Patent Grant
11118761
A portion of the disclosure of this patent document contains material that is subject to copyright protection. The copyright owner has no objection to the reproduction of the patent document or the patent disclosure, as it appears in the U.S. Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.
This application claims the benefit under 35 USC. § 119(e) of U.S. Provisional Application No. 62/890,706, filed Aug. 23, 2019, entitled “End Cap Mounts to Secure Cable Without Leakage Paths,” which is hereby incorporated by reference in its entirety.
The present disclosure relates generally to lighting systems and, more particularly, to apparatuses to prevent entry of contamination into a light system.
Compact low-power lighting systems are becoming more commonplace for residential and office lighting as the costs for lighting systems based on light-emitting diodes (LEDs) decrease. Because of the small size of LED-based lighting systems, the LED-based lighting systems are more noticeably affected by contamination such as contamination from dust and moisture. Although LED-based lighting systems generally produce less heat than corresponding lighting systems based on other technologies, LED based lighting systems do produce heat such that an increased volume of heated air surrounding the lighting systems must be allowed to escape. Thus, a completely sealed LED-based lighting system may not be feasible.
A need exists for an LED-based lighting system that enables heated air surrounding an LED lighting source to escape while preventing entry of contaminants such as dust and moisture.
One aspect of the embodiments disclosed herein is an end cap mounting system for a lens of a lighting fixture. The end cap mounting system includes a lens engagement portion having a proximal end, a distal end, an outer surface and an inner surface. The inner surface defines a cavity extending distally into the lens engagement portion from the proximal end for a cavity depth to a cavity end surface. The cavity has an inner wall with a perimeter corresponding to a first asymmetric shape of an outer profile of a lens. A central protrusion extends proximally from the cavity end surface towards the proximal end. The protrusion has an outer wall with a perimeter that corresponds to a second asymmetric shape of an inner profile of the lens. A gasket-receiving recess is positioned proximate to the cavity end surface between the outer wall of the central protrusion and the inner wall of the cavity to receive a gasket.
Another aspect of the embodiments disclosed herein is an end cap mounting system for a lens of a lighting fixture in which the lens is elongated along a longitudinal axis. The lens has an outer surface having an outer profile along the longitudinal axis. The outer profile has a first asymmetric shape. The lens has a central bore along the longitudinal axis. The central bore forms an inner surface of the lens. The inner surface of the lens has an inner profile having a second asymmetric shape. The end cap mounting system comprises an end cap and an end cap mount. The end cap mount has a lens engagement portion and an end cap engagement portion. The end cap engagement portion extends distally from the lens engagement portion to engage the end cap. The lens engagement portion has a proximal end, a distal end, an outer surface and an inner surface. The inner surface defines a cavity extending distally into the lens engagement portion from the proximal end for a cavity depth to a cavity end surface. The cavity has an inner wall with a perimeter corresponding to the first asymmetric shape of the outer profile of the outer surface of the lens. A central protrusion extend\s proximally from the cavity end surface towards the proximal end of the lens engagement portion. The protrusion has an outer wall with a perimeter that corresponds to the second asymmetric shape of the inner profile of the inner surface of the lens. A first bore extends through the distal end of the lens engagement portion and through the central protrusion. A gasket-receiving recess is positioned proximate to the cavity end surface between the outer wall of the central protrusion and the inner wall of the cavity.
In certain embodiments in accordance with this aspect, a plurality of standoffs extend from the cavity end surface of the lens engagement portion. The standoffs are positioned between the outer wall of protrusion and the inner wall of the cavity. The gasket has openings to accommodate the plurality of standoffs.
In certain embodiments in accordance with this aspect, the end cap engagement portion of the end cap mount comprises an outer surface and a distal end surface. The outer surface supports a plurality of first engagement features protruding from the outer surface. The end cap engagement portion further comprises a central bore that extends through the end cap engagement portion and through the protrusion within the cavity. In certain embodiments, the end cap comprises a proximal portion and a distal portion. The proximal portion has an outer wall and an inner cavity. The inner cavity of the proximal portion of the end cap has an inner surface having a size selected to fit around the outer surface of the end cap engagement portion of the end cap mount. The outer wall of the proximal portion has a plurality of second engagement features. Each second engagement feature is positioned to engage one of the first engagement features of the end cap mount when the end cap is engaged with the end cap engagement portion of the end cap mount. In certain embodiments, each first engagement feature of the end cap mount comprises a protrusion extending radially outward from the outer surface of the distal end portion of the lens engagement portion; and each second engagement feature of the end cap comprises an opening through the outer wall of the proximal portion of the end cap, each opening aligned with a respective protrusion when the end cap is engaged with the lens engagement portion. In certain embodiments, a plurality of pairs of slits extend through the outer wall of the proximal portion of the end cap. Each pair of slits comprises a respective first slit and a respective second slit, wherein each slit extends to the proximal end of the outer wall, and wherein each second engagement feature is positioned between the respective first slit and the respective second slit in a respective pair of slits. Each pair of slits enables a respective portion of the outer wall between the respective first slit and the respective second slit in the pair to move outward away from the inner cavity of the end cap cover portion.
In certain embodiments, the end cap further comprises a distal portion. The distal portion has a distal end surface. The distal portion has a central bore that extends from the distal end surface to the inner cavity of the end cap. In certain embodiments, the distal portion of the end cap includes an outer wall surrounding the central bore, and a threaded bore extends radially inward through the outer wall to the central bore. In certain embodiments, a screw has external threads that engage the threaded bore of the end cap.
In certain embodiments, the end cap mounting system includes a cylindrical grommet having an outer diameter and having a central bore. The end cap engagement portion of the end cap mount includes a distal cavity. The distal cavity has a diameter sized to receive the cylindrical grommet and to position the cylindrical grommet within the central bore such that the cylindrical grommet is aligned with the central bore of the cap cover engagement portion.
In certain embodiments, the end cap mounting system further comprises a filter. The filter has an outer perimeter with a selected shape. The filter has a thickness. The end cap engagement portion of the end cap mount includes a distal recess having the selected shape and having a recess depth corresponding to the thickness of the filter. The filter is positioned in the recess. In certain embodiments, the filter comprises a microporous polytetrafluoroethylene (PTFE) membrane.
In certain embodiments, the end cap mounting system further comprises a gasket having a shape configured to fit into the gasket-receiving recess of the lens engagement portion. In certain embodiments, the gasket comprises a high viscosity adhesive that fills the gasket-receiving recess. In certain embodiments, the gasket comprises silicone rubber.
Another aspect of the embodiments disclosed herein is a lighting system. The lighting system comprises a lens holder having a longitudinally extending support surface. A first side wall and a second side wall extend from the support surface. Each side wall has a respective lens retention feature. A longitudinally extending lens is positionable within the lens holder. The lens has a first end and a second end. The lens has a first retention feature to engage the lens retention feature of the first side wall and a second retention feature to engage the lens retention feature of the second side wall. The lens further includes a printed circuit board receiving recess. A printed circuit board comprises a plurality of light-emitting diodes (LEDs). The printed circuit board is positioned in the printed circuit board receiving recess of the lens. A first end cap mounting assembly is positioned on the first end of the lens. The first end cap mounting assembly comprises a first lens cap mount. The first end cap mount comprises a first lens engagement portion having a first cavity surrounded by a first cavity wall. The first lens engagement portion receives a portion of the first end of the lens within the first cavity. The first lens engagement portion includes a first lens engagement portion central bore extending into the first cavity. A grommet is positioned within the first lens engagement portion central bore. The grommet has a grommet central bore. A first end cap engagement portion extends from the second lens engagement portion. A first end cap is positioned over a distal end of the first end cap engagement portion of the first end cap mount. The first end cap has a first end cap central bore aligned with the first lens engagement portion central bore. A second end cap mounting assembly is positioned on the second end of the lens. The second end cap mounting assembly comprises a second end cap mount. The second end cap mount comprises a second lens engagement portion having a second cavity surrounded by a second cavity wall. The second lens engagement portion receives a portion of the second end of the lens within the second cavity. The second lens engagement portion includes a second lens engagement portion central bore extending into the second cavity. A filter is positioned over the second lens engagement portion central bore. A second end cap engagement portion extends from the second lens engagement portion. A second end cap is positioned over the second end cap engagement portion of the second end cap mount. The second end cap has a second end cap central bore aligned with the central bore of the first end cap mount. An electrical cable is positioned through the first end cap central bore, through the grommet central bore and through the first lens engagement portion central bore. The electrical cable has at least first and second conductors engaged with the printed circuit board.
In certain embodiments in accordance with this aspect, the first end cap and the second end cap are identical.
In certain embodiments in accordance with this aspect, a first gasket is positioned within the first cavity of the first lens engagement portion with the first gasket positioned against the first end of the lens. A second gasket is positioned within the second cavity of the second lens engagement portion with the second gasket positioned against the second end of the lens.
In certain embodiments in accordance with this aspect, a portion of the first cavity wall of the first lens engagement portion has a first peripheral opening positioned to enable light from a portion of the first end portion of the lens to pass through the first peripheral opening; and a portion of the second cavity wall of the second lens engagement portion has a second peripheral opening positioned to enable light from a portion of the second end portion of the lens to pass through the second peripheral opening.
In certain embodiments in accordance with this aspect, the lens has an outer surface having an outer asymmetric profile and has an inner surface having an inner asymmetric profile. The first cavity of the first lens engagement portion has an inner surface with an inner profile matching the outer asymmetric profile of the lens. A first protrusion extends proximally within the first cavity. The first protrusion has an outer surface with an outer profile matching the inner asymmetric profile of the lens. The second cavity of the second lens engagement portion has an inner surface with an inner profile matching the outer asymmetric profile of the lens. A second protrusion extends proximally within the second cavity. The second protrusion has an outer surface with an outer profile matching the inner asymmetric profile of the lens. When viewed from the respective proximal ends of the first lens engagement portion and the second lens engagement portion, the inner profile of the first cavity and the inner profile of the second cavity are mirror images of each other, and the outer profile of the first protrusion and the outer profile of the second protrusion are mirror images of each other.
The following detailed description of embodiments of the present disclosure refers to one or more drawings. Each drawing is provided by way of explanation of the present disclosure and is not a limitation. Those skilled in the art will understand that various modifications and variations can be made to the teachings of the present disclosure without departing from the scope of the disclosure. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment.
The present disclosure is intended to cover such modifications and variations as come within the scope of the appended claims and their equivalents. Other objects, features, and aspects of the present disclosure are disclosed in the following detailed description. One of ordinary skill in the art will understand that the present discussion is a description of exemplary embodiments only and is not intended as limiting the broader aspects of the present disclosure.
The lighting structure 100 includes a longitudinally disposed lens 120 having a first (left) end 122 and a second (right) end 124. The lens includes a cavity 126 that extends longitudinally through the lens from the first end to the second end. As used herein “left,” “right,” “top,” “bottom,” “upper,” “lower” and like positional adjectives refer to the positioning of elements in the drawing figures and are not intended to suggest any positioning of the elements in an actual embodiment. For example, a physical lighting structure may be rotated to any position and operate as described herein.
The cavity 126 of the lens 120 receives and encloses a printed circuit board (PCB) 130. The PCB supports a plurality of light-emitting diodes (LEDs) 132 and supporting electronic components 134.
A longitudinally disposed mounting bracket (or rail) 140 is positioned on the lens 120. The mounting bracket has a first end 142 and a second end 144.
A first (left) end cap mount 150 is mounted on a portion of the lens 120 near the first end 122 of the lens. The first end cap mount has a proximal end 152 and a distal end 154. A through bore 156 extends through the first end cap mount.
A second (right) end cap mount 160 is mounted on a portion of the lens near the second end of the lens. The second end cap mount has a proximal end 162 and a distal end 164. A through bore 166 extends through the second end cap mount.
As used herein, “proximal end” refers to the end of the respective end cap mount 150, 160 nearer the lens 120, and “distal end” refers to the end of the respective end cap mount facing away from the lens. Accordingly, the proximal ends of the two end cap mounts face towards each other.
A first (left) end cap 170 is mounted on the first end cap mount 150. A proximal end 172 of the first end cap faces toward the first end cap mount and engages the first end cap mount. A distal end 174 of the first end cap faces away from the first end cap mount. The first end cap includes a central through bore 176 that extends longitudinally through the first end cap. When assembled as shown in
A second (right) end cap 180 is mounted on the second end cap mount 160. A proximal end 182 of the second end cap faces toward the second end cap mount and engages the second end cap mount. A distal end 184 of the second end cap faces away from the second end cap mount. The second end cap includes a central through bore 186 that extends longitudinally through the first end cap. When assembled as shown in
As shown in
As shown in
As shown in
A wiring assembly 260 includes a connector 262 and a two-wire cable 264. A portion of the two-wire cable extends through the central through bore 176 of the first end cap 170, extends through the through bore 222 of the cable-sealing grommet 220 and extends through the through bore 156 of the first end cap mount 150. The two-wire cable extends into the cavity 126 of the lens 120. A first conductor 266 and a second conductor 268 of the two-wire cable are electrically connected to the PCB 130 to provide power to the LEDs 132 on the PCB. The two-wire cable is secured within the through bore of the first end cap by a set screw 270, which is threaded into the axial bore 178 of the first end cap.
As shown in
The lens 120 includes a base portion 310 opposite the emission surface 302 and the emission structure 304. A first mounting ledge 312 and a second mounting ledge 314 extend from the base portion. As shown in
As shown in
As further shown in
As shown in
As further shown in
The first cap mount 150 is shown in more detail in
The distal portion of the first end cap mount 150 includes a grommet-receiving recess 410 that receives the cable-sealing grommet 220 as shown in the cross-sectional view of
The proximal lens engagement portion 400 of the first end cap mount 150 has an inner cavity 420 defined by a profile that has a size and shape generally corresponding to the outer profile 300 of the lens 120 as shown in
As shown in
As further shown in
As further shown in
The first gasket sealing gasket 200 is formed by filling the gasket-receiving recess 458 with the silicone adhesive such as Dow Corning Dowsil™ SE 9186 clear silicone adhesive, which is commercially available from the Dow Chemical Company of Midland, Mich. The silicone adhesive is inserted into the recess as a high viscosity liquid and cures to form a permanent gasket. The four lens standoff pads 450, 452, 454, 456 assist in defining the shape of the gasket. The four lens standoff pads also prevent the gasket from being compressed too far when the first end cap mount 150 is inserted over the first end portion 352 of the lens 120 so that the gasket maintains a minimum thickness of approximately 0.02 inch.
As further shown in
The second cap mount 160 is shown in more detail in
The distal portion of the second end cap mount 160 includes a filter-receiving recess 510 that receives the filter 250 as shown in the cross-sectional view of
The proximal lens engagement portion 500 of the second end cap mount 160 has an inner cavity 520 defined by a profile that has a size and shape generally corresponding to the outer profile 300 of the lens 120 as shown in
As shown in
As further shown in
As further shown in
The second gasket sealing gasket 202 is formed by filling the gasket-receiving recess 558 with the silicone adhesive, as described above. The silicone adhesive cures to form a permanent gasket. The four lens standoff pads 550, 552, 554, 556 assist in defining the shape of the gasket. The standoff pads also prevent the gasket from being compressed too far when the second end cap mount 160 is inserted over the second end portion 354 of the lens 120 so that the gasket maintains a minimum thickness of approximately 0.02 inch.
As further shown in
The outer wall 610 of the first end cap 170 has a plurality of slots formed therein. The slots extend from the proximal end 172 of the first end cap. A first slot 620 and a second slot 622 are spaced apart to form a first resilient flap 624 therebetween. A first rectangular bore 626 is formed through the first flap. A third slot 630 and a fourth slot 632 are spaced apart to form a second resilient flap 634 therebetween. A second rectangular bore 636 is formed through the second flap. A fifth slot 640 and a sixth slot 642 are spaced apart to form a third resilient flap 644 therebetween. A third rectangular bore 646 is formed through the third flap. The first rectangular bore, the second rectangular bore and the third rectangular bore are sized and positioned to engage the first engagement protrusion 460, the second engagement protrusion 462 and the third engagement protrusion 464, respectively, of the first end cap mount when the proximal mounting portion 600 of the first end cap is mounted onto the distal end cap mounting portion 402 of the first end cap mount 150. The resilient flaps move outwardly to pass over the engagement protrusions as the first end cap is positioned onto the first end cap mount.
The outer wall 710 of the second end cap 180 has a plurality of slots formed therein. The slots extend from the proximal end 182 of the second end cap. A first slot 720 and a second slot 722 are spaced apart to form a first resilient flap 724 therebetween. A first rectangular bore 726 is formed through the first flap. A third slot 730 and a fourth slot 732 are spaced apart to form a second resilient flap 734 therebetween. A second rectangular bore 736 is formed through the second flap. A fifth slot 740 and a sixth slot 742 are spaced apart to form a third resilient flap 744 therebetween. A third rectangular bore 746 is formed through the third flap. The first rectangular bore, the second rectangular bore and the third rectangular bore are sized and positioned to engage the first engagement protrusion 560, the second engagement protrusion 562 and the third engagement protrusion 564, respectively, of the second end cap mount 160 when the proximal mounting portion 700 of the second end cap is mounted onto the distal end cap mounting portion 502 of the second end cap mount 160. The resilient flaps move outwardly to pass over the engagement protrusions as the second end cap is positioned onto the second end cap mount.
In the illustrated embodiment, the second end cap 180 is identical to the first end cap 170; however, the threaded bore 188 of the second end cap does not receive a screw and remains open. The central through bore 186 of the second end cap also remains open.
When the lighting structure 100 is assembled as illustrated herein, the lighting structure is fully sealed against external contaminants. The compression of the cable sealing-grommet 220 within the grommet-receiving recess 410 of the first end cap mount 150 seals the ribs 224 of the cable-sealing grommet against the inner surface of the grommet-receiving cavity and seals the through bore 222 of the cable-sealing grommet against the outer surface of the two-wire cable 264 of the wiring assembly 260. The first (left) end 122 of the lens 120 is sealed via the first (left) sealing gasket 200. Accordingly, no air or contaminants can flow into the cavity 126 of the lens via the first end cap mount 150.
The filter 250 seals the through bore 166 of the second end cap mount 160 as described above. The second (right) end 124 of the lens 120 is sealed via the second (right) sealing gasket 202. Accordingly, only air can flow into and out of the cavity 126 of the lens via the central through bore 186 of the second end cap 180 and the through bore of the second end cap mount. As discussed above, the filter prevents moisture and other contaminants from passing through the through bore of the second end cap mount. As the lighting structure 100 heats up during operation of the LEDs 132, the expansion of heated air within the cavity of the lens causes air to flow out of the cavity via the filter. When the lighting structure cools, air flows into the cavity via the filter.
The previous detailed description has been provided for the purposes of illustration and description. Thus, although there have been described particular embodiments of a new and useful invention, it is not intended that such references be construed as limitations upon the scope of this invention except as set forth in the following claims.
| Number | Name | Date | Kind |
|---|---|---|---|
| 10690335 | Xue | Jun 2020 | B2 |
| 10851986 | Zhang | Dec 2020 | B2 |
| Number | Date | Country | |
|---|---|---|---|
| 62890706 | Aug 2019 | US |
