DE102013209852A1 - lamp - Google Patents

Abstract

The invention relates to a lamp having a lamp vessel (30) made of light-transmitting material and having a base (10) which is arranged at one end of the lamp vessel (30) and corresponds to a standardized incandescent lamp base, wherein at least two semiconductor light sources (41, 42) and a Light guide (70) are provided, is coupled into the light from the semiconductor light sources (41, 42), wherein the light guide (70) has an arcuate component (71, 73, 72), which from a in the apex of the arcuate component (71, 73, 72), light-diffusing optical waveguide section (73) and a first photoconductive section (71) of the optical waveguide (70) and a second photoconductive section (72) of the optical waveguide (70), the photoconductive sections (71, 72 ) are arranged on different sides of the light scattering formed Lichtleiterbschnitts (73), the first photoconductive portion (71) has a surface (710) for Coupling of light from at least one first semiconductor light source (41), and the second light-conducting section (72) has a surface (720) for coupling in light from at least one second semiconductor light source (42).

Description

The invention relates to a lamp according to the preamble of claim 1.

I. State of the art

Such a lamp is for example in the German utility model DE 20 2011 100 723 U1 disclosed. This document describes a lamp with a lamp envelope of translucent material and at least one arranged inside the lamp envelope semiconductor light source and a socket provided with electrical connections, which corresponds to a standardized light bulb socket.

Such lamps serve as a light bulb replacement. However, their light distribution does not comply with the legal requirements for use as exterior lighting in motor vehicles. In particular, these lamps do not comply with the regulations of the ECE (Economic Commssion for Europe). Therefore, they can be used only for other purposes, such as lighting in the vehicle interior.

II. Presentation of the invention

It is an object of the invention to provide a generic lamp that can be used as a replacement for an incandescent lamp in a corresponding version and whose light distribution complies with the legal requirements for use in the outside of the motor vehicle mounted lights.

This object is achieved by a lamp having the features of claim 1. Particularly advantageous embodiments of the invention are described in the dependent claims.

The lamp according to the invention has a lamp vessel made of light-transmissive material, a base which is arranged at one end of the lamp vessel and corresponds to a standardized light bulb socket, and at least two semiconductor light sources, wherein a light guide is provided, is coupled into the light from the semiconductor light sources. According to the invention, the optical waveguide has an arcuate component formed by a light-diffusing optical waveguide section arranged in the apex of the arc and two light-conducting sections arranged on different sides of the light-diffusing optical waveguide section, and wherein the first light-guiding section has a surface for coupling in light of at least one first semiconductor light source and the second photoconductive portion has a surface for coupling light from at least one second semiconductor light source.

These features of the lamp according to the invention have the advantage that light from at least two semiconductor light sources is guided to the light-scattering light guide section, wherein the light-scattering trained light guide section serves as an emitter, which emits the light originating from the at least two semiconductor light sources in all directions, so that a light distribution is achieved, which corresponds almost to the light distribution of a compatible incandescent lamp. The arcuate component of the light guide of the lamp according to the invention makes it possible to couple light from a plurality of semiconductor light sources, which are arranged at two different locations, into the optical waveguide and to guide it to the light-scattering light guide section arranged in the apex of the arch. The use of at least two semiconductor light sources has the advantage that the light-scattering light guide section of the lamp according to the invention emits light with high luminance and high luminous flux. The arcuate component of the light guide also offers the advantage of high mechanical stability of the light guide and the option of symmetrical alignment of the light guide with respect to the longitudinal axis of the lamp according to the invention. Instead of an incandescent filament, the lamp according to the invention uses at least two semiconductor light sources and the aforementioned light-scattering light guide section formed as a light source or light emitter.

The light-scattering light guide section preferably has substantially the outer dimensions of an incandescent filament in order to produce a light emission characteristic similar to that of an incandescent filament of an incandescent lamp. Advantageously, the light-scattering light guide section of the lamp according to the invention is therefore cylindrical and has a diameter in the range of 1 mm to 3 mm and a length in the range of 1 mm to 5 mm. Through the lateral surface of the cylindrical, light-scattering light guide section light is thereby emitted whose emission corresponds to almost the light emission of a filament.

The light-scattering light guide section of the lamp according to the invention is preferably arranged at a distance from a reference plane of the base, which in a compatible incandescent lamp corresponds to the distance of the incandescent filament to the reference plane of the incandescent lamp base. As a result, the light-scattering light guide section of the lamp according to the invention is arranged after its mounting in a lamp socket of a vehicle lamp at the same location in the vehicle lamp that the filament of a compatible incandescent lamp used in the aforementioned lamp socket would occupy in the vehicle lamp. In particular, the base of the lamp according to the invention preferably designed as a BA15s socket and the cylinder axis of the light scattering light guide section is preferably arranged at a distance of 19 mm to the reference plane of the BA15s socket.

Advantageously, the first light-conducting portion of the light guide and the second light-conducting portion of the light guide of the lamp according to the invention made of transparent material and are each formed totally reflecting. As a result, coupled into the aforementioned light-conducting portions of light without significant absorption to the light-scattering formed portion of the light guide of the lamp according to the invention.

The light-diffusing section of the light guide of the lamp according to the invention is preferably made of transparent material containing light-scattering particles. As a result, the light supplied to the diffused light guide section light is scattered without appreciable absorption of the light-scattering particles in all directions, so that the light-scattering light guide section emits light in all directions over its surface. The light-scattering trained light guide section consists of manufacturing reasons, preferably made of transparent plastic. As light-scattering particles are preferably titanium dioxide particles which are included as an additive in the aforementioned plastic material. Titanium dioxide particles have the advantage that they do not affect the color of the light emitted by the semiconductor light sources. As an alternative or in addition to titanium dioxide particles, other light scattering agents can also be used in the light-scattering optical waveguide section. For example, phosphor particles may be contained in the diffused light guide section to convert the wavelength at least in a part of the light emitted from the semiconductor light sources and thereby change the color of the light emitted from the diffused light guide section.

Advantageously, the light guide of the lamp according to the invention has a base portion which carries the arcuate component of the light guide. The base portion allows stable mounting and fixing of the light guide within the lamp vessel.

Preferably, the light guide of the lamp according to the invention is fixed to the lamp vessel. Thereby, the light guide can be mounted simultaneously with the lamp vessel on the base and it can be ensured in a simple manner that the light guide has a distance from the semiconductor light sources, which are preferably mounted on a mounting plate arranged in the base.

The base section of the light guide of the lamp according to the invention preferably has recesses for the semiconductor light sources, in order to allow a good light coupling with low loss in the first and second photoconductive portion of the light guide or in the arcuate component of the light guide.

Advantageously, the base section of the light guide of the lamp according to the invention is provided with means for shading the light emitted by the semiconductor light sources and not coupled into the light-conducting sections of the light guide to light extraction in the region of the base portion of the light guide and a direct light emission of the semiconductor light sources, bypassing the light guide , to prevent. This ensures that light is radiated from the lamp according to the invention only over the light-scattering light guide section. As shading agent, for example, an opaque coating of the surface of the base portion of the light guide is suitable. Alternatively, the base portion of the light guide may also be made of an opaque material.

The light guide of the lamp according to the invention preferably has a support element which is connected to the base section of the light guide and to the light-scattering section of the light guide. The support element gives the optical waveguide additional mechanical stability and in particular prevents vibration-induced oscillations of the optical waveguide section formed in the apex of the arcuate component of the optical waveguide and formed in a light-diffusing manner.

Advantageously, all sections of the light guide of the lamp according to the invention are formed as plastic injection molded parts. As a result, all sections of the light guide can be connected to one another by plastic injection molding technology, so that the complete light guide is present in one piece. In particular, it is possible, for example, to separately produce the first and second light-conducting section and the light-scattering section of the arcuate component of the light guide by means of a first plastic injection molding method and to connect the abovementioned sections of the arcuate component of the light guide to a unit by means of a second, downstream plastic injection molding method. Furthermore, it is also possible to additionally produce the base section and the support element as plastic injection-molded parts and already by means of the aforementioned second plastic injection molding process or by means of a further, third plastic injection molding process, which is connected downstream of the second plastic injection molding process to connect the arcuate component of the light guide.

The lamp according to the invention is preferably provided for use in a motor vehicle light. For example, it is used for license plate lighting or in front position lights or in motor vehicle tail lights or for lighting in the vehicle interior. The semiconductor light sources and the light guide of the lamp according to the invention are therefore designed, depending on the intended use of the lamp, such that the light-scattering light guide section of the lamp emits either white light, red light or orange light.

As semiconductor light sources, for example light emitting diodes are used, which emit either white light, red light or orange light depending on the application. The light-scattering effect of the light-scattering light guide section is realized in this case, for example, by means of titanium dioxide particles which are contained as an additive in the transparent material of the light-scattering light guide section. Alternatively or additionally, the light-scattering effect can be achieved by roughening the surface of the light guide.

As semiconductor light sources, instead of light-emitting diodes, it is also possible to use laser diodes which produce, for example, blue light which is proportionally converted into yellow light by means of phosphor, so that the lamp according to the invention emits white light which is a mixture of unconverted blue light and converted yellow light , For this purpose, in addition to or in place of titanium dioxide particles, phosphor particles which convert a part of the blue light generated by the laser diodes into yellow light and scatter both the converted and the unconverted light, so that the light-scattering light differs, are contained in the light-scattering optical waveguide section Optical fiber portion of the lamp according to the invention is emitted white light, which is a homogeneous mixture of unconverted blue and converted yellow light. The phosphor used here is cerium-doped yttrium aluminum garnet (YAG: Ce).

III. Description of the Preferred Embodiment

The invention will be explained in more detail below with reference to a preferred embodiment. Show it:

1 A side view of a lamp according to the preferred embodiment of the invention in a schematic representation

2 A cross section through the in 1 pictured lamp along the cutting plane AA

3 A perspective view of the light guide of in 2 pictured lamp

4 A front view of the in 3 illustrated light guide

5 A side view of the in 3 illustrated light guide

6 A top view of the in 3 illustrated optical fiber

The in the 1 and 2 The illustrated lamp according to the preferred embodiment of the invention is compatible with a standard ECE category R5W vehicle light bulb used, for example, for license plate lighting or in front-position lights or in automotive tail lights or for vehicle interior lighting. This lamp has the same base as the aforementioned vehicle light bulb, but is equipped instead of the filament with light emitting white light emitting diodes as a light source. In particular, the lamp according to the preferred embodiment of the invention has a base labeled BA15s.

The in the 1 and 2 The illustrated lamp according to the preferred embodiment of the invention has a standard Ba15s socket 10 , a hollow cylindrical heat sink 11 made of copper, two LEDs 41 . 42 on a mounting board 20 are mounted with T-shaped profile, and a lamp vessel 30 made of transparent plastic. The Ba15s socket 10 is a bayonet base, attached to its cylindrical base sleeve 100 two diametrically arranged locking knobs 101 . 102 has. The electrical connections of the lamp are from one to the lamp vessel 30 facing away from the end of the base 10 arranged center contact 103 and from the cylindrical base sleeve 100 of the pedestal 10 educated. The center contact 103 is through a pedestal 104 made of plastic or ceramic, inside the base sleeve 100 is arranged and removed from the lamp vessel 30 facing away from the end of the base 10 protrudes, electrically isolated from the base sleeve 100 , The base sleeve 100 , the hollow cylindrical heat sink 11 and the lamp vessel 30 are rotationally symmetric with respect to a longitudinal axis 6 the lamp is formed. The lamp vessel 30 is hood-like and at his from the base 10 opposite end by a dome 31 locked. That the pedestal 30 facing the end of the lamp vessel 30 is open.

The hollow cylindrical heat sink 11 is made of copper and is press-fitted inside the cylindrical base sleeve 100 fixed. The heat sink 11 has for this purpose a first heat sink section 111 , whose outer diameter to the inner diameter of the base sleeve 100 is tuned. In addition, the heat sink points 11 a second heat sink section 112 with reduced outer diameter, with the base sleeve 100 an annular groove 120 for receiving and fixing the lamp vessel 30 forms. The open end of the rotationally symmetrical, hood-like lamp vessel 30 is in the annular groove 120 fixed with clamped seat. The heat sink 11 has a depth stop for the lamp vessel 30 serving, stepped transition region 110 from the first heat sink section 111 to the second heat sink section 112 ,

The mounting board 20 has a first, circular disk-shaped board section 201 which is perpendicular to the longitudinal axis 6 the lamp is aligned and the the lamp vessel 30 facing open front side of the second heat sink section 112 covers. In addition, the mounting board has 20 a second, rectangular board section 202 which is perpendicular to the first board section 201 is arranged and in the longitudinal axis 6 the lamp runs. The mounting board 20 thus has a T-shaped profile. Metallic contacts (not shown) of the first board section 201 the mounting board 20 are by soldering or welding to the second heat sink section 112 connected to a mechanical and electrical contact between mounting board 20 and heat sink 11 and a thermal coupling between the heat sink 11 and the light emitting diodes 41 . 42 manufacture. On the surface of the second board section 202 the mounting board 20 are electrical components 210 an operating device for the LEDs 41 . 42 arranged. Another metallic contact (not shown) on the second board section 202 is arranged through a power supply wire 5 with the center contact 103 of the pedestal 10 connected.

The light-emitting diodes 41 . 42 are on the knoll 31 of the lamp vessel 30 facing surface of the first board section 201 the mounting board 20 arranged. The light-emitting diodes 41 . 42 are opposite each other, outside the lamp's longitudinal axis 6 arranged so that they lie on a fictitious line, the diameter of the circular disk-shaped first board section 201 the mounting board 20 equivalent. The light-emitting diodes 41 . 42 emit white light during their operation.

The electrical power supply of the LEDs 41 . 42 and the components 210 the operating circuit takes place on the one hand via the base sleeve 100 , the heat sink 11 and the metallic contacts of the first board section 201 the mounting board 20 and on the other hand via the center contact 103 , the power supply wire 5 and the further metallic contact on the second board section 202 the mounting board 20 , wherein the base sleeve 100 connected to the electrical ground reference potential. The electrical connection between the LEDs 41 . 42 and the components 210 their operating device is made via tracks (not shown) on the mounting board 20 are arranged.

The light guide 70 The lamp according to the preferred embodiment of the invention has a first photoconductive portion 71 , a second photoconductive portion 72 , a light-scattering trained light guide section 73 , a base section 74 and a support element 75 on. The two light-conducting sections 71 . 72 and the light scattering trained light guide section 73 form an arcuate component 71 . 73 . 72 of the light guide 70 , wherein the light scattering trained light guide section 73 in the apex of the arcuate component 71 . 73 . 72 is arranged and the two light-conducting sections 71 . 72 of the light guide 70 with different sides of the light scattering trained light guide section 73 are connected. The arcuate component 71 . 73 . 72 of the light guide 70 is in particular U-shaped, wherein the U-legs of the arcuate component 71 . 73 . 72 of the light guide 70 from the first photoconductive section 71 and the second photoconductive portion 72 of the light guide 70 are formed and the U-base of the light scattering trained light guide section 73 is formed. The formed by the light scattering light guide section 73 wegführenden ends of the light-conducting sections 71 . 72 of the light guide 70 are each with the base section 74 of the light guide 70 connected. In the area of the abovementioned ends of the light-conducting sections 71 . 72 of the light guide 70 owns the base section 74 of the light guide 70 one recess each 741 respectively. 742 for the light-emitting diodes 41 . 42 , The of the light scattering trained light guide section 73 wegführenden ends of the light-conducting sections 71 . 72 of the light guide 70 each have a light input surface 710 respectively. 720 on that in the area of the recesses 741 respectively. 742 of the base section 74 of the light guide 70 with distance to the LEDs 41 respectively. 42 are arranged and the light-emitting surface of the light-emitting diodes 41 respectively. 42 are facing, so that during operation of the light emitting diode 41 respectively. 42 emitted light via the light coupling surface 710 respectively. 720 in the first photoconductive section 71 or in the second photoconductive section 72 of the light guide 70 coupled and to the light scattering trained light guide section 73 is directed. The light-scattering trained light guide section 73 is for mechanical stabilization by the support element 75 with the base section 74 of the light guide 70 connected. The support element 75 runs in the longitudinal axis 6 and parallel to the longitudinal axis 6 the lamp. The arcuate component 71 . 73 . 72 of the light guide 70 is symmetrical to the longitudinal axis 6 arranged the lamp. The two light-conducting sections 71 . 72 of the light guide 70 each have an approximately rectangular cross-section, that is, a rectangular cross-section with rounded corners.

The light-scattering trained light guide section 73 of the light guide 70 is circular cylindrical, formed with a diameter of 1.6 mm and a length of 2 mm. The fictitious cylinder axis 730 the light-scattering trained light guide section 73 runs perpendicular to the longitudinal axis 6 the lamp. The light-scattering trained light guide section 73 is with his fictitious cylinder axis 730 arranged at a distance E of 19 mm to a fictitious plane R, which is perpendicular to the longitudinal axis 6 the lamp runs and the two opposing reference lugs 101 . 102 at her the lamp vessel 30 facing side ( 1 ). This plane is called the reference plane R of the BA15s socket 10 designated. The aforementioned distance E corresponds to the so-called e-dimension, which is compatible with incandescent lamps of the ECE category R5W in the ECE Regulation no. 37 is defined. The light-scattering trained light guide section 73 is formed as a plastic injection molded part and consists of transparent plastic, such as polycarbonate containing titanium dioxide particles (TiO ₂ ) to achieve a light-scattering effect.

The two light-conducting sections 71 . 72 of the light guide 70 consist of transparent plastic, such as polycarbonate, and are designed to be totally reflective. That is, light that is at the coupling surface 710 respectively. 720 of the first photoconductive portion 71 or the second photoconductive portion 72 of the light guide 70 can be coupled, the respective photoconductive section 71 respectively. 72 due to total reflection on its lateral surface does not leave, but is to the other end of the respective photoconductive portion 71 respectively. 72 of the light guide 70 passed, each with the light scattering trained light guide section 73 connected is. As an alternative to total reflection, a reflection can also be achieved by a light-reflecting coating on the lateral surface of the two light-conducting sections 71 . 72 can be achieved, the light on the surface of the light-conducting sections 71 . 72 reflected back in their interior.

The base section 74 and the support element 75 the light guide are made of plastic, such as polycarbonate, and are made opaque. The opacity is, for example, by color additives in the plastic material of base section 74 and support element 75 achieved or by means of an opaque coating or a blackening of the base portion 74 and support element 75 achieved.

The base section 74 of the light guide 70 extends perpendicular to the longitudinal axis 6 the lamp and has two opposite faces 743 . 744 , which by adhesive on the inside of the lamp vessel 30 with the lamp vessel 30 are connected. Alternatively, the base section 74 also mechanically by a snap or snap connection on the lamp vessel 30 be fixed. The one with the LEDs 41 . 42 provided area of the first board section 201 the mounting board 20 is from the base section 74 of the light guide 70 covered.

The light-conducting sections 71 . 72 , the light-scattering trained section 73 , the base section 74 and the support element 75 of the light guide 70 are manufactured by means of a plastic injection molding process in several steps and connected together to form a unit.

During the operation of the lamp, that of the light emitting diode 41 respectively. 42 emitted light via the light input surface 710 respectively. 720 in the first photoconductive section 71 or in the second photoconductive section 72 of the light guide 70 coupled and by total internal reflection in the light-conducting sections 71 . 72 of the light guide 70 to the light-scattering trained light guide section 73 passed, which acts as a light emitter. That of the light-emitting diodes 41 . 42 generated light leaves the light guide 70 over the lateral surface of the light-scattering light guide section 73 and is emitted in all directions. The light-scattering trained light guide section 73 has a similar light emission characteristic as the incandescent filament of a compatible ECE category R5W incandescent lamp.

The contour and the outer dimensions of the lamp according to the preferred embodiment of the invention correspond to the contour and the outer dimensions of an ECE category R5W incandescent lamp, so that the lamp according to the preferred embodiment of the invention is compatible with an ECE category R5W incandescent lamp.

The invention is not limited to the embodiment described in more detail above. For example, instead of a BA15s socket, the lamps according to the invention may have another standardized light bulb socket, in particular a BA9s socket. In addition, in each light-guiding section 71 respectively. 72 of the light guide 70 the light of more than just a light-emitting diode 41 respectively. 42 be coupled. For example, can the LED 41 or 42 be designed as a light-emitting diode array or LED chip.

Furthermore, instead of light-emitting diodes, the lamps according to the invention can also have other semiconductor light sources. In particular, the lamps according to the invention may comprise blue light-emitting laser diodes whose light is proportionately converted to yellow light by means of phosphor, so that the lamps emit white light which is a mixture of converted yellow light and unconverted blue light. In addition, as light sources, depending on the application, also colored light emitting light emitting diode or laser diodes can be used. For example, orange light-emitting semiconductor light sources for a flashing light or red light-emitting semiconductor light sources for a rear position light.

The base portion and the support element of the light guide of the lamp according to the invention need not necessarily be formed opaque, but may also be designed to be translucent.

In addition, the light-scattering trained light guide section does not necessarily have to be circular cylindrical, that is, it does not necessarily have a circular cross-section, but instead may have other cylindrical shapes with a different cross section, for example with an elliptical cross section. In this case, the term diameter denotes twice the value of the dimension of the large semiaxis of the ellipse or, in the case of other cylindrical shapes, the value of the largest dimension of the light-scattering light guide section perpendicular to the cylinder axis.

Furthermore, the sections 71 . 72 . 73 . 74 . 75 of the light guide 70 the lamp according to the invention are also manufactured by means of forming or Urformverfahren instead of plastic injection molding. Furthermore, the aforementioned sections of the light guide can also consist of glass instead of plastic.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202011100723 U1 [0002]

Claims (16)

Lamp with a lamp vessel ( 30 ) made of translucent material and with a base ( 10 ), which at one end of the lamp vessel ( 30 ) and corresponds to a standardized incandescent lamp base, characterized in that at least two semiconductor light sources ( 41 . 42 ) and a light guide ( 70 ) are provided in the light from the semiconductor light sources ( 41 . 42 ) is coupled, wherein the optical fiber ( 70 ) an arcuate component ( 71 . 73 . 72 ), which is defined by one in the apex of the arcuate component ( 71 . 73 . 72 ) arranged light scattering light guide section ( 73 ) and a first photoconductive section ( 71 ) of the light guide ( 70 ) and a second photoconductive section ( 72 ) of the light guide ( 70 ), wherein - the light-conducting sections ( 71 . 72 ) on different sides of the lichtstreuend trained Lichtleiterbschnitts ( 73 ), - the first photoconductive section ( 71 ) a surface ( 710 ) for coupling light from at least one first semiconductor light source ( 41 ), and - the second photoconductive section ( 72 ) a surface ( 720 ) for coupling light from at least one second semiconductor light source ( 42 ) having. A lamp according to claim 1, wherein the light-scattering light guide section ( 73 ) is cylindrical and has a diameter in the range of 1 mm to 3 mm and a length in the range of 1.5 mm to 5 mm. A lamp according to claim 1 or 2, wherein the light-scattering light guide section ( 73 ) is arranged at a distance (E) to a reference plane of the lamp cap, which corresponds to the distance of the filament to the reference plane of the filament lamp socket in a compatible incandescent lamp. A lamp according to claim 3, wherein the base is formed as BA15s socket and the cylinder axis ( 730 ) of the light-scattering light guide section ( 73 ) is arranged at a distance of 19 mm from the reference plane of the BA15s socket. A lamp according to any one of claims 1 to 4, wherein the first ( 71 ) and second photoconductive section ( 72 ) of the light guide ( 70 ) consist of transparent material and are designed to be totally reflective. A lamp according to any one of claims 1 to 5, wherein the light-diffusing optical fiber section ( 73 ) is made of transparent material containing light-scattering particles. Lamp according to one of claims 1 to 6, wherein the light guide ( 70 ) a base section ( 74 ) comprising the arcuate component ( 71 . 73 . 72 ) of the light guide ( 70 ) wearing. A lamp according to claim 7, wherein the base portion ( 74 ) of the light guide ( 70 ) on the lamp vessel ( 30 ) is fixed. A lamp according to claim 6 or 7, wherein the base portion ( 74 ) of the light guide ( 70 ) Recesses ( 741 . 742 ) for the semiconductor light sources ( 41 . 42 ) owns. A lamp according to any one of claims 7 to 9, wherein the base portion ( 74 ) Comprises means for shading light emitted by the semiconductor light sources ( 41 . 42 ) and not in the light-conducting sections ( 71 . 72 ) of the light guide ( 70 ) is coupled. Lamp according to one of claims 7 to 10, wherein the light guide ( 70 ) a support element ( 75 ) which is connected to the base section ( 74 ) and with the light scattering trained light guide section ( 73 ) connected is. A lamp according to claim 11, wherein the support element ( 75 ) is formed opaque. Lamp according to one of claims 1 to 12, wherein the light guide ( 70 ) from the arcuate component ( 71 . 73 . 72 ), the basic element ( 74 ) and the support element ( 75 ) consists. A lamp according to any one of claims 1 to 13, wherein the arcuate component ( 71 . 73 . 72 ) of the light guide ( 70 ) Is U-shaped. A lamp according to any one of claims 1 to 14, wherein the sections ( 71 . 72 . 73 . 74 . 75 ) of the light guide ( 70 ) are formed as plastic injection molded parts. A lamp according to any one of claims 1 to 15, wherein the semiconductor light sources ( 41 . 42 ) on one in the base ( 10 ) arranged assembly board ( 20 ) are fixed.

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