The present invention relates generally to luminaires. More specifically, the invention relates to a light emitting diode (LED) module that is used in a recessed luminaire.
LEDs offer benefits over incandescent and fluorescent lights as sources of illumination. Such benefits include high energy efficiency and longevity. To produce a given output of light, LEDs consume less electricity than incandescent or fluorescent lights. Additionally, on average, LEDs last longer than incandescent or fluorescent lights before failing.
The level of light a typical LED outputs depends upon the amount of electrical current supplied to the LED and upon the operating temperature of the LED. That is, the intensity of light emitted by the LED changes according to electrical current and LED temperature. Operating temperature also impacts the usable lifetime of LEDs.
As a byproduct of converting electricity into light, LEDs generate heat and raise the operating temperature, resulting in efficiency degradation and premature failure. Typically, a heat management system, such as a heat sink, is used in conjunction with the LEDs to facilitate maintenance of proper LED operating temperatures. Conventional LED-based recessed luminaires include a housing and a conventional LED module that is coupled within the housing. The conventional LED module includes a heat sink, a fastening device for facilitating coupling between the conventional LED module and the housing, and one or more LEDs. The housing includes a cavity formed therein and an opening at one end. The housing is installed within and above an aperture formed in a support structure, such as a ceiling, and oriented such that the opening faces a desired illumination area, such as a room. Typically, a space is formed around and between the lower exterior portion of the housing and the perimeter of the aperture. The opening is positioned in substantially the same plane as a lower surface of the support structure; however, the opening can be positioned in a different plane, such as slightly above the lower surface of the support structure.
The heat sink is installed and fitted within the cavity of the housing, generally using one or more fastening devices, such as torsion springs, and substantially occupies the entirety of the diameter of the cavity to maximize its heat removal performance. The conventional LED module is designed to fit within a housing having an opening with a certain nominal diameter. For example, one conventional LED module is designed to fit within a housing having a six inch nominal diameter opening, while a different conventional LED module is designed to fit within a different housing having a five inch nominal diameter opening. Thus, the conventional LED module typically is not designed to flexibly fit within housings having differently sized nominal diameter openings. The LEDs are typically coupled to a substrate, which is in thermal communication with the heat sink. The LEDs emit light and are oriented in a manner such that the light is directed to the desired illumination area through the opening.
Conventional LED-based recessed luminaires can also include a trim ring. The trim ring is positioned adjacent to the opening and covers the opening. The trim ring typically is separably coupled to the heat sink or to a portion of the housing, generally by use of torsion springs, and is positioned so that at least a portion of the trim ring extends below the support structure and covers the space formed between the lower exterior portion of the housing and the support structure when viewed from an area below the support structure. The trim ring is thermally coupled to the heat sink; however, since the trim ring is separably coupled to either the heat sink or the housing, the amount of heat removal from the trim ring into the area below the support structure, or room area, is limited because the area of direct contact between the trim ring and the heat sink is reduced. Some conventional LED-based recessed luminaires also include a reflector. The reflector typically is separably disposed within the heat sink and surrounds the LEDs. The reflector directs light emitted from the LEDs toward the opening. Conventional LED-based recessed luminaires having several separably coupled components increase costs related to tooling costs and assembly costs.
A light module can include a heat sink and one or more light sources. The heat sink can include an internal surface surrounding a heat sink cavity formed therein. The internal surface can include a mounting region, a reflector region, and a decorative region. The reflector region can extend from the perimeter of the mounting region to a distal end. The decorative region can extend from the distal end to a second distal end. The light sources can be coupled to the mounting region within the heat sink cavity.
Another exemplary embodiment includes a light module that can include a heat sink, one or more light sources, and at least one mounting pad. The heat sink can include an internal surface surrounding a heat sink cavity formed therein. The light sources can be coupled to a portion of the internal surface of the heat sink cavity. The mounting pad can be coupled circumferentially around a portion of the heat sink. Each mounting pad can include a coupling hole, a first locator, and a second locator. The second locator can be positioned closest to an interior portion of the heat sink. The first locator can be positioned between the second locator and the coupling hole.
Another exemplary embodiment includes a light module. The light module can include a heat sink, one or more LED packages, and at least one mounting pad. The heat sink can include an internal surface surrounding a heat sink cavity formed therein. The internal surface can include a mounting region, a reflector region, and a decorative region. The reflector region can extend from the perimeter of the mounting region to a distal end. The decorative region can extend from the distal end to a second distal end. The LED package can be coupled to a portion of the internal surface of the heat sink cavity. The mounting pad can be disposed circumferentially around a portion of the heat sink. Each mounting pad can include a coupling hole, a first locator, and a second locator. The coupling hole, the first locator, and the second locator are radially and linearly aligned with one another. The second locator can be positioned closest to an interior portion of the heat sink. The first locator can be positioned between the second locator and the coupling hole.
For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following description, in conjunction with the accompanying figures briefly described as follows:
The drawings illustrate only exemplary embodiments of the invention and are therefore not to be considered limiting of its scope, as the invention may admit to other equally effective embodiments.
Exemplary embodiments of the present invention are directed to luminaires. The term “luminaire,” as used herein, generally refers to a system for producing, controlling, and/or distributing light for illumination. For example, a luminaire includes a system that outputs or distributes light into an environment, thereby allowing certain items in that environment to be more visible. Such a system could be a complete lighting unit that includes one or more LEDs, or LED packages, for converting electrical energy into light, sockets, connectors, or receptacles for mechanically mounting and/or electrically connecting components to the system, optical elements for distributing light, and mechanical components for supporting or attaching the luminaire. Luminaires are sometimes referred to as “lighting fixtures” or as “light fixtures.” A lighting fixture that has a socket for a light source, but no light source installed in the socket, is still considered a luminaire. That is, a lighting system lacking some provision for full operability still fits the definition of a luminaire. Luminaires are used in indoor or outdoor applications.
The invention may be better understood by reading the following description of non-limiting, exemplary embodiments with reference to the attached drawings, wherein like parts of each of the figures are identified by like reference characters, and which are briefly described as follows.
The heat sink 110 is formed as a single component and includes a first portion 111, a second portion 121 positioned below the first portion 111, one or more mounting pads 130, a trim ring 140, and a cavity 135 formed therein. The exemplary mounting pads 130 are positioned at different circumferential positions around the second portion 121. The exemplary trim ring 140 extends radially outward from a second end 124 of the second portion 121. The exemplary cavity 135 is surrounded by an internal surface 139 of the heat sink 110.
The first portion 111 extends a first longitudinal length 112 and includes one or more fins 118. The fins 118 extend from an interior portion 113 of the first portion 111 to an outer vertical periphery of the first portion 111. These fins 118 are viewable from the exterior of the heat sink 110 according to certain exemplary embodiments. According to one exemplary embodiment, the fins 118 are integrally formed with the interior portion 113 during casting of the heat sink 110. Alternatively, the fins 118 are coupled to the interior portion 113 of the first portion 111 subsequent to fabrication of the interior portion 113 using welding, fasteners or other methods known to people having ordinary skill in the art. According to one exemplary embodiment, the fins 118 extend substantially the entire first longitudinal length 112. Alternatively, the fins 118 extend a portion of the first longitudinal length 112. In yet another exemplary embodiment, one or more of the fins 118 extend at least a portion of the first longitudinal length 112 and also extend along at least a portion of the outer perimeter of the second portion 121. The fins 118 extend substantially radially around the first portion 111 forming gaps 119 between adjacently positioned fins 118. In other exemplary embodiments, the fins 118 extend substantially parallel to one another, also forming gaps 119 between adjacent fins 118. These fins 118 provide for an increase in exterior surface area of the first portion 111, thereby allowing the first portion 111 to release more of the heat generated by the LED packages 250 (
The second portion 121 is positioned generally below the first portion 111 and extends a second longitudinal length 122. The second portion 121 includes a first end 123, a second end 124, and a sidewall 125. In certain exemplary embodiments, the first end 123 has a smaller perimeter than the second end 124. In alternative embodiments, the first end 123 has a perimeter that is equal to or greater than the second end 124. The side wall 125 extends from the first end 123 to the second end 124. The second portion 121 also includes a top surface 126 that is located at the first end 123 and between lower portions of adjacent fins 118. The second end 124 defines an opening 127 that extends within the heat sink 110 to form the cavity 135 therein. According to some exemplary embodiments, the second portion 121 is integrally fabricated with the first portion 111 as a single component. The second portion 121 is fabricated using a thermally conductive, rigid material, such as a polymer, metal, or metal alloy. One example of the material used to fabricate the second portion 121 is aluminum.
In certain exemplary embodiments, the mounting pads 130 are substantially “L” shaped and extend along a portion of the top surface 126 in a raised manner. However, in alternative embodiments the mounting pads 130 are not raised. According to some exemplary embodiments, a portion of each mounting pad 130 also extends along at least a portion of the sidewall 125. In one exemplary embodiment, four mounting pads 130 disposed circumferentially along the second portion 121. However, in other exemplary embodiments, there are fewer or greater numbers of mounting pads 130 disposed circumferentially along the second portion 121. These exemplary mounting pads 130 allow coupling the LED module 100 to the housing using the fastening devices 160, which is described in further detail below with reference to
As previously mentioned, a portion of the cavity 135 is surrounded by the internal surface 139 which extends within the interior of the heat sink 110. The cavity 135 is formed during the casting process of the heat sink 110 according to certain exemplary embodiments. Alternatively, the cavity 135 is formed by machining into at least a portion of the second end 124 of the heat sink's second portion 121, or by other methods known to people having ordinary skill in the art. The internal surface 139 includes a mounting region 136, a first region 137, and a second region 138. The mounting region 136 is located within the first portion 111 of the heat sink 110 and is substantially planar according to some exemplary embodiments. The mounting region 136 is oriented substantially parallel to the opening 127 and faces the desired illumination area. According to certain exemplary embodiments, the mounting region 136 is circular in shape. Alternatively, the mounting region 136 is shaped into other geometric or non-geometric shapes.
In certain exemplary embodiments, the first region 137 and the second region 138 collectively form a parabolic shape extending from the perimeter of the mounting region 136 to the perimeter of the opening 127. The first region 137 includes a proximal end 145 and a distal end 146, wherein the diameter of the distal end 146 is greater than the diameter of the proximal end 145. However, according to other exemplary embodiments, the diameter of the distal end 146 is smaller than or equal to the diameter of the proximal end 145 in other exemplary embodiments. The proximal end 145 is disposed around the perimeter of the mounting region 136 and the distal end 146 extends outwardly towards the opening 127. The first region 137 is fabricated to be reflective and facilitate directing light emitted from the LED packages 250 (
The second region 138 includes the distal end 146 of the first region and a second distal end 147, wherein the diameter of the second distal end 147 is greater than the diameter of the distal end 146. According to other exemplary embodiments, the diameter of the second distal end 147 is smaller than or equal to the diameter of the distal end 146. The second distal end 147 extends to the opening 127 and defines the opening 127. In some examples, the surface of the second region 138 is baffled. In another example, the surface of the second region 138 is smooth. In yet another example, the surface of the second region 138 includes at least one of a faceted surface, a prismatic surface, a dimpled surface, and a painted surface. The second region 138 is fabricated using the same material as that used to fabricate the first region 137, but is finished similarly or differently than the finishing of the first region 137 depending upon design choices.
The trim ring 140 extends radially outward from the second end 124 of the heat sink's second portion 121 and includes a top surface 141 and a bottom surface 142. The trim ring 140 is typically positioned just below the plane of the opening 127. In certain exemplary embodiments, the trim ring 140 is integrally formed with the remaining portions of the heat sink 110. Once the LED module 100 is installed into the housing, the bottom surface 142 of the trim ring 140 is oriented to face the desired illumination area and is observable to one present within the desired illumination area. Also, once the LED module 100 is installed within the housing, the trim ring 140 conceals the space formed around and between the lower exterior portion of the housing and the perimeter of the aperture formed within the support structure. In certain exemplary embodiments, the trim ring 140 is fabricated using a thermally conductive material, such as a polymer, metal, or metal alloy. One example of the material used to fabricate the outer trim ring 140 is aluminum. In the exemplary embodiments where the trim ring 140 is integrally formed with at least the second portion 121, the heat transfer from the second portion 121 to the trim ring 140 is improved because the trim ring 140 is always in constant contact around the entire circumference of the second portion 121. At least a portion of the heat from the heat sink 110 is released into the desired illumination area using the pathway from the second portion 121 of the heat sink 110 to the trim ring 140 and to the desired illumination area.
The heat sink 110 is described as including several components, such as the first portion 111, the second portion 121, one or more mounting pads 130, and the trim ring 140. Each of the components are integrally formed with one another according to several exemplary embodiments; however, some exemplary embodiments have at least one component separately fabricated and thereafter coupled to the remaining portions of the integrally formed heat sink 110. For example, the fins 118 are separately formed and thereafter coupled to the interior portion 113 of the first portion 111 according to some exemplary embodiments. The heat sink 110 is fabricated using a thermally conductive, rigid material, such as a polymer, metal, or metal alloy. One example of the material used to fabricate the heat sink 110 is aluminum. The material used to form some portions of the heat sink 110 is finished differently than another portion of the heat sink 110 according to some exemplary embodiments. For example, at least a portion of the internal surface's first region 137 is polished to be made more reflective according to some exemplary embodiments.
As previously mentioned, the exemplary LED module 100 includes the driver 170. The driver 170 includes circuitry for controlling one or more LED packages 250 (
As previously mentioned, the LED module 100 also includes one or more chip on board LEDs 250 (
The wavelength or color of the emitted light depends on the materials used to make the LED or LED package 250 (
In certain exemplary embodiments, an optically transmissive or clear material (not shown) encapsulates at least a portion of each LED or LED package 250 (
In certain exemplary embodiments, the LED is an LED package 250 (
The LED packages 250 (
As previously mentioned, the exemplary LED module 100 includes the gasket 180. The exemplary gasket 180 is ring-shaped and includes an inner perimeter 181, and outer perimeter 182, an upper surface 183, and a lower surface (not shown). In alternative embodiments, the gasket 180 is shaped in other geometric or non-geometric shapes. The inner perimeter 181 is substantially equal to or larger than the outer perimeter of the second portion's second end 124. The outer perimeter 182 is substantially equal to or smaller than the outer perimeter of the trim ring 140. The gasket 180 is typically disposed on the top surface 141 of the trim ring 140 such that the gasket's lower surface (not shown) is in contact with the trim ring's top surface 141. Once the LED module 100 is inserted into the housing's cavity, at least a portion of the gasket 180, if included within the LED module 100, is disposed between at least a portion of the trim ring's top surface 141 and the surface of the support structure. The exemplary gasket 180 is fabricated using a foam material. However, other suitable materials, such as a rubber and other polymer materials, are suitable for manufacturing the gasket 180 in other exemplary embodiments.
The exemplary LED module 100 also includes the lens 190. The lens 190 is coupled to substantially the distal end 146 of the internal surface's first region 137. According to some exemplary embodiments, the lens 190 is coupled to the distal end 146 using clips (not shown). Alternatively, other devices, such as screws or using the baffles as support, are used to couple the lens 190 in place. Furthermore, in certain alternative embodiments, the lens 190 is positioned either above or below the distal end 146. In certain exemplary embodiments, the lens 190 is fabricated using a transparent or translucent material, such as glass or plastic, which allows light generated from the LED packages 250 (
The exemplary LED module 100 also includes fastening devices 160 adjustably coupled to the mounting pads 130. The fastening devices 160, in conjunction with the mounting pads 130, facilitate the adjustable coupling of the LED module 100 into housings having different cavity diameter sizes. Each fastening device 160 includes a mounting bracket 162 and a torsion spring 163 coupled to the mounting bracket 162. Torsion springs 163 are known to people having ordinary skill in the art and are used for coupling the LED module 100 to an interior wall surrounding the cavity formed within the housing (not shown). The torsion spring 163 includes a ring portion 164, a first rod 165 extending from the ring portion 164 in a first direction, and a second rod 166 extending from the ring portion 164 in a second direction. As the first rod 165 is moved closer to the second rod 166, the first and second rods 165, 166 produce a biasing effect which, once coupled within a torsion spring receiver (not shown) in the housing, facilitates coupling of the LED module 100 into the housing's cavity, which is known to people having ordinary skill in the art. The fastening device 160 is coupled to the mounting pad 130 using a coupling device 206 (
Referring to
The second portion 320 extends longitudinally from the first end 312 to an opposing end 322. The second portion 320 includes a torsion spring bracket 324, which facilitates coupling the torsion spring 163 to the second portion 320. The torsion spring bracket 324 is formed by cutting through an interior portion of the second portion 320 and pushing a portion of the second portion 320, which forms the torsion spring bracket 324, into a different plane that is at an angle with the plane that the rest of the second portion 320 resides. The plane in which the torsion spring bracket 324 resides intersects with the first portion 310 according to some exemplary embodiments.
The exemplary tab 330 is substantially planar and extends longitudinally from a portion of the second end 314 to a distal end 332. In certain exemplary embodiments, the tab 330 extends substantially from the middle of the second end 314. The tab 330 extends in a plane that is substantially parallel to the plane of the second portion 320. The exemplary mounting bracket 162 is fabricated as a single component, but can alternatively be fabricated in several components and thereafter assembled together. The mounting bracket 162 is fabricated using a polymer material, metal, metal alloy, or other suitable materials known to people having ordinary skill in the art.
Referring to
Referring to
The fastening device 160 is coupled to the mounting pad 130 by positioning the mounting bracket's first portion 310 above and substantially parallel to the mounting pad's first portion 450 and the mounting bracket's second portion 320 adjacent and substantially parallel to the mounting pad's second portion 460. According to one exemplary embodiment, the tab 330 is inserted into the second locating hole 453 and the coupling device 206 is inserted through the slot 316 and into the coupling hole 454. Thus a portion of the coupling device 206 rests above the mounting bracket's first portion 310, while a portion of the coupling device 206 is inserted and coupled within the coupling hole 454. When the tab 330 is inserted into the second locating hole 453, the LED module 100 fits within a housing having a certain nominal diameter cavity. However, if the LED module 100 is to be fitted within a housing having a smaller nominal diameter cavity, the coupling device 206 is loosened so that the tab 330 is removed from the second locating hole 453 and moved into the first locating hole 452. When moving the tab 330 from the second locating hole 453 to the first locating hole 452, the mounting bracket 162 is moved closer to the interior portion 113 by sliding the coupling device 206 along the length of the slot 316. Once the tab 330 is inserted into the first locating hole 452, the coupling device 206 is securely re-coupled into the coupling hole 454. Alternatively, instead of loosening the coupling device 206, the coupling device 206 is removed when adjusting the position of the mounting bracket 162. Thus, the LED module 100 is capable of being installed within different housings having different nominal diameter cavities.
Although one example has been provided for achieving this flexibility, this flexibility is achievable in different manners, all of which are encompassed within the several exemplary embodiments. For instance, instead of a slot 316 formed into the first portion 310 of the mounting bracket 162, two or more openings (not shown) are formed into the first portion 310 of the mounting bracket 162 in other exemplary embodiments. Each of these openings are capable of receiving the coupling device 206 therethrough. In another example, instead of locating holes 452, 453 formed into the mounting pad's first portion 450, bosses (not shown) are formed in the same locations as the locating holes 452, 453 and openings (not shown) are formed into the first portion 310 of the mounting bracket 162 such that at least one opening fits onto and surrounds one of the bosses. The bosses are formed to extend above the top surface of the mounting pad's first portion 450. In yet another example, instead of a slot 316 formed into the first portion 310 of the mounting bracket 162, at least one opening (not shown) is formed into the first portion 310 of the mounting bracket 162 and a portion of the heat sink 110 includes one or more receiving holes (not shown) such that the coupling device 206 couples the mounting bracket 162 to the heat sink 110 by being inserted into the receiving hole through the opening on the mounting bracket 162.
Although the invention has been described with reference to specific embodiments, these descriptions are not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternative embodiments of the invention will become apparent to persons of ordinary skill in the art upon reference to the description of the exemplary embodiments. It should be appreciated by those of ordinary skill in the art that the conception and the specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures or methods for carrying out the same purposes of the invention. It should also be realized by those of ordinary skill in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims. It is therefore, contemplated that the claims will cover any such modifications or embodiments that fall within the scope of the invention.
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