Patent Grant
7387409
The invention relates to a light fixture for use in low voltage outdoor lighting systems and more specifically to a pathway light fixture with components that are easily removed and replaced.
Environmental lighting, particularly outdoor lighting, is well known in commercial or public settings, such as parks and schools. Such lighting is also popular in residential applications, both to enhance the appearance and safety of the outdoor area and for security, to illuminate dark areas around a building or in a yard which may provide hiding places and unobserved entry points for intruders.
Landscape and outdoor lighting systems include one or more lighting fixtures which are connected to either a 12 V transformer or a standard 120 V AC line. Some lighting fixtures enclose a halogen lamp or conventional bulb within a housing, and include a reflector assembly and a lens or window within the housing. These fixtures may be used for highlighting features such as trees or statues, i.e., up-lighting or for pathway or ground lighting. Other fixtures, used almost exclusively in down-lighting applications, may have an open aspect, where the reflector, and sometimes the lamp and socket are open and directed toward the ground. These fixtures tend to be used in larger quantities within a lighting system since they are typically less expensive than the closed fixtures and are capable of washing large expanses of open area with glare-free light, e.g., pathways, driveways, patios, ground cover plants, and for perimeter lighting.
Pathway down lighting fixtures often have a hood or cowl shaped in the form of a bell, half-shell, cone, tulip, or pyramid that surrounds the lamp except for the lower end of the cowl from which the light emanates. In addition to preventing escape of light in an upward direction, the inner surface of the cowl acts as a reflector to optimize the amount of light directed toward the desired target area.
Outdoor light fixtures are prone to dirt build-up and/or corrosion that can diminish light output and accelerate deterioration and, ultimately, failure of the fixture. In closed fixtures, the effects of dirt build-up and/or oxidation can be reduced by sealing the lamp within a clear or translucent cylinder to create a moisture-proof chamber. To achieve the desired seal, the upper edge of the cylinder is typically glued to the hood using epoxy or silicone adhesive. Any accumulation of material on the cylindrical lens can be easily wiped away to restore full illumination capability. A drawback of the closed fixture designs is that one must disassemble the housing by separating the lens from a base portion to access the lamp for replacement. Another issue with closed fixtures is that the lens can break or crack. Since the lens is glued to the hood, the entire hood/lens assembly must be replaced if one wishes to ensure a well-sealed fixture. An exemplary closed fixture is described in U.S. Pat. No. 6,874,905, of Beadle, which is incorporated herein by reference. In addition to being costly to replace both the lens and metal hood, introduction of a new hood into an established lighting system can detract from the aesthetics of the system since the new hood will not match the other fixtures because is has not weathered or oxidized, for example, to a verde finish in the case of copper.
Another drawback of current commercially available outdoor lighting systems is that such systems will remain in place for years. Due to the expense and effort of replacing an entire set of fixtures, the property owner will keep the same fixtures, even if they would prefer a change in appearance, for example, if the landscape design has changed, or the house or other building has been remodeled or painted a different color.
It would be desirable to provide a pathway light fixture that is attractive, resists breakdown in an outdoor environment, is easy to manufacture and service, and includes easily replaced critical components while still maintaining a good quality seal. The problems and deficiencies are clearly felt in the art and are solved by the present invention in the manner described below.
It is an advantage of the present invention to provide a pathway light fixture that has a moisture-proof seal to fully enclose the lamp and to protect the lamp and socket against exposure to contaminants.
Another advantage of the present invention is to provide a pathway light fixture that allows for replacement of individual components.
A further advantage of the present invention is to provide a pathway light fixture that provides for changing its appearance without requiring replacement of the entire fixture.
In an exemplary embodiment, the pathway downlight fixture for outdoor installation comprises a post, a socket assembly retained within the top of the stem for retaining a lamp, a lens assembly including a lens support and diffuser lens disposed on top of the stem surrounding the top of the socket assembly, and a hood assembly comprising a hood and reflector retaining cap removably mounted on top of the lens assembly.
The reflector hood is centered over the diffuser lens and flared to capture and reflect light emitted through the lens in a downward direction. The radial center of the hood has a flattened area so that the hood sits level on the top of the cylindrical lens. The center of the flattened top area has an opening therethrough to permit the base portion of the reflector retaining cap to pass through the hood and into a recess in the upper surface of the lens. An opening is formed in the center of the recess for insertion of a fastener to releasably attach the retaining cap to the lens assembly. An O-ring at the top of the lens forms a water-tight seal between the lens and the lower surface of the hood.
In the exemplary embodiment, the socket assembly includes a generally cylindrical socket housing that has a lower portion adapted to fit and be retained within the upper end of the hollow post. In one embodiment, the upper portion is threaded to mate with a threaded recess in the lens support. To provide a watertight seal, an O-ring is disposed between the lens support and the socket housing. In an alternate embodiment, the upper portion of the socket housing has at least two O-ring seats for receiving O-rings to provide an interference fit within the recess in the lower portion of the lens support.
A bore formed along the axial center of the socket housing has an inner diameter for receiving a commercially available socket. Wires connected to the electrical contacts within the socket extend from the socket, passing through the socket housing and post for connection to a voltage source.
The separability of the components of the lens/hood assembly permit the replacement of one or more parts of the assembly without requiring replacement of the entire assembly or fixture. Replacement may be necessitated due to damage to one of the components, or may be desired to give the fixture a different appearance by changing the hood or the reflector retainer cap to another shape, material or finish. In addition, the lens can be replaced if cracked or damaged or if a different color or other optical effect is desired. The water-tight seals provided by the O-rings are readily restored by tightening the appropriate fasteners during reassembly.
The present invention will be more clearly understood from the following detailed description of the preferred embodiments of the invention and from the attached drawings, in which:
a-4d are perspective views of different reflector/retaining cap combinations wherein
Reflector hood 210 extends radially outward and down relative to diffuser lens 310 to capture and reflect downward the light emitted through diffuser lens 310. At the radial center of the hood is flattened area 212, which has a diameter that generally matches the diameter of lens 310 to allow hood 210 to sit level on top of lens assembly 300. Opening 211 is formed in the center of flattened area 212 to allow insertion of a fastener as described below.
The shape of reflector hood 210 can be varied as long as the general shape is capable of providing an effective down-reflector. Exemplary shapes are provided in
Reflector retaining cap 220 is generally mushroom shaped, having a “T”-like cross section with a head 221 and a stem 222. Stem 222 has a diameter selected to closely fit through reflector hood opening 211 and into recess 311 in the upper surface 314 of diffuser lens 310. Head 221, which is typically tapered or convex, has a largest outer dimension larger than that of stem 222 and which generally matches the dimensions of flattened area 212, so that flattened area 212 is covered on its exterior by the base of head 221. A bore 223 is formed in the lower edge of stem 222 and is preferably threaded to mate with threads of retaining screw 230 to fasten reflector hood 210 to lens assembly 300.
In the preferred embodiment of the present invention, reflector retaining cap 220 is made from brass by CNC machining or other machining techniques known in the art. Reflector retaining cap 220 may be made from other metals such as copper, stainless steel, chromed steel, or plastics and polymers and may be formed by machining or molding. The material may be selected to either contrast with or to match the material and finish of reflector hood 210, and may be finished with a protective coating as appropriate. The shape of retaining cap 220 may be selected to continue the profile of the hood, for example, as in
Diffuser lens 310 is generally cylindrical in shape having an upper end 314 and a lower end 308. In the preferred embodiment, upper end 314 is closed with a recess 311 formed at its radial center to accept stem 222 of reflector retaining cap 220. An opening 312 is formed at the center of recess 311 for insertion of retaining screw 230. The top surface of upper end 314 serves as a seat to support flattened area 212 of reflector hood 210. Reflector hood 210 sits on reflector seat 314 and is secured in place by reflector retaining cap 220 and retaining screw 230, which is inserted through opening 312 and screwed into bore 223.
In the preferred embodiment, upper end 314 flares outward and an annular ring forms O-ring seat 313 in the outer edge of the top surface. O-ring 320 is retained within O-ring seat 313, forming a moisture tight seal between the reflector hood 210 and the diffuser lens 310. The compression of O-ring 320 when screw 230 is tightened also prevents rotation of the hood as a result of the frictional force generated between the O-ring and the inner surface of the hood. A plurality of radial fins 315 may be formed on the inside surface of upper end 314 to provide structural reinforcement of recess 311. In addition to the flare at upper end 314, diffuser lens 310 may be tapered slightly outward from the upper end to the lower end.
Lower end 308 of diffuser lens 310 is retained within the upper portion of lens support 350. In the preferred embodiment, lower end 308 is threaded to mate with matching threads in recess 352 of lens support 350. O-ring seat 331 is formed at the top of the threaded portion 309 of lower end 308 to receive O-ring 330, which provides a water-tight seal between diffuser lens 310 and lens support 350. In an alternate embodiment, lower end 308 may have a smooth surface and/or may have one or more O-ring seats for receiving O-rings that create an interference fit within the slightly larger inner diameter of recess 352. An adhesive such as epoxy may also be used to attach lens 310 within lens support 350 for a permanent bond.
Diffuser lens 310 can be transparent or translucent, e.g., frosted or etched, glass, plastic, or similar material, impact resistant, and capable of withstanding outside environmental conditions without degradation. In a preferred embodiment, the diffuser lens 310 is made of injection molded polycarbonate, such as Lexan®. A plurality of longitudinal ribs or other surface topography may be formed on the inner surface of the lens to act as diffusers.
Lens support 350 has an upper portion, with recess 352, a lower portion, and has an exterior shape that is generally cylindrical with a beveled edge. Annular channels 351 may be formed in the outer surface for primarily aesthetic reasons, however, such channels can facilitate gripping the lens assembly 300 during disassembly and reassembly of the lighting fixture 500. Concentric bore 354 is formed in the lower portion for attachment to the top of post 510. As illustrated in
In the preferred embodiment of the present invention, lens support 350 is made from CNC machined brass. Lens support 350 may be made from other metals such as copper, stainless steel, chromed steel, or plastics and may be formed by machining or molding.
In an alternate embodiment illustrated in
Lens support 350 or 106 is connected to the upper end of post 510 by way of socket housing 540 or 140, respectively for the two exemplary embodiments. Attachment may be effected by mating threads, a slip fit with O-rings, or an interference fit.
Lamp socket 530 is disposed into the socket housing 540 and is formed from a non-conductive body of plastic or other durable, non-conductive materials such as ceramic. A pair of metal conductors 535 passes through the post 510 and attach to the lamp socket 530. Lamp socket 530 is configured to receive the conductive prongs of a lamp 420. Lamp 420 is preferably a halogen filament-type lamp but can also be xenon, tungsten filament, incandescent, or other comparable lamp commonly used in similar lighting applications. The voltage supply (not shown), is preferably a low voltage (12V) transformer which is connected to 120 VAC. The conductive wires enter extend out the bottom of the post 510 to provide for connection to a low voltage cable and voltage source, such as a transformer. In the preferred embodiment, lamp socket 530 is commercially-available from BJB of Amsberg, Germany, as Part No. 25.144.1121.90, which is a lamp holder with a push fixing for a 7.8 mm cut out. Selection of other types of lamps and sockets of similar specifications will be apparent to those of skill in the art.
The need to disassemble the upper portion of the light fixture for maintenance or aesthetic purposes, e.g., changing the diffuser lens assembly due to breakage, changing the reflector hood for an alternate appearance, or replacing a burnt out lamp typically arises after the fixture has been mounted in place in the outdoor setting. When lighting fixture 500 is fully assembled, any of the components of the reflector assembly 200, the lens assembly 300, or the lamp 420 may be replaced individually by removing the lens assembly 300 from the post 510, then removing the reflector assembly 200 from the lens assembly 300, and disassembling the lens assembly 300. The process is reversed to put the lighting fixture 500 back together.
Post 510 has an upper end, a lower end, and a substantially hollow interior through which the conductive wires pass to provide a connection to a cable connected to a voltage source (not shown). The lower end of post 510 may have an end plug 520 for attachment of the fixture to a mounting device. End plug 520 has a central bore and a threaded portion. In the preferred embodiment, the threaded portion has external threads of a standard thread pattern, e.g., ½″ NPS male thread, which cooperate with female threads of a molded plastic ground spike which can then be interned into the ground. In this exemplary installation (not shown), conductive wiring, or preferably a low voltage burial-type cable connected to the conductive wiring exits the lower end of post 510 through the central bore, is threaded through an opening in the ground spike, and then continues to termination at the transformer. Other forms of mounting the fixture in place will be readily apparent to those of skill in the art, including mounting the fixture on a riser which may be attached to a ground spike or to another support.
In the preferred embodiment, post 510 is formed from solid copper, which is intended to oxidize to a verde finish and, thus, is preferably uncoated. Other corrosion resistant materials may be used as well, including stainless steel, anodized aluminum, powder-coated or painted metal, or high temperature plastics or composites.
The foregoing description of preferred embodiments is not intended to be limited to the specific details disclosed herein. Rather, the present invention extends to all functionally equivalent structures, methods and uses as fall within the scope of the appended claims.
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