EP3411626A1

EP3411626A1 - Light module for a motor vehicle illumination device

Info

Publication number: EP3411626A1
Application number: EP17703145.7A
Authority: EP
Inventors: Rolf CONNERTH
Original assignee: Automotive Lighting Reutlingen GmbH
Current assignee: Marelli Automotive Lighting Reutlingen Germany GmbH
Priority date: 2016-02-04
Filing date: 2017-02-03
Publication date: 2018-12-12
Anticipated expiration: 2037-02-03
Also published as: JP2019504457A; EP3411626B1; CN108603647A; CN108603647B; US20190041031A1; DE102016101999A1; US10400990B2; WO2017134258A1

Abstract

What is presented is a light module for a motor vehicle illumination device, comprising at least one semiconductor light source which is arranged on a circuit carrier, and comprising a reflector which is coated with a varnish and which has a mounting region coated with the varnish, said mounting region having a broad side and a narrow side and the circuit carrier being secured thereto by an adhesive bond. The light module is distinguished by the fact that the mounting region has a surface with projections which are coated with the varnish and on which the circuit carrier lies at a distance from the remaining surface of the mounting region and wherein the adhesive bond is produced by an adhesive applied next to the projections or between the projections over at least part of the remaining surface of the mounting region.

Description

Light module for a motor vehicle lighting device Description

The present invention relates to a light module for a motor vehicle lighting device according to the preamble of claim 1.

Such a lighting device is known per se and has at least one on a circuit carrier

arranged semiconductor light source and a reflector, wherein the reflector is coated with a lacquer and having a lacquer-coated mounting region having a broad side and a narrow side and to which the circuit carrier is held by an adhesive connection. The semiconductor light source is, for example, a

Light emitting diode, and the circuit carrier is for example a board or more generally, a component to which the

Semiconductor light source is mechanically fixed and that is used for electrical contacting of the semiconductor light source. The lacquer layer is a layer several microns thick, the irregularities in the plastic surface

should balance on the optical surface through

Metallization is generated. The metallization creates a high-quality reflection surface. The metal layer is in turn of a special

Protective layer protected. The metal layer and the

Protective layer are considerably thinner than the paint layer per se and together. It is currently common practice to glue the circuit board during assembly of the lighting device with the already finished coated and painted reflector. The serving for the production of adhesive bond

Mounting surface must have a reproducible quality, in particular the position of the semiconductor light source whose light exit surface, for example, only about one

Square millimeters large, is sufficiently accurate too

define. The position with which the semiconductor light source can be reproducibly fixed in series production influences the optical properties of the

Arrangement of semiconductor light source and reflector and depends, for example, on the layer thickness of the paint layer on the mounting area. At present, two painting processes in the

Serial production used. When spray painting, the paint with small pots on the reflector surface

injected. The droplets run on the reflector surface, creating a smooth surface. In this way, lacquer layers can be produced with very precisely defined thicknesses. Areas of a component that should not be painted can be covered in this process. When flood coating the object to be painted in one and moved through a paint curtain of liquid paint through. Paint flows over an edge and over the reflector to be painted. The process is very efficient, but it is completely coated with paint. However, it can not be guaranteed without further ado that the mounting region of the reflector after painting always meets the high requirements for a defined layer height and uniformity of the thickness of the lacquer layer and the adhesive layer. These disadvantages affect the accuracy with which the

Semiconductor light source can be mounted in the reflector and thus lead to undesirably large tolerances of

Position of the semiconductor light source in the reflector. Against this background, the object of the present invention is to specify a lighting device which does not have these deficiencies or at least only to a significantly reduced extent. This object is achieved with the features of claim 1. The invention differs from the above-mentioned and known per se known prior art by the characterizing features of claim 1. Accordingly, the mounting portion has a surface from the protrude protrusions, which are coated with the paint and on which the circuit carrier in a Distance from the rest of the surface of the mounting area rests and the

Adhesive bond is produced by an adhesive, in addition to the projections or between the projections on at least part of the remaining surface of the

Mounting area is applied.

Characterized in that the circuit carrier rests on the projections at a distance from the remaining surface of the mounting region, a volume between the projections can be accommodated, in which the adhesive, with which the adhesive bond is made, can be accommodated without a thickness of the self-adjusting layer thickness of the adhesive, the position of the semiconductor light source with respect to the

Reflector influenced. Rather, this position is determined by the geometry of the projections and the thickness of the

Jumps between the leaps and the leap

Circuit board resting paint layer determined. It has been shown that it is due to

Surface tension effects to edge offset of paint on the projecting out of the remaining surface of the mounting region protrusions comes. This edge escape causes the projections to hold only a very thin lacquer layer, the layer thickness of which

Layer thickness of the lacquer layer on the adjacent to the projections areas of the mounting area is largely independent. For this reason is also the

Positioning accuracy of the protrusions

resting circuit board largely from the

Layer thickness of the paint layer on the adjacent to the projections areas of the mounting area independently. The positioning accuracy is thus in particular of

Variations in this layer thickness largely independent, which in the coating of the reflectors from reflector to

Reflector can occur. In the end, a smaller fluctuation range of the positions of the results

Circuit carrier in the reflectors. This advantage arises as an effect of the Kantenflucht of the paint on the

Projections automatically and without additional effort.

In a preferred embodiment, the surface is part of a broad side of the mounting area. It is also preferable that the narrow side of the Mounting portion has at least one protruding from the narrow side projection, with the paint

is coated and on which the circuit carrier is applied.

A further preferred embodiment is characterized in that the projections have a shape in a cross section perpendicular to the remaining surface of the broad side and / or the remaining narrow side, which form a

rectangular or trapezoidal base and a subsequent to the base convex curvature composed.

It is also preferred that convex curvature passes without step and without edge in the base.

It is also preferred that the convex curvature has the shape of a circular arc.

A further preferred embodiment is characterized in that the projection in a plan view a

has linear form.

It is also preferable that the projection has a longitudinal direction parallel to the surface from which it protrudes and perpendicular to its height, and a width parallel to the surface perpendicular to the height and perpendicular to the longitudinal direction, with its longitudinal length at least five times as big as his

Width. It is also preferred that the projection has a point or circular shape in a plan view.

It is also preferable that the projection has a

frusto-conical socket and a subsequent to the base distal end in the form of a convex Owns ball segment.

A further preferred embodiment is characterized in that a height of the projection is 0.6 mm to 1 mm and that its width at the widest point is 0.8 to 1.5 mm.

It is also preferable that the radius of the circular section is 0.3-0.6 mm and that a height of the pedestal is 0.8 times to 1.2 times the height of the convex curvature.

Further advantages result from the dependent ones

Claims, the description and the accompanying figures.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. In this case, the same reference numerals in different figures denote the same or at least functionally comparable elements. In each case, in schematic form:

Figure 1 shows the technical environment of the invention in the form of a

Sectional view of a

Motor vehicle lighting device;

Figure 2 shows a cross section of a painted cuboid to

Explanation of an exploited effect of the invention; Figure 3 shows a detail of a mounting portion of a reflector having features of the invention;

Figure 4 shows a detail of a mounting portion of another reflector having features of the invention; and

Figure 5 is a section through one of a reflector having features of the invention.

In detail, Figure 1 shows a

Automotive lighting device 10 with a housing 12, the light exit opening is covered by a transparent cover plate 14. In the interior of the housing, a light module 16 is arranged. The light module 16 has a semiconductor light source 18, which on a

Circuit carrier 20 is attached. The circuit substrate 20 is connected by an adhesive connection 21 with the mounting portion 22 of a reflector 23. The reflector 23 has in its mounting region 22 projections 24, in which the

Circuit carrier 20 is present. In the applied state, the circuit carrier 20 is in a predetermined

Position with respect to the reflector 23. By the

Adhesive connection 21, the circuit carrier 20 is held in this position.

Figure 2 illustrates that in the invention

exploited effect of edge escape. 2 shows a cross section of a cuboid 26 having a surface. The cuboid extends in a to

Drawing plane vertical direction. Side surfaces 30 of the cuboid appear as edges in FIG. 2, and edges 32 of the cuboid lying between the side surfaces appear as corners in FIG. For the following it is assumed that the cuboid has the same surface finish has like the reflector 22 before applying the

Lackschicht, so that sets in the surface / paint system, the same surface tension. The lacquer layer 34 to be applied may be a first smoothing lacquer layer which smooths out unevennesses of the reflection surface of the reflector, which is preferably made of plastic or metal. However, the lacquer layer 34 to be applied can also be a transparent cover layer which projects a high-gloss metallic reflection layer of the reflector

mechanical damage due to scratches and / or to protect against corrosion.

When applying the lacquer layer 34, a substantially thinner thickness of the lacquer layer is established on the edges 32 than on the lacquered surfaces adjoining the edges 32

Surfaces 30. This phenomenon results from the

Surface tension of the paint layer covering the paint

in a sense pull away from the edges. This effect is referred to in this application as Kantenflucht.

This effect occurs in particular with lacquer layers based on the solvent ethyl acetate. The use of such paint layers for reflectors of

Automotive lighting devices is common.

The thickness of the lacquer layer remaining on the edges 32 is largely independent of the thickness of the lacquer layer 34, which adjusts to the surfaces 30 adjacent to the considered edge 32.

This means, in particular, that the position of a circuit carrier 20 resting on such edges 32 largely depends on the thickness of the lacquer layer 34 on said surfaces 30 is independent. Fluctuations in this layer thickness, which can occur when coating the reflectors from reflector to reflector, therefore, do not affect the positional accuracy of the later-to-be-bonded circuit carriers.

FIG. 3 shows a cross-section of a projection which protrudes from a surface of a mounting region 22. Let the surface of the mounting area be an x-y plane of a right-handed and right-angled coordinate system. Then the direction in which the projection 24 from the

Surface sticking out, the z-direction. If such a projection 24 together with the adjacent to him

Surface is covered with a resist layer, the surface tension acts mainly in the plane of the drawing, which is an x-z plane in the illustrated case.

The shape of the projection is composed in this plane of a base 24.1 and a convex dome 24.2 together. The base 24.1 has in one embodiment the shape of a rectangle or, as shown here, the shape of a trapezoid whose shorter side of the dome 24.2 faces. The dome preferably has one

Cross section in the form of a circular section. In one embodiment, the extension of the projection in the y-direction perpendicular to the plane of the drawing is greater than the extent in the x-direction lying in the plane of the drawing by more than a factor of five. It is then a rib-like projection whose outgoing from the base distal end in the shape of a convex

Cylinder segment has a circular-shaped base.

In a plan view (viewing direction: minus z-direction) such a projection has a linear shape. In another embodiment, the projection has a frusto-conical base and a subsequent to the base distal end in the form of a convex

Sphere segment. In demarcation to the rib-shaped

Projections, these projections can be referred to as mounting points.

In a plan view, such a projection has a circular or punctiform shape.

It is also preferred that the dome transition without tangent and with constant curvature tangentenstetig in the base. The height of the protrusion to be measured in the z-direction is preferably 0.6 mm to 1 mm. Its width is at the widest point preferably 0.8 to 1.5 mm. In the case of a circle - shaped dome, the radius of the

Section of the circle preferably 0.3-0.6 mm. The height of the rectilinearly limited base is preferably 0.8 times to 1.2 times the height of the convex dome.

FIG. 4 shows mounting regions of a reflector 23 of an exemplary embodiment of an inventive device

Lighting device. The reflector has in addition to the mounting areas in particular a reflection surface.

A first mounting area 22 has a first surface 36, which is parallel to an x-y plane, and has a second surface 38 parallel to an x-z plane. The first surface is a broad side of the mounting area, and the second surface is a

Narrow side of the mounting area. From the first surface protrude first projections 24. The first projections 24 each have a cross section (in xz planes), as shown in FIG. In a direction perpendicular to this cross section projections have the shape elongated lines. The lines do not run in alignment, but they run at a distance from each other so that they define a plane. In this case, the projections 24 each rise so far out of the surface of the rest of the mounting area 22, that their respective farthest from the rest of the surface of the mounting area extending lines lie in a plane. This plane forms a mounting plane for the circuit carrier 20. The circuit carrier 20 is in this plane to the

Projections on and is thus fixed in the z-direction.

Projections 24 also protrude from the second surface and thus form a respective stop in the y-direction for a circuit carrier which has a contact surface parallel to the x-z plane.

The second mounting portion is different from the first mounting portion in that it has a V-shaped notch configured to receive one out of a first

Circuit board outstanding pin record. This allows a circuit carrier, incidentally on the

elongated ribs rests, also be centered in the x-direction. The recesses 40 in the mounting areas serve the reflection surface 42 with the light arranged on the circuit carrier

To illuminate the semiconductor light source.

FIG. 5 shows a preferred embodiment of a V-shaped notch in the second surface 38 (ie the narrow side) of the second mounting region from FIG. 4. Here, too, a protrusion protrudes from the second surface

elongated projection 24. This projection has two elongated portions 24.3, 24.4 which extend in a straight line and are arranged in a V-shape. In the top of the V-shape thus formed become these two Sections connected by a curved portion in space 25, which is bounded by a saddle surface. The saddle surface is stepless and steady

Curvature in the cylinder shell convex

Interfaces of the elongated sections over.

This shape also results in the tip of the V-shape evenly small thickness of the paint layer, which contributes to the desired positioning accuracy.

At their free ends are the rippenarteigen and

linearly extending projections 24 preferably each convex rounded. The convex surfaces go in each case continuously and with continuous curvature in adjacent

rectilinear surfaces of the projections over. The shape of the transition between the surface from which protrude the projections, and the projections, however, are of

Of minor importance, since they have no effect on the accuracy with which a circuit carrier can be positioned in each case.

Claims

Light module (16) for a

Motor vehicle lighting device (10), with at least one semiconductor light source (18), which is arranged on a circuit carrier (20) and with a reflector (23), which is provided with a lacquer (34).

is coated and the one with the paint (34)

coated mounting portion (22) having a broad side (36) and a narrow side (38) and on which the circuit carrier (20) by a

Adhesive bond (21) is held, characterized in that the mounting portion (36) has a surface from the projections (24)

protrude, which are coated with the lacquer (34) and on which the circuit carrier (20) at a distance from the rest of the surface of the mounting area and wherein the adhesive joint (21) by one of the projections or between the projections on at least a part of the remaining Surface of the mounting area applied adhesive is generated.

Light module (16) according to claim 1, characterized

characterized in that the surface is part of a Broad side (36) of the mounting portion (22).

Light module (16) according to claim 2, characterized

characterized in that the narrow side (38) of the

Mounting portion (22) at least one of the

Has narrow side outstanding projection (24), which is coated with the paint and on which the

Circuit carrier (20) is applied.

Light module (16) according to claim 2 or 3, characterized in that the projections in a direction perpendicular to the remaining surface of the broad side and / or the other narrow side cross section of a shape

consisting of a rectangular or trapezoidal base (24.1) and a convex curvature adjoining the base (24.2)

composed.

Light module (16) according to claim 4, characterized

characterized in that the convex curvature (24.2) passes without a step and without edge in the base (24.1).

Light module (16) according to claim 5, characterized

characterized in that the convex curvature (24.1) has the shape of a circular arc.

Light module (16) according to one of the preceding

Claims, characterized in that the projection (24) in a plan view of a linear shape

owns.

Light module (16) according to claim 7, characterized

in that the projection (24) is parallel to the surface from which it protrudes and

perpendicular to its height, extending longitudinal direction and has a width parallel to the surface, at right angles to the height and at right angles to the longitudinal direction, with its length in the longitudinal direction at least five times as great as its width.

9. light module (16) according to any one of claims 1-6,

characterized in that the projection (24) has a point or circular shape in a plan view.

10. light module (16) according to claim 9, characterized

characterized in that the projection (24) has a

truncated cone-shaped base and a subsequent to the base distal end in the form of a convex spherical segment has.

11. Light module (16) according to one of the preceding

Claims, characterized in that a height of the projection is 0.6 mm to 1 mm and that its width at the widest point is 0.8 to 1.5 mm.

12. Light module (16) according to claim 6, characterized

characterized in that the radius of the circular section is 0.3 - 0.6 mm and that a height of the base is 0.8 times to 1.2 times the height of the convex curvature.