DE102019106934A1 - Light module for a lighting device of a motor vehicle - Google Patents

Abstract

A light module (2) is provided for a lighting device of a motor vehicle, the light module (2) comprising a light source (4) and a light guide (6), the light guide (6) comprising: a flat light guide section (8) with a central one Light guide plane (XY); a light deflecting section (16), wherein the light deflecting section (16) comprises a number of transparent deflecting surfaces delimiting the flat light-guiding section on the narrow side, which in pairs enclose a material-side angle of 90 °, an edge which delimits at least one of the deflecting surfaces following a base curve .

Description

The invention relates to a light module for a lighting device of a motor vehicle.

In the field of lighting devices for motor vehicles, transparent components made of glass or plastic are often used in order to extract a legally prescribed light distribution from a specific light exit surface from the light of one or more light sources. Here, light is often coupled into transparent light guides, which is then held in the transparent material by total reflection until it is specifically reflected out of the material and / or refracted. The light is partially or completely collimated when it enters the material. A great advantage is that the light, after it has entered the material, can be reflected almost without loss through total reflection. At the light entry and exit surfaces, the light can also be collimated or scattered by refraction. In this way, a large number of optical surfaces can be generated in a single component, creating a high degree of flexibility.

It is therefore the object of the invention to create a light module for a lighting device of a motor vehicle with an improved light guide.

The object on which the invention is based is achieved by a light module according to claim 1. Further advantageous embodiments can be found in the subclaims and in the following description.

One aspect of this description relates to a light module for a lighting device of a motor vehicle, the light module comprising a light source and a light guide. The light guide includes: a flat light guide section having a central light guide plane; a light deflecting section, the light deflecting section comprising a number of transparent deflecting surfaces delimiting the flat light-guiding section on the narrow sides, which in pairs enclose a material-side distal angle of 90 °, wherein an edge which delimits at least one of the deflecting surfaces follows a base curve; and a light coupling section delimiting the light guide section for coupling in a light generated by the light source, the light guide section comprising a concave curvature in a section according to the light guide plane, and wherein the light source, the concave curvature of the light input section and the base curve of the edge of the light deflection section are matched to one another in this way that a light bundle generated by the light deflecting section is collimated along a main direction of propagation and is homogenized transversely to the main direction of propagation.

An advantageous example is characterized in that the concave curvature in an opening direction of the base curve is at least partially more strongly curved than against the opening direction.

The light coupling section shifts the focal point due to the greater curvature in the opening direction of the base curve. Consequently, a light bundle diverging in the light guide plane is generated from light originating from the light source, in which the density of the light rays increases in the opening direction of the base curve. As a result, the distal areas of the light deflecting section which are further away from the light coupling section are illuminated at least as well as the proximal areas of the light deflecting section. By following the base curve, the light deflecting section advantageously generates a light bundle whose rays run parallel to one another. This results in the possibility of a light distribution that is more homogeneous in cross section within the collimated light beam emitted by the light deflecting section.

The light deflecting section for deflecting light and collimation can be enlarged, which increases the width of the collimated light beam. As a result, the light efficiency is improved.

The use of stepped surfaces for collimating the light can advantageously be prevented, as a result of which interruptions in the light distribution emitted by the light guide that are visible to the viewer are avoided.

Since the light deflecting section itself behaves similarly to a metallized reflector surface, a reflective surface coating of the deflecting surfaces can be dispensed with.

An advantageous example is characterized in that the light guide section comprises a number of pairs of deflecting surfaces, which in pairs enclose the material-side angle of 90 °, and that proximal or distal edges at which the deflecting surfaces abut a common paraboloid of revolution or a common parabolic cylinder consequences. A beam offset in the event of reflection at the deflecting surfaces generally results in an angle error. By increasing the number of pairs, the respective deflection surfaces are reduced and the path that a light beam travels to deflect is thereby reduced. As a result, both the aforementioned beam offset and the resulting angle error are advantageously reduced.

One advantageous example is characterized in that the light deflecting section comprises two, three or four pairs of deflecting surfaces. For a flat light guide section, the number of two, three or four pairs of deflection surfaces represents a compromise between a reduced beam offset and the manufacturing capabilities.

One advantageous example is characterized in that a respective one of the deflection surfaces encloses an angle of 45 ° with the light guide plane at least in an imaginary extension in a section running perpendicular to the light guide plane. A beam striking a first one of the deflecting surfaces is advantageously reflected onto an adjacent second one of the deflecting surfaces. After a reflection on the second deflecting surface, the light beam is emitted in a direction which corresponds to a direction of reflection that would result from a single metallized reflection surface running through the edge.

An advantageous example is characterized in that the light coupling section comprises a convex curvature in a section perpendicular to the light guide plane. The light beams coupled into the light guide advantageously converge due to the convex curvature in a plane which is perpendicular to the light guide plane. The light bundle coupled in via the light coupling section is guided under total reflection on light guide surfaces of the light guide running parallel to one another as far as the light deflection section.

An advantageous example is characterized in that a light decoupling section delimits the flat light guide section on the narrow side. With the aid of this light coupling-out section, what is known as a slit light is advantageously provided, which enables a narrow, slit-shaped appearance.

An advantageous example is characterized in that the light guide comprises: a light decoupling section; a further flat light guide section which is arranged between the light output section and the flat light guide section; and a further light deflecting section which is arranged between the flat light guide section and the further flat light guide section. By providing the further light deflecting section, the degree of freedom in the structural design of the light module is increased. For example, the installation space can be optimized. Furthermore, it is possible to improve the direction of emission of the light source and its arrangement on a circuit board or the arrangement of several light sources on a circuit board.

A further aspect of this description relates to a lighting device for a motor vehicle, the light module according to one of the above aspects being arranged in a housing with a light exit opening.

A further aspect of this description relates to a motor vehicle which comprises the lighting device according to the preceding aspect.

• 1 einen schematischen Schnitt des Lichtmoduls;
• 2-4 jeweils einen schematischen Schnitt eines Lichtleiters aus 1;
• 5 eine schematische Draufsicht auf den Lichtleiter; und
• 6 eine schematische Seitenansicht des Lichtleiters.

In the drawing show:

• 1 a schematic section of the light module;
• 2-4 each a schematic section of a light guide 1 ;
• 5 a schematic plan view of the light guide; and
• 6th a schematic side view of the light guide.

1 shows a light module 2 for a lighting device of a motor vehicle in a schematic view. The light module 2 includes a light source 4th , in particular a semiconductor light source and a light guide 6th . The light source 4th and the light guide 6th are arranged in a form not shown in a housing of the lighting device, the lighting device being arranged on the motor vehicle. That via a light coupling-out section of the light guide 6th Decoupled light is emitted from the lighting device via a light exit opening in the housing.

The light guide 6th includes a flat light guide section 8th , which follows a middle light guide plane XY and is shown in a section along the middle light guide plane XY. A light coupling section 10 delimits the flat light guide section 8th narrow side and includes a concave light coupling surface 12th which curves more strongly in the x-direction than against the x-direction.

Alternatively or additionally, the light source is 4th to the light coupling surface 12th arranged eccentrically in the x-direction, the concave curvature in the light guide plane XY being spherically curved.

In a further example, the light coupling area 12th and the base curve for a distal edge 22nd determined simulatively and iteratively taking into account the maintenance of luminous flux. Optical methods are used here, whereby it must be taken into account that the base curve changes the brightness. For example, a homogeneous, parallel light bundle is transmitted through the light exit surface counter to the direction of light propagation onto a parabolic reflector surface, in which the base curve lies, propagates and determines the brightness distribution on the parabolic reflector surface, which must be generated by the light coupling surface. In the next step, light from the light source is propagated through the light entry surface into the light guide. The reflector surface - and thus the base curve - is adjusted in the next step so that the light bundle leaves the light guide in parallel. If the light distribution is not sufficiently homogeneous, a further calculation cycle starts, beginning with the propagation of a homogeneous parallel light bundle through the light entry surface onto the reflector surface to redefine the light entry surface.

One over the light coupling surface 12th coupled light beam 14th experiences a compression of the light rays over an angular range in the x-direction due to the stronger curvature in the x-direction. The light coupling surface is in a section perpendicular to the light guide plane XY 12th convexly curved. The course of the convex curvature in a respective section perpendicular to the light guide plane XY remains essentially the same.

The light coupling section 10 the flat light guide section comprises opposite 8th a light deflecting section 16 . The light deflecting section 16 includes a number of the flat light guide portions 8th narrow-sided and transparent deflection surfaces 18th and 20th . The transparent baffles 18th and 20th in a section AA perpendicular to the light guide plane XY, pairs form a distal material-side angle of 90 °.

The distal edge 22nd , in which the two deflection surfaces 18th and 20th collide follows a base curve. The base curve follows a parabola in sections, for example, with an axis parallel to the x-axis, the transitions between these sections being constant in curvature. The parabola is the geometric location of all points whose distance from a focal point is the same as the distance from a guideline. The parabola opens in the x direction. The base curve lies in a surface, for example 24 which follows a paraboloid of revolution or a parabolic cylinder in sections. A respective proximal edge 28 , 30th is located between the deflection surface 18th , 20th and an equidistant from the light guide plane XY, the light guide section 8th limiting light guide surface 32 , 34 . The proximal edges 28 and 30th lie in one to the plane 24 parallel surface 36 . In an alternative example, the surface follows 36 at least in sections a paraboloid of revolution or a parabolic cylinder and the surface 24 runs equidistant to the surface 36 .

A plane in which a right angle on the material side between the deflection surfaces 18th and 20th includes a normal vector which is parallel to a tangent vector of the base curve.

The base curve is parabolic, but deviates from an actual parabola, so that the base curve, the light source 4th and the concave curvature of the light coupling section 8th are matched to one another in such a way that one of the light deflecting section 16 generated light beam along a main direction of propagation 42 of the light beam is collimated and transverse to the main direction of propagation 42 is homogenized

Two narrow-sided boundary surfaces 38 and 40 run parallel to each other and parallel to the main direction of propagation 42 of the light deflecting section 16 deflected light beam. The light coupling section 10 is characterized by a protrusion, which is an imaginary extension 44 the boundary surface 40 protrudes and to the light coupling surface 12th leads. This allows a proximal end 46 of the light deflecting section 16 in the direction of the imaginary extension 44 extend.

In one example, the light coupling-out section (not shown) closes on the narrow side in the direction 42 to the flat light guide section 8th on. In another example, a further flat light guide section is provided, which is attached to the flat light guide section via a further light deflection section 8th connected. The further flat light guide section is thus between the light output section and the flat light guide section 8th arranged.

The 2 , 3 and 4th each show an embodiment of the light deflecting section 16 with a respective number of two, three and four pairs of deflection surfaces 18a , 18b , 18c , 18d , 20a , 20b , 20c , 20d .

5 shows a schematic plan view of an embodiment of the light guide 6th with which to the flat light guide section 8th light decoupling section adjoining on the narrow side 50 . Two courses of light rays are shown by way of example, with a deflection at the proximal end 46 of the light deflecting section 16 takes place and a deflection at a distal end 48 of the light deflecting section 16 he follows. The light deflecting section 16 thus generates a light bundle, which runs along the main direction of propagation 42 is collimated and transverse to the main direction of propagation 42 is homogenized. The light output section 50 includes cylindrical outcoupling structures.

6th shows a schematic side view of the light guide 6th in y-direction. One over the light coupling surface 12th coupled light beam 52 is from the deflection surface 20th into a ray of light 54 converted, which runs perpendicular to the light guide plane XY. The ray of light 54 is from the deflection surface 18th into a ray of light 56 transformed. The two rays of light 52 and 56 run parallel to the light guide plane XY. Project the two rays of light 52 and 56 onto the light guide plane XY, the light guide plane XY represents an imaginary plane of reflection for the light rays 52 and 56 ready at which the angle of incidence of the light beam 52 equal to the angle of reflection of the light beam 56 is. This is how the light deflecting section works 16 similar to a mirrored reflector that goes through the edge 22nd runs. In comparison to the mirrored reflector, there is essentially only an offset, for example in the form of the length of the light beam 54 .

Claims (10)

A light module (2) for a lighting device of a motor vehicle, the light module (2) comprising a light source (4) and a light guide (6), the light guide (6) comprising: a flat light guide section (8) with a central light guide plane (XY); a light deflecting section (16), the light deflecting section (16) comprising a number of transparent deflecting surfaces delimiting the flat light-guiding section on the narrow side, which in pairs enclose a material-side distal angle of 90 °, an edge which delimits at least one of the deflecting surfaces being a base curve follows; and a light coupling section (10) delimiting the flat light guide section (8) for coupling in a light generated by the light source (4), wherein the light guide section (8) comprises a concave curvature in a section according to the light guide plane (XY), and wherein the light source (4 ), the concave curvature of the light coupling section (8) and the base curve of the edge of the light deflecting section (16) are matched to one another in such a way that a light bundle generated by the light deflecting section (16) is collimated along a main direction of propagation (42) and transversely to the main direction of propagation (42) is homogenized. The light module (2) according to the Claim 1 , wherein the concave curvature in an opening direction of the base curve is at least partially more curved than against the opening direction. The light module (2) according to the Claim 1 or 2 wherein the flat light guide section (8) comprises a number of pairs of deflecting surfaces, which in pairs enclose the material-side angle of 90 °, and wherein proximal or distal edges at which the deflecting surfaces abut follow a common paraboloid of revolution or a common parabolic cylinder. The light module (2) after Claim 3 wherein the light deflecting section comprises two, three or four pairs of deflecting surfaces. The light module (2) according to one of the preceding claims, wherein a respective one of the deflection surfaces encloses an angle of 45 ° with the light guide plane (XY) at least in an imaginary extension in a section perpendicular to the light guide plane. The light module (2) according to one of the preceding claims, wherein the light coupling section (10) comprises a convex curvature in a section perpendicular to the light guide plane (XY). The light module (2) according to one of the preceding claims, wherein a light decoupling section (50) delimits the flat light guide section (8) on the narrow side. The light module (2) after one of the Claims 1 to 6th , wherein the light guide (6) comprises: a light extraction section; a further flat light guide section which is arranged between the light output section and the flat light guide section (8); and a further light deflecting section which is arranged between the flat light guide section (8) and the further flat light guide section. A lighting device for a motor vehicle, wherein the light module (2) according to one of the preceding claims is arranged in a housing with a light exit opening. A motor vehicle comprising the lighting device according to the preceding claim.

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