially vertical surface and oriented to provide light onto a horizontal surface (e.g., a step light, a wall sconce). For example, a mounting bracket may be disposed on the side of the luminaire housing 2100a for connection to a vertical wall.
The luminaire housing 2100a may have various dimensions. For example, the cavity of the luminaire housing 2100a may have a diameter ranging from about 1 inch to about 8 inches. In another example, the cavity of the luminaire housing 2100a may have a volume ranging between about 15 cubic inches and about 50 cubic inches.
The downlight 2000 may also include a trim 2200 to cover the opening in the wall or ceiling of the building and/or the cavity of the luminaire housing 2100a. In some implementations, the trim 2200 may include a set of snap fit connectors 2210 to couple to the lighting module 1000e (e.g., via a ridge on the flange 1140 of the module housing 1100). The trim 2200 may be coupled to the luminaire housing 2100a using various coupling mechanisms including, but not limited to a torsion spring, a spring clip, a snap fit connector, and a fastener. For example,
In another example,
The cylinder light 3000 may thus emit light along two directions (e.g., a downlight and an uplight). In some implementations, the light output (e.g., intensity, angular distribution, spatial distribution, spectral distribution) from the lighting modules 1000e-1 and 1000e-2 may be substantially similar. For example, the lighting modules 1000e-1 and 1000e-2 may both emit indirect, ambient light to light an interior space. In some implementations, however, the light output from the lighting modules 1000e-1 and 1000e-2 may be substantially different. For example, the lighting module 1000e-1 may emit indirect, ambient light (e.g., an uplight) and the lighting module 1000e-2 may emit direct, focused light (e.g., a downlight). Although the cylinder light 3000 is shown in
The cylinder light 3000 may be mounted in various configurations including, but not limited to a surface mount, a wall mount, and a pendant mount. For example,
It should be appreciated that the downlight fixture 2000 and the cylinder light 3000 represent two exemplary types of lighting fixtures that may incorporate the lighting module 1000e. Other types of lighting fixtures using various enclosures to house the lighting module 1000e may also be used with the lighting module 1000e including, but not limited to electrical junction boxes, a recessed lighting fixture (e.g., a “can” housing of a recessed lighting fixture), a wall sconce lighting fixture, under cabinet lighting, a surface mount lighting fixture, a pendant lighting fixture, a floodlight fixture, an outdoor lighting fixture (e.g., a tree lighting fixture, a step lighting fixture, a ground or pathway lighting fixture, a garden lighting fixture, a landscape lighting fixture), and a security lighting fixture. It should also be appreciated that the lighting module 1000e may be installed into a space without a separate enclosure. For example, the lighting module 1000e may be coupled to trim having one or more spring clips and/or friction clips that directly attach to an interior ceiling plane or wall plane.
A Lighting Module with an External Connector and a Ground Connection
In some implementations, the lighting module may forego integrating an electrical connector in order to further reduce the overall size of the lighting module. Instead, the lighting module may utilize an external electrical connector coupled to the lighting module via one or more wires and/or cables protruding out of the lighting module. The lighting module may also utilize a driver enclosure that is not double insulated (i.e., the driver enclosure does not electrically isolate the driver from the other electrically conductive materials in the lighting module, such as a heat sink) in order to further reduce the dimensions of the driver enclosure, which, in turn, allows for a smaller lighting module.
A driver enclosure 1200g and, in particular, a driver cover 1230f may be disposed within the first cavity 1110 to at least partially contain a driver 1202. The driver enclosure 1200g may further include an electrically insulating film 1280 disposed on a surface of the partition 1104 adjoining the first cavity 1110. In this manner, the driver cover 1230f and the film 1280 may provide an electrically insulating barrier that substantially surrounds the driver 1202. As shown in
In some implementations, one or more wires/cables 1205 may be routed through the driver enclosure 1200g and into the first cavity 1110 to at least supply electrical power to the driver 1202. In some implementations, the wires/cables 1205 may also provide a dimmer signal (e.g., a 0-10V signal) to adjust the brightness of the light emitted by the light source 1300. The exposed ends of the wires/cables 1205 may be coupled to a standardized electrical connector (not shown) to facilitate connection to an external power source (e.g., a DC or AC electrical power supply in a building). In some implementations, the lighting module 1000f may further include a selectable switch 1220 supported by the driver enclosure 1200g and electrically coupled to the driver 1202 to adjust one of a power level or spectral properties of the light emitted the light source.
In some implementations, a light source holder 1310 may be included to position and securely mount the light source 1300 to the heat sink 1100d. The lighting module 1000f may further include an optical element, such as a reflector 1322 or an optical lens 1350, disposed within the second cavity 1120 to redirect light along a preferred direction (e.g., a desired angular and/or spatial distribution) and/or to increase the light coupling efficiency of the lighting module 1000f. The lighting module 1000f may further include an optic cover 1330e that substantially encloses the second cavity 1120 and, in some instances, securely retains the reflector 1322 within the second cavity 1120.
In some implementations, the heat sink 1100d may further include one or more receptacles 1134a disposed on a flange 1140 of the heat sink 1100d to facilitate attachment of the trim 1600 to the heat sink 1100d. In particular, the trim 1600 may include a connector 1620 having a connecting end 1624 that is configured to be inserted into the receptacle 1134a. The connection between the connecting end 1624 and the receptacle 1134a and the resultant interface between the heat sink 1100d and the trim 1600 may be tailored to enhance the dissipation of heat generated by the light source 1300 and/or the driver 1202 from the heat sink 1100d to the trim 1600. In some implementations, the receptacle 1134a and the connector 1620 may be tailored such that the trim 1600 is electrically grounded to the heat sink 1100d. In some implementations, the wires/cables 1205 may include a ground wire/cable 1205a to electrically ground the heat sink 1100d to an external ground. For example,
It should be appreciated the various features, structures, and materials described with respect to the lighting modules 1000a-1000e describes above may also be applied to the lighting module 1000f shown in
As before, the lighting module 1000f may be shaped and/or dimensioned to fit within the confined space of a ceiling, wall, or floor and/or an enclosure. For example, the lighting module 1000f may have an overall width (e.g., the outer diameter w of the heat sink 1100d) that is less than about 3 inches. The overall height of the lighting module 1000f (e.g., the height h of the heat sink 1100a) may be less than about 1.6 inches. These dimensions may enable the lighting module 1000f to fit into a space having a height dimension less than or equal to about 2.25 inches and a width dimension of about 4 inches. In some implementations, the lighting module 1000f may fit into a space having a volume of at least about 18 cubic inches.
In some implementations, the lighting module 1000f may be inserted into an enclosure, such as a 3/0, 4/0 standard electrical junction box or a 4-10 inch recessed lighting fixture. For example,
It should be appreciated that the lighting module 1000f may also be installed directly into a ceiling, wall, or floor space. For example, the trim 1600 may include a spring clip to couple the trim 1600 and the lighting module 1000f directly to a ceiling or wall plane.
In some implementations, the sidewall 1231 may be shaped to conform with and physically contact the interior portion of the sidewall 1130 of the heat sink 1100d such that the driver cover 1230f substantially fills the first cavity 1110. For example, the driver cover 1230f may include keyed features 1236 (e.g., curved portions of the sidewall 1231) that align with corresponding keyed features 1132 of the heat sink 1100d. The sidewall 1231 may further include male snap-fit connector(s) 1243 disposed on a bottom exterior edge of the sidewall 1231 to couple the driver cover 1230f to the receptacles 1134a of the heat sink 1100d. In this manner, the driver cover 1230f may be coupled to the heat sink 1100d without the use of any tools.
The base 1235 may provide a substantially flat exterior surface. In some implementations, the base 1235 and the sidewall 1231 may be shaped and/or dimensioned such that the flat exterior surface of the base 1235 is substantially flush with a top (or rear) edge of the sidewall 1130 adjoining the first cavity 1110 as shown in
As described above, the driver cover 1230f may include ledges 1244 disposed along the bottom interior edge of the sidewall 1231. The driver cover 1230f may further include posts 1247 disposed on the interior portion of the sidewall 1231. The ledges 1244 and the posts 1247 may be arranged to abut opposing sides of the PCB of the driver 1202 in order to securely couple the driver 12202 to the driver cover 1230f. In some implementations, the ledges 1244 may offset the PCB of the driver 1202 such that the gap 1204 is formed between the PCB and the partition 1104.
In some implementations, the insulating film 1280 may be shaped to conform with the opening defined by the bottom edge of the sidewall 1231. In this manner, the insulating film 1280 and the driver cover 1230f may provide an insulating barrier that substantially surrounds the driver 1202.
The driver housing 1230f and the insulating film 1280 may be formed from various electrically insulating materials including, but not limited to polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS), polycarbonate (PC), polyurethane (PU), polyethylene, polyethylene terephthalate, polypropylene, polystyrene, and mylar.
As shown, the heat sink 1100d may include one or more fins 1107 disposed along the exterior surface of the sidewall 1130. When the lighting module 1000f is installed into sufficiently large space, the fins 1107 may dissipate a portion of the heat generated by the light source 1300 and/or the driver 1202 via convection. However, it should be appreciated the heat sink 1100d, in other implementations, may not include the fins 1107.
The heat sink 1100d may further include one or more female snap-fit receptacles 1136 formed, in part, from the sidewall 1130 and/or the partition 1104 to receive corresponding male snap-fit connectors 1332 of the optic cover 1330e to couple the optic cover 1330e to the heat sink 1100d. In some implementations, the female snap-fit receptacles 1136 may be formed onto at least one surface defining the second cavity 1120.
In some implementations, the flange 1140 may include an annular portion 1146a having an outer edge 1146b and an inner edge 1146c. As shown in
The flange 1140 may include one or more openings 1142 (shown in
The flange 1140 may further include one or more receptacles 1134a to receive a connecting end 1624 of a connector 1620 on the trim 1600 to couple the trim 1600 to the heat sink 1100d. In some implementations, the receptacles 1134a may be disposed on the annular portion 1146a such that no portion of the receptacle 1134a intersects the outer edge 1146b. Instead, the receptacles 1134a may be formed along the inner edge 1146c of the annular portion 1146a. In some implementations, the receptacle 1134a may provide an opening that extends through the partition 1104 and into the first cavity 1110. In some implementations, the receptacle 1134a may also receive the male snap-fit connectors 1243 of the driver enclosure 1230f.
As shown in
The contact area between the annular portion 1146a and the base section 1612 may enable the heat sink 1100d to transfer heat received by the light source 1300 and/or the driver 1202 to the trim 1600 via heat conduction. In some implementations, the lighting module 1000f may be installed in a sufficiently confined space such that the lighting module 1000f is unable to be effectively cooled via convective cooling and/or radiative transfer from the sidewall 1130 of the heat sink 1100d to the surrounding environment within the ceiling/wall space and/or the enclosure. Thus, the heat generated by the light source 1300 and/or the driver 1202 may be dissipated primarily by the trim 1600 via heat transfer between the annular portion 1146a and the base section 1612. In some implementations, the annular portion 1146a of the flange 1140 and the base section 1612 may be shaped and/or dimensioned to provide a sufficiently large contact area to transfer heat so that the light source 1300 may generally maintain a temperature below 125° C. In some implementations, the heat sink 1100d and the trim 1600 may be designed such that the light source 1300 is preferably kept below a temperature of 85° C., particularly when the driver 1202 is supplying at least 10 W of electrical power to the light source 1300. Similarly, the heat sink 1100d and/or the trim 1600 may be tailored such that the circuit elements of the driver 1202 (e.g., a capacitor) is kept below 90° C. during operation of the lighting module 1000f. In some implementations, the annular portion 1146a of the flange 1140 and the base section 1612 may make sufficient contact such that a temperature drop between the heat sink 1100d and the trim 1600 is less than or equal to about 20° C. to provide sufficient heat flow from the heat sink to the trim and from the trim to the ambient environment (e.g., air). For example, the temperature difference between a portion of the annular portion 1146a and a portion of the base section 1612 may be less than or equal to about 20° C.
In some implementations, the surface 1138 of the ledge 1137 may be sloped such that as the trim 1600 is rotated, the connecting end 1624 may slide along the surface 1138 resulting in a progressively larger compressive force being applied to press the heat sink 1100d and the trim 1600 together. The compressive force may increase the contact area between the annular portion 1146a and the base section 1612, thus reducing the thermal contact resistance and increasing heat dissipation.
In some implementations, the trim 1600 may also be electrically grounded to the heat sink 1100d based, in part, on the contact between the connector 1620 and the receptacle 1134a. For example, the heat sink 1100d and the connector 1620 may each be formed from an electrically conductive material, such as aluminum. A portion of the receptacle 1134a, such as the surface 1138, may expose the electrically conductive material such that when the trim 1600 is coupled to the heat sink 1100d, the connecting end 1624 may physically contact the portion of the receptacle 1134a where the electrically conductive material is exposed. In this manner, the trim 1600 may be electrically coupled to the heat sink 1100d. If the lighting module 1000f includes a ground wire/cable 1205, the trim 1600 may thus be electrically grounded to an external ground together with the heat sink 1100d. In some implementations, the heat sink 1100d may be painted (e.g., with a black paint) and/or coated (e.g., anodized) such that a portion of the receptacle 1134 (e.g. the surface 1138) is left exposed to facilitate an electrical connection with the trim 1600.
The base section 1612 may further include angled tabs 1614 to align and center the trim 1600 to the heat sink 1100d via the rounded and/or chamfered edge 1144. The base section 1612 may also include the connectors 1620. The connector 1620 may be a metal clip formed separately from the base section 1612 to improve manufacturability (e.g., the metal clip may be formed using standard sheet metal processes, the components of the trim 1600 do not have any undercuts). As shown, the connector 1620 may have an opening 1622 that aligns with a corresponding opening (not shown) on the base section 1612 so that a fastener may couple the connector 1620 to the base section 1612. The connector 1620 may be disposed within a recess in the base section 1612 to ensure the base section 1612 physically contacts the heat sink 1100d.
As shown, the connector 1620 may include the connecting end 1624 that couples to the receptacle 1134a. The connector 1620 may also include a connecting end 1626 disposed outside the heat sink 1100d when the trim 1600 is coupled to the heat sink 1100d. The connecting 1626 may be used, in part, as a friction clip to couple the trim 1600 to an enclosure. The shape and/or dimensions of the connector 1620 may thus vary depending on the placement of the receptacles 1134a on the heat sink 1100d and the size of the enclosure housing the lighting module 1000f. As shown, the connector 1620 may include both the connecting ends 1624 and 1626 (e.g., a single metal clip may be used to couple the trim 1600 to the lighting module 1000f and an enclosure). However, it should be appreciated that in other implementations, the trim 1600 may include two metal clips with one metal clip including the connecting end 1624 and another metal clip including the connecting end 1626.
The sidewall 1311 may further include a tapered section 1312 adjoining the opening 1313. In some implementations, the tapered section 1312 may have a linear profile. If the opening 1313 is circular in shape, the tapered section 1312 may thus form a conical surface. The linear profile of the tapered section 1312 may be oriented at angle, a, with respect to an axis parallel to a centerline axis 1301 of the light source holder 1310 as shown in
In some implementations, the light source holder 1310 and, in particular, the tapered section 1312 may be tailored to reflect at least a portion of the light emitted by the light source 1300. In this manner, the light source holder 1310 may increase the light coupling efficiency of the lighting module 1000a by ensuring light emitted at larger emission angles are coupled out of the lighting module 1000a instead of being trapped and absorbed within the lighting module 1000a. The light source holder 1310 may also be shaped to reflect light along a desired set of directions. For example, the light source holder 1310 may be shaped to reflect light such that light is more uniformly distributed spatially and/or angularly. In some implementations, the light source holder 1310 may be tailored to have a reflectivity of at least about 75%.
The light source holder 1310 may also include a light source recess 1314 to receive the light source 1300 for assembly. In general, the shape and/or dimensions of the light source recess 1314 may depend on the shape of the light source 1300. For example,
The sidewall 1311 may further include various mounting mechanisms to couple the light source holder 1310 to the heat sink 1100. For example, the sidewall 1311 may include one or more snap-fit connectors (e.g., snap-fit connectors 1317a and 1317b) to engage corresponding snap-fit receivers (not shown) in the recessed section 1130 of the heat sink 1100. In some implementations, the snap-fit connectors 1317a and 1317b may also be coupled to respective snap-fit receivers in the optical element (e.g., a reflector 1322, an optical lens 1350). In another example, the sidewall 1311 may include openings 1315 to receive the fasteners 1302 to couple to the heat sink 1100 via the openings 1106.
The light source holder 1310 may also provide features to connect the power cables 1030a and 1030b to the light source 1300. For example, the light source holder 1310 may include a slot formed along the sidewall 1311 to receive a poke-in connector. As shown, the slot may include an opening 1316a on the sidewall 1311 to receive the power cable, an opening 1316b adjoining the light source recess 1314 for the poke-in connector to contact a respective terminal of the light source 1300, and an opening 1316c to access the poke-in connector (e.g., to bend a tab once the power cable is inserted thereby restraining the power cable). As shown, the light source holder 1310 may include a pair of slots to support the power cables 1030a and 1030b. Furthermore, the light source holder 1310 may be marked to indicate the polarity of the terminal (e.g., a positive or negative terminal).
The light source holder 1310 may be formed from various electrically insulating materials including, but not limited to polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS), polycarbonate (PC), polyurethane (PU), polyethylene, polyethylene terephthalate, polypropylene, and polystyrene. Various manufacturing techniques may be used to fabricate the light source holder 1310 depending, in part, on the material used to form the light source holder 1310 including, but not limited to injection molding, blow molding, and 3D printing.
In some implementations, the heat sink may provide other connecting mechanisms to couple the trim 1600 to the heat sink.
As before, the ledge 1139 may be shaped to impart a compressive force that presses the heat sink 1100e and the trim 1600 together in order to reduce the thermal contact resistance between the annular portion 1146a and the base section 1612. The heat sink 1100e may also be formed from an electrically conductive material (e.g., aluminum) and a portion of the ledge 1139 may expose the electrically conductive material such that an electrical connection may be formed between the trim 1600 and the heat sink 1100e such that the trim 1600 is electrically grounded to the heat sink 1100e.
All parameters, dimensions, materials, and configurations described herein are meant to be exemplary and the actual parameters, dimensions, materials, and/or configurations will depend upon the specific application or applications for which the inventive teachings is/are used. It is to be understood that the foregoing embodiments are presented primarily by way of example and that, within the scope of the appended claims and equivalents thereto, inventive embodiments may be practiced otherwise than as specifically described and claimed. Inventive embodiments of the present disclosure are directed to each individual feature, system, article, material, kit, and/or method described herein.
In addition, any combination of two or more such features, systems, articles, materials, kits, and/or methods, if such features, systems, articles, materials, kits, and/or methods are not mutually inconsistent, is included within the inventive scope of the present disclosure. Other substitutions, modifications, changes, and omissions may be made in the design, operating conditions and arrangement of respective elements of the exemplary implementations without departing from the scope of the present disclosure. The use of a numerical range does not preclude equivalents that fall outside the range that fulfill the same function, in the same way, to produce the same result.
Also, various inventive concepts may be embodied as one or more methods, of which at least one example has been provided. The acts performed as part of the method may in some instances be ordered in different ways. Accordingly, in some inventive implementations, respective acts of a given method may be performed in an order different than specifically illustrated, which may include performing some acts simultaneously (even if such acts are shown as sequential acts in illustrative embodiments).
All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety.
All definitions, as defined and used herein, should be understood to control over dictionary definitions, definitions in documents incorporated by reference, and/or ordinary meanings of the defined terms.
The indefinite articles “a” and “an,” as used herein in the specification and in the claims, unless clearly indicated to the contrary, should be understood to mean “at least one.”
The phrase “and/or,” as used herein in the specification and in the claims, should be understood to mean “either or both” of the elements so conjoined, i.e., elements that are conjunctively present in some cases and disjunctively present in other cases. Multiple elements listed with “and/or” should be construed in the same fashion, i.e., “one or more” of the elements so conjoined. Other elements may optionally be present other than the elements specifically identified by the “and/or” clause, whether related or unrelated to those elements specifically identified. Thus, as a non-limiting example, a reference to “A and/or B”, when used in conjunction with open-ended language such as “comprising” can refer, in one embodiment, to A only (optionally including elements other than B); in another embodiment, to B only (optionally including elements other than A); in yet another embodiment, to both A and B (optionally including other elements); etc.
As used herein in the specification and in the claims, “or” should be understood to have the same meaning as “and/or” as defined above. For example, when separating items in a list, “or” or “and/or” shall be interpreted as being inclusive, i.e., the inclusion of at least one, but also including more than one, of a number or list of elements, and, optionally, additional unlisted items. Only terms clearly indicated to the contrary, such as “only one of” or “exactly one of,” or, when used in the claims, “consisting of” will refer to the inclusion of exactly one element of a number or list of elements. In general, the term “or” as used herein shall only be interpreted as indicating exclusive alternatives (i.e. “one or the other but not both”) when preceded by terms of exclusivity, such as “either,” “one of,” “only one of,” or “exactly one of” “Consisting essentially of” when used in the claims, shall have its ordinary meaning as used in the field of patent law.
As used herein in the specification and in the claims, the phrase “at least one,” in reference to a list of one or more elements, should be understood to mean at least one element selected from any one or more of the elements in the list of elements, but not necessarily including at least one of each and every element specifically listed within the list of elements and not excluding any combinations of elements in the list of elements. This definition also allows that elements may optionally be present other than the elements specifically identified within the list of elements to which the phrase “at least one” refers, whether related or unrelated to those elements specifically identified. Thus, as a non-limiting example, “at least one of A and B” (or, equivalently, “at least one of A or B,” or, equivalently “at least one of A and/or B”) can refer, in one embodiment, to at least one, optionally including more than one, A, with no B present (and optionally including elements other than B); in another embodiment, to at least one, optionally including more than one, B, with no A present (and optionally including elements other than A); in yet another embodiment, to at least one, optionally including more than one, A, and at least one, optionally including more than one, B (and optionally including other elements); etc.
In the claims, as well as in the specification above, all transitional phrases such as “comprising,” “including,” “carrying,” “having,” “containing,” “involving,” “holding,” “composed of,” and the like are to be understood to be open-ended, i.e., to mean including but not limited to. Only the transitional phrases “consisting of” and “consisting essentially of” shall be closed or semi-closed transitional phrases, respectively, as set forth in the United States Patent Office Manual of Patent Examining Procedures, Section 2111.03.
The present application is a Bypass Continuation Application of International Application No. PCT/US2020/050767, filed Sep. 14, 2020, entitled “MINIATURE LIGHTING MODULE AND LIGHTING FIXTURES USING SAME,” which claims priority to U.S. Provisional Application No. 63/045,250, filed Jun. 29, 2020, entitled “LIGHTING MODULE HAVING INSULATING ENCLOSURE AND ELECTRICALLY ISOLATED ELECTRICAL CONNECTOR AND DRIVER,” U.S. Provisional Application No. 63/016,215, filed Apr. 27, 2020, entitled “LIGHTING MODULE HAVING INSULATING ENCLOSURE AND ELECTRICALLY ISOLATED ELECTRICAL CONNECTOR AND DRIVER,” and U.S. Provisional Application No. 62/899,348, filed Sep. 12, 2019, entitled “LIGHTING MODULE HAVING INTEGRATED ELECTRICAL CONNECTOR AND SWITCH AND LIGHTING FIXTURES USING SAME.” Each of the aforementioned applications is incorporated by reference herein in its entirety.
Number | Date | Country | |
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63045250 | Jun 2020 | US | |
63016215 | Apr 2020 | US | |
62899348 | Sep 2019 | US |
Number | Date | Country | |
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Parent | PCT/US2020/050767 | Sep 2020 | US |
Child | 17318193 | US |