DE102015113551A1 - Conversion module with a fiber optic light guide for a lighting device - Google Patents

Abstract

The invention generally relates to a conversion module as part of a lighting device, preferably on a vehicle, in particular as part of a headlight. The conversion module is operated with excitation light of a light source using a fiber optic light guide. For holding a converter for generating the useful light, a support element is provided, while the light guide is positioned and supported by a coupling head.

Description

The invention generally relates to a conversion module as part of a lighting device, preferably on a vehicle, in particular as part of a headlight. The conversion module is operated with excitation light of a light source using a fiber optic light guide.

A light-emitting device as part of a lighting device of a headlamp is basically from the document DE 10 2006 029 203 A1 and comprises an excitation light source, an optical fiber coupled thereto and adjoining converter material for converting the shorter-wavelength excitation light into, on average, longer-wavelength useful light with a white-light impression. The useful light is composed of a long-wave, converted component and a non-converted part of the excitation light. A heat sink for the converter is not available.

Further, from the document DE 10 2010 034 054 A1 a laser-based white light source known in which a laser by means of a converging lens generates a light spot in a converter to emit white useful light in transmission operation. To avoid high temperatures at the light spot, the converter is made with the inclusion of thermally conductive material, additionally cooled by air and / or rotate to let the light spot in the converter material to wander all around.

The use of several light guides side by side in a light emitting device with converter in the transmission mode is from the document US 2010/0254153 A1 known.

Finally, from the document DE 10 2012 109 088 A1 a fiber optic conversion module known which can be operated as a lighting device on a vehicle. For transmitting the excitation light to the conversion medium or converter, a plurality of optical fibers are provided. Therefore, a distributor housing is provided which serves to merge a plurality of optical fibers. For holding the optical fibers and the converter, a decoupling head is disclosed. Such multi-fiber systems are, especially if they are mounted together with the converter on a common carrier system, very expensive to manufacture and therefore correspondingly expensive.

For example, the fiber ends of the light guide are often provided with a polished section at a certain angle, which requires a complex production. In addition, a fine adjustment of the distance of the fiber ends to the conversion medium, for example after installation in the lighting device, hardly possible or only at great expense. In addition, the arrangement of fiber holder and converter holder on a common carrier is unfavorable, since the converter can heat up very strong, which can lead to damage to the fibers. A repair or the replacement of defective fibers is very expensive.

The invention is therefore based on the object to provide a fiber optic conversion module simple structure that is suitable as a mounting part in a lighting device between an excitation light source and a headlight for emitting useful light and allows good heat dissipation.

The conversion module is to be operated for cost reasons only with a single fiber. The shading, in particular by the supplied fiber should be as low as possible. In addition, a simple and rapid installation of the conversion module on the one hand and as a whole in the utility device, such as the lighting device, be given to allow a cost-effective production and assembly. Consequently, the conversion module should also be easy to maintain, so it should be easy to replace in case of damage. A fine adjustment should still be possible after installation.

Furthermore, the required beam safety in the use of laser light as excitation light in lighting devices should be given. In this context, a fiber optic conversion module is to be created, the dangerous excitation light in the case of laser or laser diodes as light sources prevents it from leaking to the outside, even if, as occurs in car accidents, destroyed the car headlights and thereby broken optical fibers in the Car headlights lead.

Surprisingly, this object is achieved by a conversion module according to one of the independent claims. Preferred embodiments and further developments of the invention are to be taken from the respective subclaims.

• – ein Trägerelement,
• – einen Auskoppelkopf, und
• – einen faseroptischen Lichtleiter, wobei
• – der Auskoppelkopf zur Positionierung und Halterung eines Lichtaustrittsendes des Lichtleiters ausgebildet ist,
• – der faseroptische Lichtleiter an seinem Lichteintrittsende zur Ankopplung an eine zugeordnete Anregungslichtquelle ausgebildet ist,
• – das Lichtaustrittsende des Lichtleiters zur Abgabe von Anregungslicht in vorgegebener Strahlrichtung eingerichtet ist, und wobei
• – das Trägerelement eingerichtet ist zum Haltern eines Konverters,
• – das Trägerelement Mittel zum Verbinden mit dem Auskoppelkopf derart umfasst, dass
• – der Konverter in Strahlrichtung des aus dem Lichtaustrittsendes des Lichtleiters austretenden Anregungslichtes liegt, und dabei geneigt zur Strahlrichtung des Anregungslichtes angeordnet ist, wobei
• – ein vordefinierter Abstand zwischen dem Mittelpunkt des Konverters und dem Lichtaustrittsende des Lichtleiters gegeben ist, und wobei
• – der Konverter der Konversion des kurzwelligeren Anregungslichtes in das langwelligere Konversionslicht und der Emission des gemischten Nutzlichtes dient.

Accordingly, in a first aspect, the invention comprises a fiber-optic conversion module as part of a lighting device which emits useful light mixed with short-wavelength excitation light and long-wavelength conversion light. The conversion module according to the invention comprises:

• A carrier element,
• - a decoupling head, and
• - A fiber optic light guide, wherein
• - The coupling head is designed for positioning and holding a light exit end of the light guide,
• - The fiber optic light guide is formed at its light entry end for coupling to an associated excitation light source,
• - The light exit end of the light guide is arranged to emit excitation light in a predetermined beam direction, and wherein
• The carrier element is set up to hold a converter,
• - The support member comprises means for connecting to the coupling head such that
• - The converter is in the beam direction of emerging from the light exit end of the optical fiber excitation light, and is arranged inclined to the beam direction of the excitation light, wherein
• - Given a predefined distance between the center of the converter and the light exit end of the light guide, and wherein
• - The converter of the conversion of the short-wave excitation light in the long-wavelength conversion light and the emission of the mixed useful light is used.

The fiber optic light guide, also called optical fiber, may have a light entry end provided with a plug for coupling to an associated excitation light source. The decoupling head ensures that the light exit end of the light guide directs the shorter-wavelength excitation light onto a light spot located on the surface of the converter. According to the invention, the coupling head accordingly comprises a receptacle for holding and fixing the light exit end of the optical fiber. Furthermore, it is designed to be firmly connected to the carrier element.

The shorter-wavelength excitation light penetrates for the most part in the converter and is converted there into long-wavelength conversion light, which is emitted together with scattered excitation light in a usable beam angle as useful light, while interfering reflected excitation light (the so-called Fresnel reflex) collected by a light shield and harmless is done. In the case of a car headlight, the useful light is emitted to a parabolic mirror.

The point at which the excitation light impinges on the converter is called a light spot. Starting from the converter, the useful light spreads in a range of a usable radiation angle of this. In this case, the useful light is radiated cone-shaped from the light spot. The resulting opening angle of the light cone is at least 50 °, preferably at least 60 ° and particularly preferably at least 70 °.

Furthermore, a carrier element is provided according to the invention for holding the converter. The carrier element with the converter is structurally separated from the coupling head in the sense of the invention. For mounting the conversion module, the carrier element and / or the coupling head are designed such that they can be firmly connected to each other. For this purpose, the support element and / or the decoupling head may have suitable means for a fixed connection, such as a recess and a precisely matched counter-trained recording to create a high-precision, solid connection. To support the exact positioning adjustment aids, such as a stop or positioning pins may also be provided. The exact alignment of the coupling head and the carrier element in the mounted position is of great importance in order to radiate the excitation light precisely onto the converter.

Thus, the coupling head may be formed in a preferred embodiment rotationally symmetrical peg-shaped and plugged into a precisely matching gegengleiche bore of the support element. Preferably, a close tolerance of the fit is selected, in which the coupling head can be joined with low pressure.

The separation into a carrier element, which comprises and supports the converter, as well as a decoupling head, which is designed for holding and fixing the optical fiber, offers several advantages, in particular over solutions in which the holder of the optical fiber and the converter are provided on a common carrier element ,

Thus, in the present case, the Auskoppelköpfe can be made comparatively easily and inexpensively in large quantities, which are then subsequently connected to the carrier element. The carrier element and / or the coupling-out head can therefore already be formed as part of a lighting device or as part of a lighting device.

The coupling head with the optical fiber or the optical fiber can also be easily removed and replaced, for example due to a breakage of the optical fiber after installation in the lighting device or after prolonged operation or due to other interference in the optical fiber. Such defects can occur, for example, when using the conversion module in a car headlight, where it can often come to Rüttelbelastungen. The structural separation not only facilitates the production and assembly, but also the maintenance and replacement of components.

Due to the structural separation, it is also possible to use other materials for the carrier element than for the coupling head. This can be advantageous because the converter generates a large amount of heat during operation. This can cause damage to the optical fiber.

For this purpose, the carrier element can advantageously be produced from a temperature-stable sintered material, for example a metallic sintered material. Such material generally behaves uncritically at high temperature loads such as may occur during operation of the converter. In addition, the resulting thermal expansion of the carrier material is rather low, so that a temperature-induced change in the light characteristic due to changed distance between the light guide and converter due to thermal expansion can be largely avoided.

The carrier element may also be formed in the intended as a receptacle of the converter area as a heat sink, so assume a heat-dissipating function. Likewise, the support member may also include a heat sink for receiving the converter in heat-conducting and mechanically fixed connection. The carrier element is thus designed so that heat generated in the converter can be dissipated and dissipated via the carrier element. The physical separation of the heat transfer to the coupling head and / or the optical fiber can be reduced, so that there is a lower risk that the optical fiber is damaged during operation.

In addition, eliminates the problem of bundling the light emerging from several light emission ends in confined spaces and to focus on a common spot on the converter surface. For this purpose, the various optical fibers must generally be provided with a beveled cut at their light exit ends, which may also depend on the specific arrangement of the individual optical fiber. This makes the production relatively complicated and costly.

For guiding and holding the optical fiber in the coupling head different measures can be taken. Thus, preferably, the coupling head is provided with a bore through which the optical fiber can be passed. Expediently, the decoupling head has an insert part, preferably a sleeve, in which the light exit end of the optical fiber can be fixed and held. The inner diameter of the sleeve is precisely matched to the outer diameter of the optical fiber designed, preferably also with very low tolerance, to allow precise positioning of the optical fiber. The inner diameter of the insert element is matched to the outer diameter of the light guide and may be in a range of 0.1 mm to 0.5 mm, with a maximum deviation of at most +/- 0.1 mm, preferably at most +/- 0.05 mm and more preferably at most +/- 0.02 mm. For an optical fiber having an outer diameter of 0.34 mm, the inner diameter of the insert member is preferably 0.35 mm.

As a result, the required very tight tolerances in the positioning of the light exit end can be met. In addition, the insert element should have a minimum length in order to allow a corresponding knuckle-free, axially parallel guidance of the light exit end such that the excitation light emerges exactly in the beam direction. Further, the light exit end is preferably formed with a plane polished surface perpendicular to the longitudinal axis to couple out the excitation light in the beam direction.

In this way, a very good radial alignment and positioning of the optical fiber with respect to the converter can be achieved when the decoupling head is connected to the carrier element.

In a particularly preferred embodiment, means are further provided to allow subsequent axial alignment of the light exit end of the optical fiber with respect to the converter. Starting from a predefined distance between light exit end and converter, which is typically in a range of about 1 to 10 mm, this distance can then be changed in a certain range, preferably in a range of 0.05 mm to 5 mm. This makes it possible to make an exact axial positioning of the optical fiber with respect to the converter. This can be beneficial if, for example, the light guide must be replaced and another light guide with slightly different optical properties is used, which requires a correspondingly changed positioning with respect to the converter in order to obtain the same useful light.

Thus, for example, the insert element can be firmly connected to the light exit end, about medium terminals or gluing, and then inserted into the coupling head. After assembly, it can be moved in the axial direction before it is fixed, such as by gluing. In another embodiment, the end of the optical fiber can be moved axially in the insert element.

In another preferred embodiment, the coupling head is already formed with a reflector or as part of a reflector. In this embodiment, it comprises a feed for the light guide and an opening in which the converter of the carrier element is arranged. Exiting the light guide excitation light can then impinge on the converter after mounting.

Further details of the invention will become apparent from the description of the illustrated embodiments and the appended claims.

The drawings show:

1 a longitudinal section of a fiber optic conversion module in a first embodiment, and

2 an oblique view of a fiber optic conversion module in another embodiment.

Detailed description of preferred embodiments

In the following detailed description of preferred embodiments, for the sake of clarity, like reference numerals designate substantially similar parts in or on these embodiments. For better clarity of the invention, however, the preferred embodiments shown in the figures are not always drawn to scale.

The whole with the reference number 1 provided fiber optic conversion module is already in the illustrated example as a lighting device 10 designed and shown in ready assembled, installable form. The conversion module 1 is shown in a longitudinal section. The lighting device 10 is formed substantially peg-shaped and can be easily inserted and fixed in a car headlight.

The conversion module 1 according to the invention comprises a carrier element 20 , a decoupling head 30 and a fiber optic light guide 50 , also referred to below as optical fiber. To simplify the precise positioning of the illumination device 10 in the car headlight is on the support element 20 a recess 25 provided for fixing with corresponding reference surfaces, so that a simple and quick installation is possible.

The light guide 50 is provided at its light entry end with a plug (not shown) for coupling to an associated excitation light source (not shown). The plug is preferably a plug comprising a ceramic ferrule which has a higher diameter accuracy and less eccentricity than an SMA plug, which is designed to be coupled to a laser diode which provides its excitation light into the optical fiber 50 couples. Such a ceramic ferrule facilitates the assembly significantly, so that a complex adjustment can be avoided. The light guide 50 kinkless to the coupling head 30 a certain curvature is generally harmless and unavoidable. The optical fiber 50 leads to the coupling head 30 where she is fixed and held.

The carrier element 20 is with a converter 21 equipped, which is arranged so that excitation light from the mounted light guide 50 obliquely impinges.

That from the light guide 50 Exiting excitation light thus falls obliquely on the converter 21 , which converts the shorter-wavelength excitation light into longer-wavelength conversion light, but also scatters excitation light, so that the remitted light represents on average longer-wavelength useful light. In the case of useful light, white light character is usually sought. If the headlamp should generate substantially parallel useful light, is on the converter 21 generates a preferably small spot.

The decoupling head 30 is in the example of rotationally symmetrical, cone-shaped form. The decoupling head 30 is of low complexity and can therefore be manufactured easily and in large quantities at low cost.

The carrier element 20 is accordingly with a likewise rotationally symmetrical bore 27 equipped, which fits exactly opposite to the outer contour of the decoupling head 30 is trained. The hole 27 and the outer diameter of the Auskoppelkopfes in the connection area are manufactured with close tolerance. This may be a dH7 / m6 transition fitting, which allows for installation with light pressure. In this way, the output head 30 precisely in the hole 27 can be inserted and then fixed. The fixation can be done by gluing in the intended position. But it can also be provided a clamp or a screw.

The decoupling head 30 includes a central, axial through-hole with an insert element 31 , which is designed as a sleeve. This insert element 31 serves to receive the light exit end of the optical fiber 50 , The optical fiber 50 can in the insert element 31 be inserted so that the optical fiber 50 flush with the converter-side end of the insert element.

For exact positioning of the decoupling head 30 in the hole 27 the carrier element is the carrier element 20 with a circumferential stop 26 formed, the mounted on Auskoppelkopf a likewise circumferential projection 34 of the decoupling head 30 receives.

As a fixing aid is still a rotationally symmetrical insert element 32 intended. This is likewise designed as a sleeve and surrounds with a first region flush with the converter facing the front region of the coupling head. With the outer surface is the insert element 32 with its lateral surface in mounted position in contact with the bore 27 , A second region of the insert element opposite the first region 32 is designed to be an optical element 40 to pick up and hold. The optical element 40 thus lies in the direct beam path of the excitation light. By a predetermined distance between the light exit end of the light guide 50 and the optical element 40 to create is a spacer element 33 provided, which is within the insert element between the coupling head 30 and the optical element 40 located.

In this way, in the context of the invention, a low to be finished, ready to assemble coupling head 30 be made available, which on the one hand the holder and fixing a light guide 50 for supplying excitation light, on the other hand also an optical element 40 , Preferably for focusing the excitation light on a converter 21 , ready.

This embodiment offers, in addition to the possibility of rapid replacement of the coupling head, the further advantage that the axial distance between the light exit end of the light guide 50 and the optical element 40 by selecting spacers 33 with different lengths and / or the axial distance between the light exit end of the light guide 50 and the converter by changing the positioning of the decoupling head 30 in the hole 27 through the selection of insert elements 32 can be changed with different length.

For the optical element 40 In the example, a focusing optical element, preferably a rod lens, is provided. The optical element 40 is coaxial with the light guide 50 arranged. By means of the optical element 40 The excitation light is focused on the converter. For this purpose, the rod lens is formed with a plane-polished light entrance surface and a lens-shaped curved light exit surface.

The whole peg-shaped structure of the conversion module 1 leads to a likewise peg-shaped structure of the support element 20 and the lighting device 10 ,

To simplify the installation of the light guide 50 in the decoupling head 30 is a mounting shaft 35 provided, which is a particularly simple insertion of the light guide 50 allows.

The with the support element 20 mounted coupling head 30 ensures that the light exit end of the light guide 50 the excitation light is aimed at a spot of light that is on the surface of the converter 21 located. The long-wave useful light is emitted by the light spot in the form of a light cone. The cone of light has an opening angle of at least 50 °, preferably at least 60 ° and particularly preferably at least 70 °. The carrier element 20 further includes a reflective surface 23 for reflection of useful light.

In order to prevent the escape of reflected, short-wave excitation light, the support element is provided with a light aperture 22 equipped, which acts as a light trap. This can be designed as a scattering body or comprise a scattering body, which makes the excitation light dead. In this way, the exit of reflected excitation light can be prevented.

The interior of the support element 20 which the converter 21 includes, is with a translucent protective cover 24 surrounded to protect the converter. The converter 21 This can be optimally protected against penetrating particles or moisture. The translucent protective cover 24 is made of glass and sealed to the carrier element 21 connected. Preferably, therefore, the protective cover provides protection at least according to IP 44 DIN EN 60529 , In this way, the light exit end of the light guide can also 50 and / or the optical element 40 be optimally protected against dust and moisture.

The carrier element 20 is made in the example as a metallic sintered body. In particular for the carrier element 20 The production is suitable as such a sintered body, since a sintered component can be manufactured with high accuracy and also has a high temperature resistance, as occurs in the operation of the converter.

Alternatively, the carrier element 20 but also be made of a different material, such as a thermally conductive material to dissipate the high temperature of the converter during operation. The decoupling head 30 however, can be made of other materials, for example, inexpensive plastic, since the heat load through the operation of the converter 21 is lower.

The useful light passes through the protective cover 24 to the utility part (not shown), which in the case of a headlamp represents a parabolic mirror, a parabolic mirror segment or a modified parabolic mirror surface.

The distance between the optical element 40 and the converter 21 in the example is about 70 mm. In such a distance, it is generally sufficient if the axial adjustment possibility in a range of 0.05 mm to 5 mm, preferably in a range of 0.03 to 4 mm, to exact axial positioning of the light exit end of the optical fiber in Referring to the converter 21 to reach.

Another embodiment of a fiber optic conversion module according to the invention shows 2 in an oblique view.

Depicted is the coupling-out head 60 , This has an area which, as a parabolic reflector 61 is trained. In the center of the reflector 61 is a circular opening 62 present, in which the converter (not shown) can be placed. The support member carrying the converter is also not shown for the sake of clarity.

The surface of the reflector 61 is by an elongated, radial on the opening 62 tapered slot 63 interrupted. This is located in the region of the reflector near the center. The slot 63 allows it from the light exit end of the light guide 50 Exiting excitation light to be radiated to the converter. The slot thus runs in the beam direction on the converter 21 to.

The light guide 50 is with an insert element (not shown) with the coupling head 60 connected, as shown in the previous embodiment. In this way, an axial movement for positioning the light exit end of the light guide is also here 50 given in terms of the converter. Furthermore, it is also an optical element 64 present to focus the excitation light on the converter. The optical element 64 is arranged so that it does not protrude into the reflector area. In this way, shading of the useful light is largely avoided.

In an embodiment without an optical element 40 . 64 can the light exit end of the light guide 50 closer to the converter 21 be led up. Care must be taken to ensure that the light exit end does not lead to greater shadowing by protruding too much into the emission cone of the converter. In order to enable sufficient focusing of the excitation light on the converter despite higher distance, the light exit end of the light guide can be polished lenticular curved.

The bottom 65 of the coupling head 60 is equipped for precise recording and attachment to the support element with recesses and stops.

The top 66 of the coupling head 60 is provided with projections which allow easy connection with the translucent protective sheath (not shown).

Both embodiments have in common that the respective light exit end of the light guide comprises only a plan ground end face and therefore can be made very easily and inexpensively. Thus, in particular, no oblique, consuming to be produced bevels, as they are needed when using multiple optical fibers required.

In the embodiments, the light guide 50 a fiber core of quartz glass and a fiber cladding of quartz glass, wherein the refractive index of the fiber cladding is lower than the refractive index of the fiber core. Such a light guide is cheaper because of its comparatively high temperature resistance than, for example, plastic light guides.

For the purposes of the present invention, the carrier element and / or the decoupling head can already be formed as part of a lighting device or as part of a lighting device.

The structural separation allows a functional separation to the effect that a different material can be selected for the carrier element supporting the converter than for the coupling head. Thus, for example, a particularly temperature-stable material, such as a sintered material, preferably a metallic sintered material, be provided for the carrier element, while for the coupling head, a different material, such as a plastic material may be provided. The coupling head can therefore be easier and cheaper to manufacture.

The carrier element is thus designed so that heat generated in the converter can be dissipated and dissipated via the carrier element. The structural separation, the heat transfer to the coupling head can be reduced, so that there is a lower risk that the optical fiber is damaged during operation. In this way, the life of the fiber optic conversion module can be extended.

In addition, the problem of bundling the light emerging from a plurality of light emission ends in confined space conditions and concentrating on a common light spot on the converter surface is eliminated, so that overall less installation space is required for the conversion module according to the invention.

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 102006029203 A1 [0002]
• DE 102010034054 A1 [0003]
• US 2010/0254153 A1 [0004]
• DE 102012109088 A1 [0005]

Cited non-patent literature

• DIN EN 60529 [0052]

Claims (16)

 Fiber-optic conversion module as part of a lighting device that emits mixed light from shorter-wavelength excitation light and longer-wavelength conversion light, comprising: A carrier element, - a decoupling head, and - A fiber optic light guide, wherein - The coupling head is designed for positioning and holding a light exit end of the light guide, - The fiber optic light guide is formed at its light entry end for coupling to an associated excitation light source, - The light exit end of the light guide is arranged to emit excitation light in a predetermined beam direction, and wherein The carrier element is set up to hold a converter, - The support member comprises means for connecting to the coupling head such that - The converter is in the beam direction of emerging from the light exit end of the optical fiber excitation light, and is arranged inclined to the beam direction of the excitation light, wherein - Given a predefined distance between the center of the converter and the light exit end of the light guide, and wherein - The converter of the conversion of the short-wave excitation light in the long-wavelength conversion light and the emission of the mixed useful light is used. Fiber-optic conversion module according to the preceding claim, characterized in that the decoupling head comprises an insert for positioning and holding the light exit end of a single optical fiber. Fiber-optic conversion module according to one of the preceding claims, characterized in that the excitation light impinges on the converter in a light spot and propagates therefrom in a range of a usable radiation angle. Fiber-optic conversion module according to one of the preceding claims, characterized in that the useful light is radiated cone-shaped from the light spot, wherein the light cone has an opening angle of at least 50 °, preferably at least 60 ° and more preferably at least 70 °. Fiber-optic conversion module according to one of the preceding claims, characterized in that the coupling head is at least partially formed as a reflector or comprises a reflector. Fiber-optic conversion module according to one of the preceding claims, characterized in that the carrier element is at least partially formed as a reflector or comprises a reflector. The fiber optic conversion module according to any one of the preceding claims, characterized in that the light exit end of the optical fiber is disposed in the mounted position such that it is outside of the useful beam angle, and / or does not extend into the reflector. Fiber-optic conversion module according to one of the preceding claims, characterized in that the carrier element is formed at least in the intended area for receiving the converter as a heat sink or comprises a heat sink for receiving the converter in heat-conducting and mechanically fixed connection. Fiber-optic conversion module according to one of the preceding claims 1 to 10, characterized in that the carrier element is made of a temperature-stable material, preferably made of a sintered material and particularly preferably of a metallic sintered material. Fiber-optic conversion module according to one of the preceding claims, characterized in that a light-permeable protective cover for protecting the converter and / or the light exit end of the light guide is provided, preferably made of glass and particularly preferably of a hardened glass. Fiber-optic conversion module according to one of the preceding claims, characterized in that means are provided to change the distance between the light exit end of the light guide and the center of the converter, starting from a predetermined distance, after assembly, preferably in a range of 0.05 mm up to 5 mm. Fiber-optic conversion module according to one of the preceding claims, characterized in that a focusing optical element is provided, which is arranged coaxially to the optical fiber in beam direction between the light exit end and the converter. Fiber-optic conversion module according to one of the preceding claims, characterized in that the focusing optical element comprises a lens, preferably a rod lens. Fiber-optic conversion module according to the preceding claim, characterized in that the lens comprises a cylindrical rod with a plane-polished light entrance surface and a lens-shaped curved light exit surface. The fiber optic conversion module according to any one of the preceding claims, characterized in that the optical fiber comprises a fiber core made of quartz glass and a fiber cladding made of quartz glass, and wherein the refractive index of the fiber cladding is lower than the refractive index of the fiber core. Fiber-optic conversion module according to one of the preceding claims, characterized in that the optical fiber is inserted into the coupling head and clamped and / or glued.

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