Illumination – Plural light sources – With support
Reexamination Certificate
1999-11-24
2001-08-07
Sember, Thomas M. (Department: 2875)
Illumination
Plural light sources
With support
C362S311040, C362S227000, C362S555000, C428S901000
Reexamination Certificate
active
06270236
ABSTRACT:
BACKGROUND INFORMATION
In lighting units with LEDs, e.g., additional brake lights for motor vehicles, the LEDs are usually mounted on a circuit board together with appropriate current limiting resistors. To protect the LEDs and optionally to improve the light distribution, a protective lens (a glass panel in the simplest case) is placed in front of it. German Pat. No. 196 35 564 describes that resistors may be designed as wired components, surface mount devices (SMD) or in the form of a resistance layer on the circuit board.
Japanese Pat. No. 5119706 describes a lighting unit where LED chips are mounted on a glass panel. To this end, the glass panel is coated on one side with a layer of indium-tin oxide (ITO) structured in a photolithographic process. First contact areas are applied in the form of a gold layer at the points where the LED chips are to be placed, and second contact areas also in the form of a gold layer are applied at adjacent locations, and the LED chips are attached to the first contact areas by die bonding with the help of electrically conducting adhesive and are bonded to the second contact areas by wire bonding. Due to the structure and mounting of the LED chips, they emit light in the direction away from the glass panel holding them.
Japanese Pat. No. 4199754 describes a similar lighting unit which differs from the conventional lighting unit described above in that a nickel-phosphorus layer is applied to the structured ITO layer and then a gold layer is applied to this, with the LED chips being attached to the gold layer over the first and second contact areas by die bonding and wire bonding. The nickel-phosphorus layer assumes the function of current limiting resistors for the individual LEDs. Here again, due to the structure and mounting of the LED chips, they emit light in the direction away from the glass panel holding them.
Surface mount (SMD) LEDs which, when assembled on a circuit board, have their light emitting side facing the circuit board, with the light passing through a hole in the circuit board, are described by Stanley Electric Sales of America, Inc. (online Internet address: URL: http://www.stanleyelec.com/smt/rm.htm (as of Nov. 17, 1998). Similar LEDs are also distributed by Siemens AG under the name “Hyper TOPLED® RG.”
SUMMARY
An object of the present invention is to reduce the manufacturing and design complexity of lighting units having LEDs, in particular with regard to different shapes and dimensions of lighting units.
According to the present invention, this object is achieved by providing a lighting unit having a transparent carrier panel provided with electrically conductive structures on one side, and surface mount LEDs having terminals on both sides of a light emitting side that are mounted on the carrier panel with their terminals in contact with the conductive structures and with the light emitting side facing the carrier panel.
The LEDs may be, for example, the above-mentioned LEDs from Siemens or Stanley Electric. The transparent carrier panel assumes the function of a protective lens as well as the supporting function for the LEDs, with the conductive structures on the carrier panel establishing the electric connections to the LEDs. According to the respective design of the conductive structures, the LEDs may be controlled individually or in groups connected in parallel or in series. Since the LEDs are surface mount devices, the carrier panel may be assembled with the LEDs by the simplest method, regardless of its respective size and shape, with the different areas of the carrier panel being assembled with different LEDs, e.g., of different colors. In this way, additional brake lights, rear lights and flashing lights for vehicles, either individually or both integrated into one lighting unit, interior lights for vehicles, trunk lights, glove compartment lights, traffic lights, lights for advertising purposes or display lights in various sizes and shapes can be manufactured at a minimal manufacturing expense. In addition, the lighting unit according to the present invention is characterized by an especially small overall height. The transparent carrier panel itself may additionally be provided with imprints, e.g., for marking display fields or advertising imprints, and there are no adjustment problems with regard to the position of the LEDs and the imprints due to the design of the lighting unit according to the present invention.
The transparent carrier panel may be a glass or plastic panel, which may be more or less transparent and may be colored, depending on the application, and may be designed as reinforced glass or laminated safety glass for high mechanical stresses. The carrier panel may also have optical structures such as grooves, grids or lenses for light scattering or light bundling on the side facing away from the mounting side.
The conductive structures on the carrier panel allow the light emitted by the LEDs to pass through the carrier panel, which is accomplished either by the fact that the carrier panel remains uncovered by the conductive structures in the areas directly opposite the light emitting sides of the LEDs, or by the fact that the conductive structures themselves are transparent. In the latter case, the conductive structures preferably include an indium-tin oxide (ITO) layer which is structured either at the time when the carrier panel is applied or by subsequent removal of material, in the latter case in an especially simple manner by introducing separation grooves by using a laser. As an alternative, the conductive structures may be made of a conductive plastic or they may be formed by metallization or by applying conductive pastes, e.g., by printing.
The LEDs may be attached to the conductive structures with a conductive adhesive at their terminal points, so that additional electrically conductive contact areas may be applied to these structures at the respective locations by coating or by applying a conductive paste.
To increase their mechanical stability, the LEDs may be attached to the carrier panel by a transparent adhesive on their light emitting side.
The electrically conductive structures are preferably made of a resistor material, e.g., in the case of the ITO layer, to which are additionally applied electrically conductive current leads, e.g., by screen printing, with the resistor material between the current leads and the terminals of the LEDs forming current limiting resistors for the LEDs.
REFERENCES:
patent: 5367441 (1994-11-01), Wustlich
patent: 6106127 (2000-08-01), Fuwausa
patent: 196 35 564 (1997-03-01), None
Patent Abstracts of Japan, JP5119706, Stanley Electric Co. Ltd. Described in the Specification.
Patent Abstracts of Japan, JP4199754, Stanley Electric Co. Ltd. Described in the Specification.
Stanley Electric Sales of America, Inc. http://www.stanleyelec.com/smt/rm.htm, Nov. 17, 1998. Described in the Specification.
Kenyon & Kenyon
Negron Ismael
Sember Thomas M.
Siemens Aktiengesellschaft
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