The present disclosure is related to a recessed light fixture with a rotatable trim.
Recessed light fixtures are designed to be minimally visible from below a ceiling, e.g., a ceiling-board, in which they are mounted. LED light sources used for recessed lighting typically generate significant quantities of heat, requiring the use of a heat sink as part of the light fixture, to avoid overheating. The LED light source and an associated reflector, referred to as the optic, are typically mounted in the heat sink, such as a canister, or “can,” type housing, so as to project light from the bottom of the heat sink. In some designs, the heat sink may be supported in a mounting frame that is suspended by bar hangers fastened between joists above the ceiling. The mounting frame is positioned so that the bottom of the heat sink passes through a ceiling opening (e.g., a cut out in the ceiling board) and is approximately flush with the bottom, exterior surface (e.g., a room-side surface) of the ceiling. A trim, which includes a trim frame (e.g., a trim ring), can be used to surround the opening in the ceiling, and mask the ceiling opening cut-out.
In some recessed light fixtures, the heat sink and the trim are distinct pieces which are separately assembled and installed onto the ceiling. For example, the heat sink is first installed onto the ceiling. The heat sink can include a lip that extends over edges around the ceiling opening against the bottom of the ceiling. The lip of the heat sink acts as a stop that does not allow the heat sink to continue to be pushed up into the ceiling cavity through the ceiling opening. The trim is thereafter installed onto the ceiling to cover the lip of the heat sink. Accordingly, the installation of these types of a recessed light fixture is complex and time consuming, and can adversely impact cosmetic aspects of the recessed light fixture when installed onto the ceiling. For example, the lip of the heat sink causes the trim to be displaced farther away from the bottom, exterior surface of the ceiling, and may require the use of a trim with sufficient thickness to mask the lip and other components of the heat sink. Further, the trim is not independently rotatable in the canister-type heat sink.
To address these and other shortcomings, an improved recessed light fixture is provided, which incorporates a simple, yet effective snap-on spring assembly to connect the heat sink and the trim together while allowing rotational adjustment of the trim relative to the heat sink. The heat sink and trim can be mounted in the ceiling as a single unit or module, which simplifies installation. Furthermore, by allowing the trim and heat sink to be assembled into a single unit or module, the improved light fixture eliminates the need for a lip on the heat sink because the trim can act as a stop against the ceiling when mounting the heat sink and the trim onto the ceiling. As a consequence, the trim can be designed to further enhance cosmetic aspects of the recessed light fixture. For example, the trim can be designed with a thinner profile. The trim can also sit closer to the ceiling in comparison to known light fixtures, such as those previously discussed above, which employ a separate heat sink assembly and trim assembly.
An exemplary recessed light fixture can include a trim, heat sink, fasteners and springs. The trim has a trim frame with a trim opening for a light source, such as an LED light module or engine. The heat sink includes an open end which opens into a cavity to house a portion of the lighting source, and an interior surface with an interior groove that extends circumferentially around the interior surface. Each spring has a first end and an opposing second end. The first end of the springs is connected to the trim frame with a fastener such as a bolt or screw. The second end of the springs is inserted through the open end of the heat sink until the second end of the springs snaps into and engages the interior groove to connect the heat sink and the trim frame. The second end is movable along the interior groove to allow rotational adjustment of the trim frame relative to the heat sink. The fasteners can be detached to release the first end of the springs from the trim, which allows disengagement of the trim from the heat sink.
The heat sink along with the trim can be mounted in a ceiling opening of a room using a mounting frame, with the trim frame being flush against or proximate to an exterior surface of the ceiling. The trim frame, which can be rectangular (e.g., square), can thereafter be rotatably adjusted for cosmetic purposes to align the trim frame relative to other aspects in the room, such as the side walls. Furthermore, the adjustability of the trim frame is particularly useful for “wall wash” lighting applications, to align a plurality of wall wash trims or gimbal trims to project light onto a wall surface in a desired fashion.
The description of the various exemplary embodiments is explained in conjunction with the appended drawings, in which:
The present disclosure is directed to a recessed light fixture with a rotatable trim. The recessed light fixture includes a heat sink (e.g., within or as part of a canister housing) and a trim with a trim frame, which are connected together into a single unit or module using a snap-on spring assembly to allow rotational adjustment of the trim relative to the heat sink. The heat sink and the trim are together mountable onto a wall through a wall opening via a mounting frame. The trim is rotatable to a desired orientation to align the trim with other objects in a room (e.g., room side walls, and other light fixture trims) for cosmetic purposes, or to facilitate wall washing when using a wall wash trim or gimbal trim. An example of the recessed light fixture is described in greater detail below with reference to the figures.
Specifically, in this example, the trim 110 includes a trim frame 112 with a first side 114, a second side 116 opposite the first side 114, and a trim opening 118 located in a center of the trim frame. The trim 110 is a gimbal trim, which includes a gimbal 130 with a light source 132. The gimbal 130 with the light source 132 is arranged in the trim opening 118 to pivot around an axis 136, which allows rotational adjustment to different angular positions. For example, the light source 130 is adjusted to vertical in
As further shown in
The heat sink 170 is a canister-style housing, which houses at least a portion of some of the lighting components of the light fixture 100, such as, for example, the gimbal 130 with the light source 132, inner heat sink 134, and so forth. The heat sink 170 includes an open end 172, which opens into a substantially cylindrical cavity 174 that is defined by an interior surface 176. The heat sink 170 further includes a groove 180, which extends circumferentially around the interior surface 176 at a position proximate to the open end 172. In this example, the groove 180 runs continuously around the interior surface 176; however, the groove 180 can instead comprise of a plurality of discontinuous grooves for each spring 150.
Each of the springs 150 includes a first end 152, and a second end 154 which is opposite the first end 152. The first end 152 is connectable onto the outer side surface 124 of the raised rim 120, using a respective fastener 140 which extends through the first end 152 and is secured into one of the fastener openings 127. In this example, two springs 150 are connected at opposite locations on the raised rim 120. Between the first and second ends 152 and 154, there is also a portion 156 which is configured to extend into and through a respective spring channel 128 so that the second end 154 is insertable into the cavity 174 of the heat sink 170. As shown, the second end 154 of each of the springs 150 extends away from the top surface of the raised rim 120 when the first end 152 of the springs 150 are connected to the raised rim 120.
To connect the trim 110 to the heat sink 170, the second end 154 of the springs 150 are inserted into the cavity 174 of the heat sink until they snap into and engage the interior groove 180 of the heat sink. The second end 154 of the springs is movable along the interior groove to allow rotational adjustment of the trim frame relative to the heat sink. The second end 154 can have a male element, which is configured with a shape and dimension to engage the groove 180, which is a female element. In this example, the second end 154 of the spring 150 has an angular portion that is bent at an acute angle to engage the groove 180. The interior groove 180 has cross-sectional area, which tapers as the interior groove 180 extends outwards from the interior surface 174 toward and an exterior surface 178 of the heat sink 170. When engaged in the interior groove 180 of the heat sink 170, the angular portion of the second end 154 extends into the interior groove 180 of the heat sink 170 to prevent disengagement of the heat sink 170 from the second end 154 of the spring 150.
As shown in
At reference 310, the first end 152 of each spring 150 is connected to the raised rim 120 of the trim frame 112 using a respective fastener 140. At reference 320, the heat sink 170 is connected to the trim frame 112 by inserting the second end 154 of each spring 150 through the open end 172 of the heat sink 170 until the second end 154 snaps into and engages the interior groove 180 of the heat sink 170. The second end 154 of the springs 150 initially deflect to allow insertion of the second end 154 through the open end 172 of the heat sink 170.
At reference 330, the heat sink 170 and the trim 110 is mounted onto a wall (e.g., a ceiling board) by inserting the heat sink 170 through a wall opening in the wall until the heat sink 170 is secured to a mounting frame and the trim frame 112 is flush with or proximate to a room side surface of the wall. Thereafter, at reference 340, the trim 110 can be rotatably adjusted relative to the heat sink 170 (e.g., the stationary components of the mounted heat sink 170) to a desired orientation, such as for cosmetic purposes. For example, the trim 110 can be rotated to align the trim frame with other objects in a room (e.g., trims of other light fixtures, walls or other objects) or to orient a direction of a light from the light source 132 against a wall for wall washing purposes which may entail the use of multiple recessed light fixtures 100.
The recessed light fixture, as described herein, is simply provided as an example of a light fixture with an independently adjustable trim. The spring and the interior groove of the heat sink can be designed with any suitable shape and dimension, to provide for snap-on connection of the trim and the heat sink. The interior groove can be a continuous groove, or can comprise of a plurality of discontinuous grooves on the interior surface of the heat sink for each spring.
Instead of an interior groove, the heat sink can have an exterior groove on the exterior surface. Similar to the interior groove, the exterior groove can be arranged proximate to the open end of the heat sink and extend circumferentially around the exterior surface of the heat sink. The second end of the spring can be configured to snap into and engage the exterior groove to connect the heat sink and the trim. The spring can move along the exterior groove to allow rotational adjustment of the trim relative to the heat sink.
Furthermore, instead of a groove on the heat sink, the trim can have an interior or exterior groove which extends circumferentially around the interior or exterior surface, respectively, of the trim (e.g., the raised rim of the trim frame). Each spring has a first end fastened to the heat sink via a fastener, and a second end configured to snap into and engage the groove to connect the heat sink and the trim. The spring can move along the groove to allow rotational adjustment of the trim relative to the heat sink.
Words of degree, such as “about”, “substantially”, and the like are used herein in the sense of “at, or nearly at, when given the manufacturing, design, and material tolerances inherent in the stated circumstances” and are used to prevent the unscrupulous infringer from unfairly taking advantage of the invention disclosure where exact or absolute figures and operational or structural relationships are stated as an aid to understanding the invention.
While particular embodiments and applications of the present disclosure have been illustrated and described, it is to be understood that the present disclosure is not limited to the precise construction and compositions disclosed herein and that various modifications, changes, and variations can be apparent from the foregoing descriptions without departing from the invention.
The present application claims priority under 35 U.S.C. §119(e) based on U.S. Provisional Application Ser. No. 61/934,966 filed on Feb. 3, 2014, which is incorporated by reference herein in its entirety.
Number | Name | Date | Kind |
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4356540 | Goralnik | Oct 1982 | A |
6632006 | Rippel | Oct 2003 | B1 |
6655813 | Ng | Dec 2003 | B1 |
7654705 | Czech | Feb 2010 | B2 |
8096670 | Trott | Jan 2012 | B2 |
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8403533 | Paulsel | Mar 2013 | B1 |
Number | Date | Country | |
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20150219296 A1 | Aug 2015 | US |
Number | Date | Country | |
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61934966 | Feb 2014 | US |