The present application is generally related to enclosures for systems and devices. In particular, the present application is directed to systems and methods for enclosing and sealing systems and devices.
Devices and systems, such as the lighting systems may be used in a variety of applications and deployed in many different settings and environments. Lighting fixtures may be used in environments that are prone to exposure to natural elements, such as rain, snow, heat, cold, humidity, water or wind. These and other natural elements may cause problems and even malfunctions of lighting units which may include electronic and/or electrical components. Short circuit contacts may be caused by water or humidity which may destroy the electronic components such as switches or processors, thus decreasing the life span of the lighting fixtures and increasing the maintenance cost. Shielding the lighting units from these natural elements may become even more challenging as the rates of extension and contraction of different materials used for building the lighting fixtures may vary. This variation in extension and contraction rates between different materials may cause seals to crack along the interfaces of these materials. The cracks may provide openings for leakages, which may be even exacerbated by future contractions and expansions of materials as some parts of lighting units expand much more than other parts.
The present disclosure addresses these issues by providing a reliable and comprehensive enclosure system that seals a lighting fixture from outside elements. The systems, apparatuses and techniques of the present disclosure provide a lasting seal for the lighting fixture regardless of the rates of expansion and contraction different materials may experience. The systems, apparatuses and techniques described herein also allow for a water-tight seal regardless of sizes and lengths of enclosure components. The solution presented may utilize one or more silicone gaskets in combination with one or more o-ring chords, an acrylic optic and an extrusion to provide a sealed, water-tight and air-tight enclosure for any lighting unit whose enclosure is prone to temperature changes which may induce contractions and/or expansions of materials. The solution presented may also be used to provide a water-tight and air-tight seal for any other unit, electrical or mechanical apparatus, system, object or component having components prone to expansions and contractions. The seal created by the systems, apparatuses and techniques presented is maintained regardless of any changes in temperature or environment as the variation in rates of expansion and contraction of enclosure's components are compensated by other components of the enclosure maintaining the tight seal.
The present disclosure is related to methods, systems or apparatuses for providing a seal to an enclosed object, system, apparatus, device or a matter, such as a lighting fixture or a unit. A lighting fixture may be enclosed or packaged inside an enclosure that comprises an extrusion, such as an aluminum extrusion, a packaging box or any other enclosure. The extrusion may comprise three connected sides: a bottom side and two adjacent sides. Each of the sides may provide a length, a width and a height and may be connected or interfacing with one or more other sides of the extrusion. The extrusion may further comprise two end caps sealing or enclosing each of the two open cross-sectional ends of the extrusion not covered by the extrusion sides. Two silicone gaskets comprised of a flexible material may be positioned or fitted inside each of the two end caps prior to assembling the end caps onto the ends of the extrusion. An extruded acrylic optic may be positioned or fitted in along the length of the opening of the top portion of the extrusion. The acrylic optic may cover any portion of the top side opening not covered by the extrusion sides or the end caps. The optic may cover or protect a light source, such as a light bulb, a neon or a fluorescent tube enclosed within the enclosure. The optic may be reinforced by or interfaced with an o-ring positioned between the optic and the extrusion walls or sides. The o-ring may be acting as an interface providing a pressure and a seal between the optic and the extrusion walls (along the length-height plane). The silicone gaskets may interface with an end of the extruded acrylic optic by pushing against a cross-sectional (width-height plane) section of the extruded acrylic optic. The interface between the silicone gaskets and the ends of the extruded acrylic optic may provide a tight seal. As the optic is tightly fitted between the o-ring on both sides along the length of the extrusion and between the silicone gaskets along the ends of the optic, the enclosure may provide a reliable and lasting water and air impermeable seal.
During the operation of the lighting fixture, as the lighting fixture heats up or cools down, the extruded acrylic optic expands or contracts along with other components of the enclosure. As the optic may comprise a different material from other components of the enclosure, the optic may expand or extend or contract and shrink faster and by a greater rate than other components of the enclosure. Silicone gaskets interfacing with the ends of the optic, in the combination with one or more o-rings interfacing with the sides of the optic and the extrusion, may compensate for these expansions and contractions by deforming. Deformation by the silicone gaskets and the o-rings may fill in any gaps or cracks left by the expanding or contracting optic or any other component of the enclosure. As the optic expands, the optic having a length larger than the width may extend along the length and push against the silicone gaskets inserted into the end caps of the enclosure. The silicone gaskets may morph, reshape and/or contract to absorb the change in length of the optic, thus maintaining the seal of the enclosure. Similarly, when the lighting fixture is cooling after being used, the acrylic optic may shrink and contract and silicone gaskets may morph, reshape and/or expand to fill in any gaps left by the contracting optic. Likewise, the o-ring may also compensate for the shrinkage, movements, expansions and contractions of the optic, thus still maintaining the seal of the enclosure along the length of the optic.
In some aspects, the present disclosure relates to an apparatus providing a water-proof enclosure of an optic of a lighting fixture. The apparatus may include an enclosure having a plurality of connected rectangular sides. The apparatus may also include an optic of a lighting fixture inserted into an extrusion of the enclosure. The extrusion may interfacing with one or more o-rings between the optic and walls of the extrusion. The optic may expand when heated and contract when cooling. The apparatus may further include a deformable gasket at an end of the extrusion comprising at least one hole for receiving an end of the optic and the one or more o-rings. The apparatus may also comprise an end cap of the enclosure comprising a cavity to receive the deformable gasket. Upon inserting an end of the optic into the hole of the deformable gasket received by the end cap and securing the end cap to the extrusion, the apparatus, or the enclosure, may provide a water-proof seal around the end of the optic, the deformable gasket and the extrusion. The deformable gasket may maintain the water-proof seal during expansion and contraction of the optic.
In some embodiments, the deformable gasket comprises a silicon material having a predetermined hardness and flexibility. In further embodiments, a second deformable gasket at a second end of the extrusion received by a second end cap comprises at least a second hole for receiving a second end of the optic and the one or more o-rings. In yet further embodiments, the second deformable gasket at the second of the extrusion secured by the second end cap provides a water-proof seal around the second end of the optic and the one or more o-rings when the second end of the optic is inserted into the second hole. In still further embodiments, the one or more o-rings along with the deformable gasket and the second deformable gasket maintain the waterproof seal between all sides of the optic and the walls the extrusion and the end cap and the second end cap during expansion and contraction of the optic. In yet further embodiments, the deformable gasket and the second deformable gasket maintain the water-tight seal between the ends of the optic.
In some embodiments, the o-rings maintain the water-tight seal between a first side of the optic and a first wall of the extrusion and between a second side of the optic and a second wall of the extrusion during expansion or contraction of the optic. The first wall of the extrusion and the second wall of the extrusion may be adjacent to the end cap and the second end cap. In some embodiments, the optic is shaped to bend along a cross-section of the optic and apply pressure against walls of the extrusion via the one or more o-rings during contraction of the optic and during expansion of the optic. In further embodiments, the optic length from the end of the optic to a second end of the optic is at least four feet long. In yet further embodiments, the extrusion along the length of the optic is at least four feet long.
In some aspects, the present disclosure relates to an enclosure providing a water-tight seal of a lighting fixture. The enclosure may include an extrusion for a lighting fixture. The extrusion may comprise an optic. The enclosure may include one or more o-rings having a predetermined size, flexibility and hardness to provide a water tight interface between the optic and the extrusion. The optic may exert pressure between the one or more o-rings and walls of the extrusion. A silicone gasket may have a predetermined thickness to exert pressure against an end of the optic upon connecting an end cap to an end of the extrusion, the end cap comprising a hole for fitting the silicone gasket. Upon heating of the optic by the lighting fixture, the optic may expand and the end of the optic may press against the silicone gasket to maintain a water-tight seal. The silicone gasket may be deformable to morph, reshape and/or contract to compensate for the expansion of the optic. Upon cooling of the optic, the optic may contract and the silicone gasket may maintain the water-tight seal with the end of the optic as the end of the optic contracts. The silicone gasket may be deformable to morph, reshape and/or expand to compensate for the contraction of the optic.
In some embodiments, the one or more o-rings maintain the water-tight seal between the optic and the walls of the extrusion as the optic expands upon heating and as the optic contracts upon cooling. In further embodiments, a second silicone gasket having a second predetermined thickness to press against a second end of the optic upon and fitting within a hole of a second end cap at a second end of the extrusion. In yet further embodiments, upon heating of the optic, the second end of the optic presses against the second silicone gasket to maintain a water-tight seal, the second silicone gasket deformable to contract to compensate for the expansion of the optic. In further embodiments, upon cooling of the optic, the second silicone gasket maintains the water-tight seal with the second end of the optic as the second end of the expands to compensate for the contraction of the optic.
In some embodiments, the length of the optic between the first end and the second end is at least four feet long. In further embodiments, the optic is shaped to bend along a cross-section of the optic and apply pressure between the optic and the walls of the extrusion via the one or more o-rings during the contraction of the optic and during the expansion of the optic. In further embodiments, the first end cap and the second end cap are applying pressure against the silicone gasket and the second silicone gasket and providing a water-tight seal.
In some aspects, the present disclosure relates to an enclosure providing a water-tight seal of a lighting fixture. An extrusion of an enclosure for a lighting fixture may comprising an optic and one or more o-rings having a predetermined hardness and sized to fit between the optic and the extrusion. The optic may be constructed to exert pressure between the one or more o-rings and the extrusion. The enclosure may further comprise a silicone gasket to exert pressure against the optic upon fitting within an end cap of the extrusion. The end cap may be connected to the extrusion. Upon heating of the optic by the lighting fixture, the optic may expand and press against the silicone gasket to provide a water-right seal. The silicone gasket may morph, reshape and/or contract to compensate for the expanding optic. Upon cooling of the optic, the optic may contract and silicone gasket may maintain the water-tight seal by morphing, reshaping and or expanding to compensate for the contracting optic.
In some embodiments, the silicone gasket comprises one of a rubber, silicone, latex or elastic polymer material. In further embodiments, the silicone gasket comprises the material with an elongation percentage of about 720 when press cured at 5 minutes at 166 Celsius. In still further embodiments, the silicone gasket comprises the material having tear strength of about 15 kN/m when press cured for about 5 minutes at 166 Celisus. In yet further embodiments, the deformable gasket comprises a flexible and deformable material having tensile strength of about 6.5 MPa when press cured for 5 minutes at 166C.
In some aspects, a lighting fixture providing a water-tight seal to optical components. The lighting fixture may include an acrylic optic positioned along a length of an opening of a extrusion of an enclosure. The lighting fixture may also include an o-ring positioned between the acrylic optic and walls of the extrusion the o-ring providing a pressure and a seal between the acrylic optic and walls of the extrusion. The lighting fixture may include an end cap enclosing a silicone gasket interfacing with an end of the acrylic optic extruding from the extrusion. Deformation by the silicone gasket and the o-ring may fill in gaps created by movement of the acrylic optic responsive to heating or cooling from the lighting fixture, the silicone gasket and the o-ring contracting and expanding to maintain a water-tight seal with the acrylic optic.
The foregoing and other objects, aspects, features, and advantages of the present invention will become more apparent and better understood by referring to the following description taken in conjunction with the accompanying drawings, in which:
The features and advantages of the present invention will become more apparent from the detailed description set forth below when taken in conjunction with the drawings, in which like reference characters identify corresponding elements throughout.
A device or an object, such as for example a lighting fixture, may be deployed in a variety of environments and operated under any conditions. Some applications require devices or systems, such as the lighting fixtures, to be deployed in environments exposed to varying natural elements. These natural elements may be any elements, such as snow, water, wind, heat, cold, humidity or pressure. These and similar elements may have a negative effect on many components of the device enclosed, such as for example electronic or electrical circuitry, logic components or wiring. Packaging and protecting the lighting fixtures from such elements by providing a sealed, water and air impermeable enclosure may be accomplished by the systems, apparatuses, techniques and methods described below.
Referring to
In further overview,
Enclosure 100 enclose or provide packaging for any object, apparatus, matter or a system using any number of different types of components. Enclosure 100 may be a packaging or an enclosure that comprises a single piece of material or multiple different materials. In some embodiments, enclosure 100 includes any number of parts or components made up of any materials, including metals, such as aluminum, steel, iron or any alloys, as well as plastics and glass, plexiglass, or any transparent material used for covers. The components of the enclosure 100 may include, but not be limited to, extrusion 105, end caps 110, silicone gaskets 120, o-rings such as an o-ring 130, optic 140, end cap covers 145, screws such as end cap screws 150 and any other number of components known to be used for packaging, sealing and enclosing purposes. Enclosure 100 may comprise any number of components made up of same, similar or different type of materials. In some embodiments, enclosure 100 comprises some components that are clear or translucent over any spectral range of light. In further embodiments, enclosure 100 comprises some components whose expansion rates given a temperature change is larger than the expansion rate of other components of the enclosure 100.
Enclosure 100 may be of any size and shape. Depending on the application and the design, the enclosure 100 may be anywhere between 1 millimeter and 100 meters long. Depending on the design, enclosure 100 may have a length of anywhere between 1 inch and 100 feet. For example, enclosure 100 may have a length of about 1 inch, 2 inches, 4 inches, 8 inches, 1 foot, 1.5 feet, 2 feet, 2.5 feet, 3 feet, 3.5 feet, 4 feet, 4.5 feet, 5 feet, 5.5 feet, 6 feet, 6.5 feet, 7 feet, 7.5 feet, 8 feet, 8.5 feet, 9 feet, 9.5 feet, 10 feet, 11 feet, 12 feet, 13 feet, 14 feet, 15 feet, 16 feet, 17 feet, 18 feet, 19 feet, 20 feet, 25 feet, 30 feet, 40 feet, 50 feet, 60 feet, 70 feet, 80 feet, 90 feet or 100 feet. Sometimes, depending on the design, enclosure 100 may be anywhere from 0.01 inches to 3 feet wide. Enclosure 100 may include a width of anywhere between 0.1 inch and 3 feet. In some embodiments, enclosure 100 includes a width of 0.01 inches, 0.05 inches, 0.1 inches, 0.2 inches, 0.4 inches, 0.5 inches, 0.75 inches, 1 inch, 1.5 inches, 2 inches, 2.5 inches, 3 inches, 3.5 inches, 4 inches, 4.5 inches, 5 inches, 5.5 inches, 6 inches, 7 inches, 8, inches, 9 inches, 10 inches, 11 inches, 1 foot, 1.5 feet, 2 feet, 2.5 feet or 3 feet. In some embodiments, enclosure 100 is between 0.01 and 3 feet high. Sometimes, depending on the design, enclosure 100 may have a height of anywhere between 0.01 inches till about 3 feet. In some embodiments, enclosure 100 comprises a height of about 0.01 inches, 0.05 inches, 0.1 inches, 0.2 inches, 0.4 inches, 0.5 inches, 0.75 inches, 1 inch, 1.5 inches, 2 inches, 2.5 inches, 3 inches, 3.5 inches, 4 inches, 4.5 inches, 5 inches, 5.5 inches, 6 inches, 7 inches, 8 inches, 9 inches, 10 inches, 11 inches, 1 foot, 2 feet or 3 feet. The sizes and shapes of the enclosure 100 may vary depending on the environment in which the lighting fixture is used. The size of optic 140 inserted as a top cover for enclosure 100 may also vary in accordance with the size of enclosure 100.
Extrusion 105 may be any extrusion, casing, box, or a piece of material providing an enclosure. In some embodiments, extrusion 105 is an enclosure component, or a plurality of components combined or connected to form an enclosure or a portion of an enclosure for an object, unit, or a device such as a lighting fixture. In some embodiments, extrusion 105 is an aluminum box or an aluminum tube. In other embodiments, extrusion 105 is an enclosing unit or a casing comprising any type and form of material. The extrusion may comprise any material used for manufacturing any type and form of packaging or enclosure. In some embodiments, extrusion 105 includes any metal or an alloy of one or more metals. In other embodiments, extrusion 105 includes any one of, or any combination of: plastic, plexiglass, glass, acrylic, rubber, foam, wood, ceramic, stone or any other type and form of material which may be used to produce an enclosure box, or walls of an enclosure box. In some embodiments, extrusion 105 is clear. In other embodiments, extrusion 105 is opaque. In further embodiments, extrusion 105 is water-tight or air-tight. In still further embodiments, extrusion 105 is custom designed to comprise a material or shape in accordance with special applications the enclosure 100 is used for.
Extrusion 105 may comprise any size and shape. Extrusion 105 may be of any length, width or height. In some embodiments, extrusion 105 of the enclosure 100 comprises a length of anywhere between 1 centimeters and 100 meters. Extrusion 105 may have any size in length, width and/or height of enclosure 100. In some embodiments, extrusion 105 may have a length of about 1 foot, 1.5 feet, 2 feet, 2.5 feet, 3 feet, 3.5 feet, 4 feet, 4.5 feet, 5 feet, 5.5 feet, 6 feet, 6.5 feet, 7 feet, 7.5 feet, 8 feet, 9 feet, 10 feet, 11 feet, 12 feet, 13 feet, 14 feet, 15 feet, 16 feet, 17 feet, 18 feet, 19 feet or 20 feet. In some embodiments, extrusion 105 comprises a width of anywhere between 1 centimeter and 20 meters. Extrusion 105 may have a width of 0.25 inches, 0.5 inches, 0.75 inches, 1 inch, 1.25 inches, 1.50 inches, 1.75 inches, 2 inches, 3 inches, 4 inches, 6 inches, 8 inches, 10 inches, 12 inches, 15 inches, 18 inches, 24 inches or 36 inches. Extrusion 105 may comprise any height between 1 centimeters and 100 centimeters. In some embodiments, extrusion 105 comprises a height of 0.1 inch, 0.25 inch, 0.5 inches, 0.75 inches, 1 inch, 1.25 inches, 1.5 inches, 1.75 inches, 2 inches, 2.5 inches, 3 inches, 4 inches, 5 inches, 6 inches, 7 inches, 8 inches, 9 inches, 10 inches, 12 inches, 18 inches, 24 inches or 36 inches. Extrusion 105 may comprise any type of style or shape. In some embodiments, extrusion 105 may comprise a plurality of sections, each one of which may be shaped differently than other shapes. In some embodiments, extrusion 105 has a rectangular shape. In other embodiments, extrusion 105 has a cylindrical, semi-cylindrical or tube-like shape. In further embodiments, extrusion 105 comprises any number of sides of any length and type. In some embodiments, any number of sides that make up an extrusion 105 may be interconnected, divided with or interfaced with any number of o-rings, such as an o-ring 130.
End cap 110 may be any cap or covering that may be attached to an end of an extrusion 105. In some embodiments, an end cap 110 is a cover of a cross sectional portion of extrusion 105 at the ends of the extrusion, along the width-height plane. Size of end caps 110 may vary based on the size of extrusion 105 and/or enclosure 100. In some embodiments, an end cap 110 is a cap to enclose the ending of the extrusion 105. In further embodiments, an end cap 110 is custom fitted to seal the open ending of the extrusion 105. End cap 110 may comprise any material also comprised by an extrusion 105 or a different material. End cap 110 may be attached to an extrusion via any means, such as screws, hooks, glue, pin or lock. End cap 110 may be interfaced with the extrusion 105, silicone gasket 120 or optic 140 via one or more o-rings, such as an o-ring 130. End cap 110 may be custom fitted to enclose a silicone gasket 120. In some embodiments, end cap 110 comprises a back wall and side walls forming a hollow space into which the silicone gasket 120 is placed or fitted. The end cap 100 may be shaped and sized in a manner to press or compress the silicone gasket 120 against the extrusion 105, optic 140 and the o-ring 130. Compressing the silicone gasket 120 enclosed within the end cap may deform the silicone gasket 120 and ensure that portions of the deformed silicone gasket 120 fill or seal any openings between the end cap 110, extrusion 105, optic 140 and o-ring 130. The end cap 110 may be shaped to provide a specific amount of compression to the silicone gasket 120 upon screwing, or otherwise attaching, the end cap 110 to the extrusion 105.
Silicone gasket 120 may include any component comprising a flexible, deformable and elastic material and formed to interface with components of enclosure 100. Silicone gasket may include any deformable gasket capable of filling in gaps and sealing interfaces with hard materials, such as metals, plastics, optical components, glass and/or plexiglass. Silicone gasket 120 may be a piece of elastic or flexible material of any size or shape formed to interface with optic 140, end cap 110, o-ring 130 and/or extrusion 105. The size and shape of the silicone gasket 120 may be designed or adjusted depending on the shape of the ending portion of the optic 140 that interfaces with the silicone gasket 120. Silicone gasket 120 may interface with, connect to, touch or pushing up against any one of or any combination of: an optic 140, end cap 110, extrusion 105 and o-ring 130. Silicone gasket 120 may be formed or shaped to enclose, engulf or hold any portion of optic 140. Silicone gasket 120 may allow optic 140 to move while maintaining a water-tight and air-tight seal with the optic.
Silicone gasket 120 may include any type and form of elastic, morphing and/or deforming material. Silicone gasket 120 may comprise rubber, latex, silicone, and/or any elastic polymer or elastomer allowing the silicone gasket 120 to change shape and/or morph to compensate for movements of rigid components. In some embodiments, silicone gasket 120 comprises a natural or an artificial rubber. In some embodiments, silicone gasket 120 comprises a flexible or elastic form of silicone. In further embodiments, silicone gasket 120 comprises Elastosil™ by Wacker-Chemie GmBH. In some embodiments, silicone gasket 120 comprises a material that is characterized by any durometer range, such as durometer of about 5-100. In some embodiments, silicone gasket 120 comprises a commercial grade liquid silicone rubber having durometer value of about 20. In further embodiments, silicone gasket 120 comprises a material designed for liquid injection molding. In some embodiments, silicone gasket 120 comprises a translucent material. In further embodiments, silicone gasket 120 comprises a material having a specific gravity at 25 Celsius temperature of 1.11. In some embodiments, silicone gasket 120 comprises a material that is extrusion rate catalyzed at 25 Celsius at 350 g/min. In some embodiments, silicone gasket 120 comprises a material whose tensile strength is 6.5 MPa when press cured 5 min/166 C or 7.9 MPa post cured at 4 hr/204 C. In further embodiments, silicone gasket 120 comprises a material whose tear strength is 15 kN/m when press cured 5 min/166 C and 20 kN/m when post cured 4 hr/204 C. In further embodiments, silicone gasket 120 comprises a material whose elongation percentage is 720 when press cured at 5 min/166 C and 750 when press cured at 4 hr/204 C. Elongation of the silicone gasket 120 may be anywhere between 100 and 1000%. In some embodiments, elongation is about 500, 600, 700, 800 or 900%.
Silicone gasket 120 may be designed to have any size and shape to interface with enclosure 100 components. In some embodiments, the size and shape of the silicone gasket 120 is determined based on the size and shape of the end caps 110, o-ring 130 and optic 140. Silicone gasket 120 may include a through hole through which optic 140 is inserted. In such embodiments, silicone gasket 120 may provide a seal by tightly surrounding a cross-sectional portion of optic 140 while the optic contracts or expands. When optic 140 is inserted through the hole of the silicone gasket 120, the seal between the silicone gasket and the optic 140 is tight as the optic is snug against the walls of the silicone gasket 120. In some embodiments, silicone gasket 120 comprises a hole that is not a through-hole and that has a bottom within the silicone gasket 120. Optic 140 may be inserted into the hole and may press against the bottom or be snug with the bottom of the silicone gasket 120. In such embodiments, silicone gasket 120 may morph, reshape, contract or expand, enabling the end of the optic 140 pressing against silicone gasket 120 to move in an out of the hole, while the bottom and the surrounding sides of the silicone gasket 120 adjust to maintain the seal around optic 140. Silicone gasket 120 may further be shaped to interface with o-ring 130. In some embodiments, silicone gasket 120 comprises a hole, slit or a dent to interface with the o-ring 130. In other embodiments, silicone gasket 120 is shaped to have a snug fit within the end cap 110 as well as have a tight seal with the optic 140 and the o-ring 130.
In some embodiments, silicone gasket 120 may comprise a material with specifications as shown in the table below:
O-ring 130 may be any type and form of gasket comprising a flexible or elastic material. O-ring 130 may be any gasket acting as a water-tight and air-tight interface between the optic 140 and the extrusion 105. In some embodiments, o-ring 130 is a chord of flexible and elastic material comprising a specific length and diameter. In further embodiments, o-ring 130 is a chord comprising a length, width and thickness. In further embodiments, o-ring 130 is a ring-shaped or donut-shaped gasket. O-ring 130 may be installed or inserted between the optic 140 and the walls of extrusion 105. O-ring 130 may be installed between a silicone gasket 120 and an optic 140. In further embodiments, o-ring 130 is installed between any two or more components of the extrusion 105, such as extrusion sides. In yet further embodiments, o-ring 130 is installed between the end cap 110 and the extrusion, between the end cap 110 and the silicone gasket or between the silicone gasket and the optic 140.
O-ring 130 may comprise any type and form of material. In some embodiments, o-ring 130 comprises an elastomer, such as a rubber or a latex. In further embodiments, o-ring 130 comprises a silicone compound. In yet further embodiments, o-ring 130 comprises a Silicone compound, such as M2GE706A19B37EA14EO16EO36G11Z1. The hardness of the o-ring 130 material may be between 60 and 70 durometers. In some embodiments, the o-ring 130 material may comprise tensile strength of 1000 psi. In further embodiments, o-ring 130 material may comprise elongation percentage of 225. In further embodiments, the specific gravity of the o-ring 130 material is 1.26. In some embodiments, at 70 hours at 225 Celsius durometer of the o-ring 130 material may change by about −5 durometers from the original. In further embodiments, at 70 hours at 225 Celsius tensile of the o-ring 130 material may change by −20 percent from the original. In still further embodiments, the o-ring 130 material may comprise the tear resistance of 10 kN/m. O-ring 130 may be of any color, such as orange, red or black.
Some embodiments of the o-ring 130 are provided in the table below:
In some embodiments, the materials of the o-ring 130 comprises any of the specifications as described in the table below:
Optic 140 may comprise any type and form of material and may be used to cover a top portion of the enclosure 100. In some embodiments, optic 140 comprises any type and form of translucent or semi-translucent material. In yet further embodiments, optic 140 comprises a material from which, or through which, an electromagnetic wave can be emitted or transmitted. In some embodiments, optic 140 comprises an opaque material, such as for example a metal or any material that may be comprised by an extrusion 105. In some embodiments, optic 140 comprises an acrylic. In still further embodiments, optic 140 comprises an extruded acrylic. In some embodiments, optic 140 comprises plexiglass. In yet further embodiments, optic 140 comprises glass. In still further embodiments, optic 140 comprises any type and form of plastic. Optic 140 may comprise any type and form of material which is transparent or partially transparent to any type and form of emitted electromagnetic wave or light. Optic 140 may further comprise an edge, such as an edge disclosed in
Optic 140 may serve as light guide or a light renderer of an enclosed light emitting device. In some embodiments, lighting fixture comprises one or more light emitting diodes or LEDs. The LEDs may emit light of any type, power or spectral range. The lighting fixture may further comprise neon lamps, fluorescent lamps, light bulbs, laser diodes or any other type or form of light emitting device. Optic 140 may provide light rendering, diffusion or light guiding for the light emitted by the LEDs of the lighting fixture. In some embodiments, Optic 140 serves as a cover and protector for the LEDs or light sources enclosed within the lighting fixture.
Optic 140 may be designed and constructed to comprise any extension or shrinkage rates. In some embodiments, optic 140 is manufactured to ensure a specific shrinkage/expansion rate or to ensure a range of shrinkage rate. In some embodiments, optic 140 comprises a shrinkage rate of between 0 and 1%. In further embodiments, optic 140 comprises a shrinkage rate of between 1-2%. In further embodiments, optic 140 comprises shrinkage rate of about 2, 3, 4 ,5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 35, 40 and 50 percent. Optic 140 may be manufactured and tested in any way to ensure any range of shrinkage rate percentage.
Optic 140 may comprise any size and shape to interface with the extrusion 105, end cap 110, o-ring 130 or silicone gasket 120. In some embodiments, optic 140 is shaped as a semi-circular tube. In other embodiments, optic 140 is hollow. In further embodiments, optic 140 is designed to provide a specific tension when pushing against o-ring 130, extrusion 105 and silicone gasket 120 to provide a tight seal. In yet further embodiments, optic 140 comprises an elongated tube whose cross-section plane (width-height plane) resembles a circle, an oval, a half-circle, a half oval, a crescent-like shape or an irregular custom shape, such as a shape of turtle-shell as shown in cross-sectional plane of
Further embodiments of optic 140 are disclosed in the table below:
Optic 140 of about 4 feet length may extend by about 0.2 inches due to heating of the lighting fixture. During the manufacturing of the optic 140, the optic 140 may be annealed at a temperature of between 80 and 120 Celsius, such as for example 95 Celsius to decrease the shrinkage rate of the optic 140.
Still referring to
In a further example, the lighting fixture emits about 15 watts of light per foot of length of the lighting fixture. As the lighting fixture operates on this power, the lighting fixture and the enclosure 100 may heat up. As the lighting fixture may comprise length of 4, 6, 8, 12 or more feet, some components of the lighting fixture may expand due to change in temperature of the device. The silicone gaskets 120 may comprise one or more holes into which one of each ends of the optic 140 is inserted. As the optic 140 or any other component of the enclosure 100 expands or contracts, the silicone gasket 120 compensates for the expansion or contraction, thus maintaining the seal. The silicone gaskets 120 may comprise one or more through holes through which one of each ends of the optic 140 is inserted. The silicone gaskets 120 may be designed to provide a tight seal around the optic 140, thus preventing any leakage of air or water between the optic 140 and the end cap 110 regardless of the changes in sizes due to temperature changes of either optic 140 or the end caps 110. The silicone gasket 120 may further be designed to provide a tight seal between the extrusion 105 and the end caps 110 once the end caps 110 are attached to the extrusion 105. The silicone gasket 120 may provide the seal by deforming to compensate for any change in size or shape by any of the enclosure 100 components. In some embodiments, there are two or more silicone gaskets 120 of same or different shape and size on each side of the optic 140. Some silicone gaskets 120 may comprise through holes, while others may comprise holes which are not through holes. Once the end of the optic 130 is inserted into the silicone gasket 120 enclosed within an end cap 110, the silicone gasket 120 may compress or contract whenever the optic 140 expands, extends or increases in size due to temperature change. Similarly, the silicone gasket 120 may decompress or expand whenever the optic 130 shrinks, shortens or decreases in size due to any temperature change. The silicone gasket 120 may similarly also shrink or expand and therefore compensate for any movements of extrusion 105 or end cap 110. Therefore, the silicone gasket 120 may maintain the watertight seal despite any movements of the optic, extrusion 105 or end cap 110 due to any changes in temperature.
O-ring 130 may be designed to have a specific hardness, flexibility, size and shape to fit snuggly between the optic 140 and the extrusion 105. In addition, the o-ring 130 may comprise elasticity to stretch and compress along with any movements of the optic 140 or the extrusion 105. The o-ring 130 may further be greased to minimize wear and tear while the optic 140 extends and contracts with changes in temperature of the lighting fixture. The o-ring 130 may also be interfaced with the silicone gasket 130 to enable a tight seal in the corner connections of the silicone gaskets 120, extrusion 105, end cap 110 and the o-ring 130. The o-ring 130 may be lined or kept in place by a groove in the extrusion 105.
The optic 140 may be inserted into the extrusion from the top opening of the extrusion 105. The optic 140 may be shaped to provide compression, or push against the o-ring 130 which interfaces between the extrusion 105 and optic 140. The optic 140 may further be shaped to provide compression, or exert pressure against the silicone gaskets 120 and the end caps 110. The optic 140 may be kept in place by a groove of the extrusion 105. The silicone gasket 120 may comprise a specific thickness such that when the end caps 110 are connected to the ends of the extrusion 105, a pressure is exerted by the silicone gasket 120 against the ends of the optic 140. As the optic 140 is heated by the lighting fixture, the optic 140 may expand and further press against the extrusion 105 and end cap 110, thus maintaining the water tight seal of the enclosure 100. Similarly, as the optic 140 cools off, the optic 140 will shrink or contract, however a sufficient pressure to maintain the water-tight seal will be exerted by the optic 140 against the extrusion 105 and the silicone gaskets 120, as well as the end caps 110. As such, the lighting fixture enclosure 100 maintains the water-tight, water-proof and air-tight seal despite any changes in the temperature caused by the lighting fixture or the outside environment.
In another example, the end caps 110 are aluminum end caps. The end caps 110 provide the cavity into which the silicone gasket 120 is compressed. Silicone gasket 120 may be a silicone rubber gasket. End caps 110 and the silicone gaskets 120 for each of the end caps 110 may be designed so that the silicone gasket 120 thickness is greater than the depth of the cavity of the end caps 110 into which the gaskets 120 are inserted. As such, the silicone gaskets 120 may be compressed as the end caps 110 are attached or screwed onto the extrusion 105. In some embodiments, end caps 110 and the silicone gaskets 120 are designed so that the silicone gaskets 120 are compressed by about 0.05 inches, or that the silicone gaskets 120 provide about 0.05 inches of compression against the extrusion 105 or optic 140. End caps 110 may further comprise 5 screw holes for ensuring the pressure applied to the silicone gaskets 120 is even.
In a further example, an optic expansion pocket may be calculated such that when the optic 140 expands under heating conditions, it has room to expand into the end cap 110. The design may account for any changes in size of the optic 140, or any other component of the enclosure 100 such that the contact between the silicone gasket 120 does not lapse or changes. This design provides a lasting seal regardless of any changes in the size of the optic 140 or any other component of the enclosure 100.
An overhanging lip on the end cap 110 or an extrusion 105 may keep a silicone gasket 120 from extruding out of the cavity. The design may ensure that the only area where the silicone gasket 120 has an opportunity to expand or extrude is at the top side of the enclosure where the optic 140 is located. As that area remains exposed and the silicone gasket 120 may expand into that area when the additional pressure is applied due to the expansion of the optic 140. The overhanging lip may keep downward pressure on the gasket where it comes in contact with the optic 140, thus providing seal. The overhanging lip may also keep the silicone gasket 120 in tact during expansion and contraction phases.
A chamfered internal edge adds may also be added to the design. The chamfered internal edge may increase the manufacturability of the design. When the silicone gasket 120 is compressed the tapered edge may lead the silicone gasket 120 into position keeping it from pinching or bowing. Similar edges may be added to the extrusion for the purpose of maintaining an o-ring 130 in position or maintaining optic 140 in position.
In a further example, silicone gasket 120 may be cut from a sheet of molded sheet rubber. The molded sheet rubber may have a low durometer values, or moderately low durometer values. The molded sheet rubber may have durometer values, such as about 20 durometers. The molded sheet rubber may also have a relatively high elongation at break percentage, such as 650-750%. The relatively high elongation at break percentage may enable providing more even pressure on the areas where the sealing is provided, such as the optic 140. By compressing silicone gasket 120 by about 0.05 inches on a 0.188 inch thick silicone gasket 120, the silicone gasket 120 is compressed about 26.5% at nominal dimensions. In some embodiments, for every 50% of compression the internal elongation of the material is over 100%. As such, the design may be adjusted to exhibit a roughly 50% internal elongation of the material. This amount of internal elongation may still be sufficiently far from the maximum allowed, enabling the design to provide the seal within the spec of the material. This design may also prevent bowing or pinching of the silicone gasket 120 unevenly during compression. The combination of the material selected, compression, and durometer of the material may all come together to make the silicone gasket 120 to seal the design.
In a further example, compression testing for a design of the components of the enclosure 100 may provide following results. The test may be performed with 30 Durometer Silicone Sheet Rubber from Diversified Silicone Products, 0.188″ Thick, Compression—0.040″—Material fills the hole 0.056″ Compression—0.030—Material fills the hole 0.042″. The silicone gasket may come in on the low end tolerance of the thickness, material to compress may be down to 0.008″. If the machined end cap comes in on the low end tolerance of the depth of the pocket, material to compress will be down 0.005″. These tolerances may take 0.013″ off of our thickness of material to compress. This may bring our calculated 0.040 compression down to 0.027″. At 0.027″ compression, the material may fill approximately 0.042″. If the optic comes in on the small side, it may be 0.006″ smaller. If the gasket cut comes in on the high side, it may be 0.007″ larger. The dimensions of the silicone gasket 120 may be undersized by 0.003 as compared to the optic. If the machined end cap comes in on the high end width tolerance of the pocket, the gasket may fill out an additional 0.003″. The dimensions of the silicone gasket 120 may be oversized by 0.002 as compared to the end cap pocket. When these tolerances are added: 0.006+0.007+0.003=0.016″. There may be an additional 0.016″ that may be subtracted from our 0.042″ compression on the low end tolerance. This may leave us with 0.026″ of compression at one scenario for analysis. As such, the conclusion may be that even at 0.026″ of compression, the enclosure 100 may still adequately seal. In addition, silicone grease may be used as an additional sealant on the silicone gaskets 120. Silicone grease may also provide additional level of protection and may improve the sealing.
Further information regarding the analysis is provided in the table below:
Grease, such as the silicone grease, may be used on the inside of the optic 140 cavity of the silicone gasket 120 or on the optic 140. The grease may also be used between the optic 140 and the o-ring 130. In some embodiments, the grease fills in any microscopic scratches and cracks, thus providing a seal. In further embodiments, the grease provides a lubricant for the piston effect of the optic 140 as the optic shrinks and contracts. In some embodiments, based on the coefficient of thermal expansion of the optic 140 may change the length by about 0.200″ inches (assuming 48″ nominal optic length) when cycled from −30 C to +60 C. If the optic 140 is heated to a higher temperature, optic 140 may change the length by more than 0.200″, such as 0.25″, 0.30″, 0.35″, 0.40″, 0.45″, 0.5″, 0.55″, 0.6″, 0.7″, 0.8″, 0.9″ and 1.0″. Changes in length may be linear or otherwise related to the length of the optic 140. As the optic is aggressive in moving, the grease may ensure that the optic 140 will not pinch or pull the silicone gasket 120 during this movement.
In a further example, assembly of the enclosure of the lighting fixture may start with adding some grease to the inside of the optic cavity of the silicone gasket. Once the silicone gasket has been pre-greased, it may be slid onto the optic overhanging the extrusion and the 4 o-rings also overhanging the extrusion may be slid through the gasket. The o-rings may be cut flush with the outward face of the gasket which may be compressed against the end cap. The end cap then may be slid over the top of the gasket and compressed by evenly tightening the 5 screws which are inserted through the end cap, through the gasket, and into the threaded holes in the extrusion. When the screws compress the gasket, the openings in the gasket may begin to squeeze. The holes for the screws may be compressed around the screw and seal it. The outside of the interface between the end cap and the extrusion may also be sealed by this compression of the gasket against the flat of the extrusion. The gasket over the top of the optic may also seal and the lip on the end cap may be keep even downward pressure against the optic. In some embodiments, all four o-rings may be compressed around and sealed while the ones on the top are also tightly squeezed against the side of the optic keeping it sealed. The label may be added and the end cap assembly may then be complete.
The enclosure may be tested with thermal shock tests from −25 C to +55 C and tested with a hydrogen leak tester to conform at the extremes as well as during the cycle when the optic is moving the most. In order to guarantee air tight seal prior to shipment of the enclosure, in-process Hydrogen leak test may be used. This method may also used in the air conditioning and refrigeration industries where complete sealing is considered important. Hydrogen testing may provide instant results on leaks that would normally be too small to even be detected by other methods with a sensitivity of <0.5 ppm. The Hydrogen Leak Test may be performed on each lighting fixture after which they are vacuumed and filled with Nitrogen gas to further promote a dry internal cavity of the fixture.
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The present application claims priority to and is a continuation of U.S. patent application Ser. No. 12/766,807 filed on Apr. 23, 2010, which claims the benefit of and priority to U.S. Provisional Application No. 61/172,186 filed on Apr. 23, 2009, both of which are incorporated herein in their entirety by reference.
Number | Date | Country | |
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61172186 | Apr 2009 | US |
Number | Date | Country | |
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Parent | 12766807 | Apr 2010 | US |
Child | 14081576 | US |