DE20301627U1 - Optoelectronic component for non axial use has light emitting diode placed non centrally on a carrier beneath transparent dome - Google Patents

Abstract

An optoelectronic component for non-axial use comprises a carrier plate (1) on which as an electronic component (2), such as an LED, in electrical contact beneath a transparent dome-shaped cover (3). The component is placed eccentrically with respect to the axis of the domed cover.

Description

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Telephone: (030) 47 41 13 56 * Fax: (030) 47 41 13 57

OSA Opto Light GmbH, Berlin

Optoelectronic SMD component for non-axial applications

The invention relates to an optoelectronic component for non-axial applications. This refers to applications in which the radiation cone is not in the axial direction of the SMD component.

To date, optoelectronic components such as SMD LEDs are known in which the radiation cone lies in the axial direction of the component. This state of the art is shown in Fig. la and Fig. 1b. While Fig. la shows an SMD component 2 arranged on a flat carrier plate 1, Fig. 1b shows a carrier plate 1 provided with a dome, which is designed as a reflector. The SMD component 2 is arranged in this dome. In these known designs, the dome-like transparent capping applied to this component is formed in the axial direction of the component. The SMD components with typical axial radiation can be used in a variety of ways. Examples of areas of application include the coupling of light with these SMD LEDs into transparent light-conducting bodies with the aim of providing information signs, nameplates and company signs. Other areas of application for light coupling are the illumination of prominent buildings or selected parts of these buildings or other structures.

In all of these solutions, which are documented, for example, in the publications DE 43 11 018; DE 43 44 963; DE 195 13 185; DE 297 06 201; DE 298 20 384; DE 92 07 253 and DE 296 03 006, the beam cone is formed in the axial direction of the SMD component. The low height of these components on the one hand and the principle of light coupling on the other hand make it possible to have information presentation and display elements in particularly flat designs.

The special advantage of these SMD components is their low height of S 3mm.

DE 196 54 850 introduced a device for monitoring transparent materials for breakage and danger spots. This device uses the SMD components described above. It is characterized by the fact that two units fitted with SMD LEDs, designed as light rails, and a reference line are arranged on the object to be monitored.

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One of the light rails is used to couple in light, while the other light rail is designed as a detector. By comparing the signals present in an associated evaluation circuit, an acoustic and/or optical signal is triggered if there is a deviation from a target value. The arrangement of the SMD LED in light rails already represents an option for a compact component with which solutions in the field of sensor technology can also be implemented, as the above publication shows.

The invention is based on the object of modifying an optoelectronic SMD component in such a way that, when using the advantage of the flat height of the component, the emitted electromagnetic waves form a beam cone that deviates from the axial direction of the component and approaches the X-axis.

This task is essentially solved by the fact that an eccentricity exists between the SMD component and the dome-shaped transparent capping.

Advantageously, the SMD component is arranged eccentrically to the dome-shaped transparent capping.

An alternative solution provides for the dome-shaped transparent capping to be arranged eccentrically to the SMD component. In principle, the degree of eccentricity can be varied. The eccentricity is determined by the amount of deviation from the imaginary axial extension of the dome-shaped transparent capping.

It is also within the scope of the invention that the SMD component assumes a position on the carrier material that deviates from the usual horizontal position and that the dome-shaped capping is formed in the axial direction of the SMD component.
The dome-shaped capping can also deviate from the axial direction by a certain amount. It is also possible to provide an offset in relation to both the X-axis and the Y-axis.

As a result of the selected arrangement of the SMD component, the optoelectronic SMD component for non-axial applications is characterized by an atypical position of the beam cone. 35

This solution ensures that the advantage of the flat construction height of these components is retained and, in addition, new areas of application are opened up by targeted deflection of the radiation cone.

be developed.

By focusing the beam cone in an angle range of 0° to ± 50°, SMD components open up new areas of application by utilizing the flat height of these components.

The invention will be explained in more detail below using an exemplary embodiment. The accompanying drawing shows:

Fig. 2a shows an SMD component arranged eccentrically on a carrier plate in a schematic representation, partly in section;

Fig. 2b shows an SMD component eccentrically arranged in a cap of a carrier plate in a schematic representation, partly in section;

Fig. 3 shows a changed position of the radiation cone of the SMD component in a diagram.

Fig. 2a shows an SMD component 2 arranged on a carrier plate 1, which is offset by the amount X from the central axis of the dome-shaped capping 3. Both the amount X of the eccentricity and the dome-shaped transparent capping of the SMD component are decisive for the position and the formation of the radiation cone.

Fig. 2b illustrates the SMD component 2 arranged in a dome of the carrier plate 1, which is arranged eccentrically to the imaginary axial extension of the dome-shaped cap. The recess formed as a dome basically serves as a reflector.

Fig. 3 shows a diagram of a possible new position of the radiation cone. It is clearly visible that the radiation cone is in an area that is close to the X-axis. The original radiation cone, which can be assigned to the state of the art, is shown in dashed lines.

The new position of the beam cone and especially the flat design of these units open up new possibilities for the use of SMD components. These components can now be attached directly to objects, for example in the function of an optical sensor and/or receiver for detecting drops of moisture and/or dirt particles on a window, in particular on a windshield of a motor vehicle.

Claims (7)

1. Optoelectronic SMD component for non-axial applications, consisting of a carrier material and an SMD component arranged on this in an electrically conductive manner, which has a dome-shaped transparent capping, characterized in that an eccentricity exists between the SMD component ( 2 ) and the dome-shaped transparent capping ( 3 ). 2. Optoelectronic SMD component according to claim 1, characterized in that the eccentricity exists in the X-axis and/or in the Y-axis. 3. Optoelectronic SMD component according to claim 1 and 2, characterized in that the SMD component ( 2 ) is arranged eccentrically to the dome-shaped transparent capping ( 3 ). 4. Optoelectronic SMD component according to claims 1 to 3, characterized in that the dome-shaped transparent capping ( 3 ) is arranged eccentrically to the SMD component ( 2 ). 5. Optoelectronic SMD component according to one of claims 1 to 4, characterized in that the amount (X) which represents the degree of eccentricity to the axial line is variable. 6. Optoelectronic SMD component according to one of claims 1 to 5, characterized in that the SMD component ( 2 ) assumes a position on the carrier material ( 1 ) which deviates from the usual horizontal position. 7. Optoelectronic SMD component according to one of claims 1 to 6, characterized in that the SMD component ( 2 ) assumes a position on the carrier material ( 1 ) which deviates from the usual horizontal position and that the dome-shaped capping ( 3 ) additionally deviates by a certain amount (X) from the axial extension(s).