Light emitting diode reflector

Electric lamp and discharge devices: systems – Plural series connected load devices – Christmas lights

Reexamination Certificate

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Details

C313S113000

Reexamination Certificate

active

06667582

ABSTRACT:

FIELD OF THE INVENTION
The invention relates to a reflector for a light emitting diode (“LED”). More particularly, the invention relates to a LED reflector which may be used with an LED array for specific purpose lights, eg navigational lights.
BACKGROUND OF THE INVENTION
The use of LEDs for light displays is well known. Typically, a LED has a low power consumption and high longevity. However, another characteristic of a LED is its low candescence compared to conventional lights and wide angle of light diffusion. This makes LEDs unsuitable without modification for certain application. Consequently, where the particular application of an array of LEDs requires the light beam to be concentrated in a particular direction or plane, reflector devices have been used. These applications are typically in the navigational area where concentrated light beams are desirable for beacons.
One approach is disclosed in U.S. Pat. No. 5,130,761 (Tanaka). The reference to this document is by way of illustration of one particular approach to the problem and is not to be construed as an admission that the document is common general knowledge in Australia or was known to persons in Australia at the priority date.
Tanaka discloses an LED array with a reflector. That invention is said to be an LED array having a printed circuit board, a plurality of LED chips disposed linearly on the printed circuit board, each LED chip being capable of radiating a light beam, and a reflection member for reflecting the light beam from the LED chip and to guide the light beam outward of the LED array in the main illumination direction generally parallel to the surface of the board. Consequently, the Tanaka invention is directed to linear arrays of LEDs and reflection of the LED light beam in a direction perpendicular to the LED (ie parallel to the surface of the circuit board upon which the LED chip is mounted).
Tanaka also discloses other arrangements to redirect and/or concentrate the light beam from a linear LED array.
None of the devices disclosed in Tanaka reflect those portions of the LED light beam which travel in a direction between adjacent LEDs in the array. As such, a significant amount of light is not concentrated.
SUMMARY OF THE INVENTION
According to one preferred form of the invention there is provided, a reflector for a LED having a housing and a front portion for emitting a main beam of light, the reflector comprising a body defining a cavity in which the LED may be at least partially located, the body comprising:
(a) at least one wall to substantially surround the perimeter of the housing, said wall being in use spaced from the housing;
(b) a fastener to releasably fasten the LED at least partially in the cavity; and
(c) an opening to permit passage of light from the LED;
wherein the at least one wall of the body is adapted to reflect a substantial amount of incident light from the LED towards the opening.
A reflector according to the present invention is most suitably for a circular array of LEDs each having a housing and a front portion for emitting a main beam of light, the reflector comprising a body having an axis, said body defining a plurality of cavities extending radially from the axis in which the LEDs may be at least partially located, the cavities comprising:
(a) at least one wall to substantially surround the perimeter of the housing, said wall being spaced from the housing and adapted to reflect incident light from the LED along the cavity towards an open end of that cavity; and
(b) a fastener to releasably fasten the LED at least partially in the cavity.
The reflector wall which substantially surrounds the perimeter of the housing substantially increases the amount of light emerging from the opening of the reflector.
According to a particularly preferred embodiment, the space between the at least one wall and the housing defines a gap through which light passes towards the open end of the cavity. Such a gap increases the amount of light which is reflected towards the opening by enabling the reflector to have shape or surface features which are separate from the LED housing and which direct the light to the open end of the cavity. According to another embodiment, the space may be filled with a transparent medium through which light passes towards the open end of the cavity. The transparent medium according to this preferred embodiment may be any suitable medium. Preferably it may form a seal to stop water from entering the cavity. Preferably, the LED is fastenable substantially within the cavity so as to maximise the amount of light which is reflected. Where the LED is fastened substantially within the cavity, then preferably it is fastenable at one end of the cavity and preferably at the opposite end to the opening. This allows for greater reflection of light through the opening by providing a greater area of wall to reflect the light.
According to another preferred embodiment, the depth of the cavity approximates the depth of the LED so the upper extremity of the LED does not extend significantly from the body. In this way, any divergent light emitting from the upper region of the LED which is incident on the wall will be reflected towards the opening.
Preferably, the at least one wall may be extended from the body to define a pair of divergent surfaces. These divergent surfaces permit the light emitting from the cavity to extend substantially along one plane but reflects any incident light upon those surfaces in the same direction. This means the light may radiate in substantially one plane but not substantially in another plane. This is particularly desirable in navigational lights for example in the marine environment, where light travelling upward from a beacon is of little use to mariners who are in approximately the same plane as the beacon.
The direction of reflection of the light may be determined by any suitable mechanism. According to one preferred embodiment, the direction of reflection of the light is determined at least in part by the shape of the wall. According to a particularly preferred embodiment, the shape of the wall substantially determines the direction in which the light is reflected. Preferably the wall is substantially concave in shape and preferably it is axially symmetrical. The direction of reflection may also be determined at least in part by features of the surface of the wall.
According to another preferred embodiment, the features of the surface of the wall substantially determine the direction of reflection of the light. In a particularly preferred embodiment, the wall comprises ridges which increase the amount of light reflected towards the open end of the cavity of the reflector.
Conveniently, the cavity may be formed by the body being at least two parts which are connectable together. This permits easier replacement and location of the LED in the cavity, especially when the depth of the cavity is similar to the depth of the LED so the upper extremity of the LED does not extend from the cavity.
In such a case, the body preferably comprises complimentary parts which are connectable together. Preferably the complimentary parts are identical so as to minimize the costs of production. The complimentary parts preferably have portions of the cavity formed therein so that upon their connection together the cavity is formed. Preferably, the fastener of the LED would also be formed with such connection. For example, the slots for the mounting pins of an LED may be formed when two parts are connected.
According to a particularly preferred embodiment, a plurality of reflectors according to the present invention are arranged in an array so as to maximize the amount of light emitted. Preferably the reflectors are arranged in a circular array, and preferably each reflector is arranged so as to have its opening radially positioned in an outward direction. This arrangement is used when the array is used for 360° light applications such as with beacons. Of course, there is no reason why a linear array for other applications could not be adopted.
The circular arrays

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