DE19857928A1 - Integrated laser module coupled to ribbon light conductor e.g. for lighting device, has alignment reference surfaces provided by integrated laser module for positioning ribbon light conductor in 2 directions - Google Patents

Abstract

The integrated laser module (1) has a connection device (64) for coupling its linear light output opening to a ribbon light conductor (76), provided with a ferrule (75) for reception of the latter, with alignment reference surfaces provided by the integrated laser module adjacent the light output opening, for positioning the ribbon light conductor in 2 different directions. Also included are Independent claims for: (a) a ferrule for reception of a ribbon light conductor; (b) a connection device for coupling an integrated laser module with a ribbon light conductor; and (c) a lighting device

Description

The invention relates to an integrated laser module to which a band optical fiber can be coupled. Continue to be the invention relates to a ferrule for receiving a tape Optical fiber and a connection device for ver binding of an integrated laser module with a belt Optical fiber that has a ferrule. Finally be the invention meets a lighting device that an inte laser module and a ribbon optical fiber points.

The invention is based on the problem of Coupling optical fibers to an integrated laser module.

The invention is characterized by the subject of the independent An sayings solved. Advantageous configurations result from the respective dependent claims.

According to the invention, a lighting device is provided, which are integrated in an integrated laser module and in a Optical fiber structure, with the ribbon optical fiber Provide a ferrule in the area of an inlet opening is. A ferrule is an essentially ring-shaped one Body surrounding the ribbon optical fiber at that end summarizes where the inlet opening is provided.

The integrated laser module according to the invention has one line-shaped outlet opening for radiation, to the in a coupling direction of the ribbon optical waveguide can be coupled. There is little in the area of the outlet opening at least a first module reference surface area is provided. The Module reference surface area is designed so that the band optical fibers to be coupled in a first direction transverse to the coupling direction with respect to the outlet opening  is definable. It is also in the area of the outlet opening according to the invention at least a second module Reference area area provided. The second module The reference surface area is designed so that the band optical fibers to be coupled in a second, from the first direction different direction transverse to the coupling direction tion with respect to the outlet opening can be determined.

The laser module designed according to the invention can be used a ribbon optical fiber with a Ferru invention le or with a connecting device according to the invention particularly easy to fix and position precisely.

The laser module can be a leadframe with a casing have, wherein the first module reference area as Housing recess is formed in the area of the leadframe. Then the second module reference surface area can be used as a housing Seausform formed in the area of the outlet opening the. This can be done with conventional manufacturing techniques Manufacture trained laser module particularly easy, where advantageously the inherently stable leadframe itself Can provide module reference surface area. Leave with it use laser modules particularly advantageously, the have a TO220 housing.

According to the invention, the first module reference surfaces area and the second module reference area area each be designed as guide surfaces that have a common, in Have coupling edge extending cutting edge. With like this trained module reference surface areas is a special exact guidance of the integrated laser module with respect a ribbon optical fiber possible. The casing can Seausforming two wedge-shaped horizons have valley reference areas. This results in a be particularly precise guidance of a ribbon optical fiber to the Exit opening of the laser module. If the housing recess two vertical reference surfaces running parallel to each other  has, is also a secure attachment of a Band optical fiber possible on the laser module.

According to the invention it is further provided that each egg ne housing recess connects to one housing shape each. This allows a particularly small-sized laser module provide.

The invention also relates to a ferrule for receiving a Band optical fiber. The ferrule according to the invention has a line-shaped optical waveguide opening on, in a coupling direction a band light waves head is predictable. Furthermore, at least a first one Ferrule reference surface area provided, so trained det is that the ferrule in a first direction transverse to Coupling direction with respect to a first module Reference surface area of a laser module can be determined. In addition, at least one second ferrule Provided reference surface area which is designed that the ferrule is in a second, from the first direction different direction with respect to a second module Reference surface area of the laser module can be determined. With Such a ferrule can be a ribbon optical fiber particularly easy and precise coupling to a laser module.

The first ferrule reference area and the second ferrule reference surface area as Ferru lenausschluß be formed, in particular the shape egg podium if guide surfaces are provided that a common cutting edge running in the coupling direction exhibit. With such a pedestal one can be special achieve precise guidance of the ferrule on the laser module.

The ferrule recess can be two wedge-shaped to each other horizontal reference surfaces and two to each other have parallel vertical reference surfaces. With one of the Art designed ferrule recess is a special one  reliable connection between ferrule and laser module reachable.

According to the invention, a connecting device for Connection of an integrated laser module with a belt Optical fiber can be provided, which is a ferrule in the loading has an entrance opening. The connection direction has at least a first connection direction reference surface area, which is designed so that the connector is transverse in a first direction for the coupling direction with respect to a first module Reference surface area of a laser module can be determined.

Furthermore, at least one second connection device Reference surface area can be provided, which is designed in this way is that the connecting device in a second, from the first direction different direction with respect to a two th module reference surface area of the laser module can be determined is.

Furthermore, a guide device for receiving the Ferrule of the ribbon optical fiber provided. With a such connection device can be particularly simple detachable connections between ribbon optical fiber and La Manufacture the module.

The guide device can be used as a guide pin for ver binding with a guide hole provided in a ferrule or as a guide hole for connection to an egg ner ferrule provided guide pin may be formed. There can be a particularly simple trained verb Provide equipment.

The guide device can also be in the coupling direction guiding shaft to accommodate a ferrule have, the guide shaft with a substantially Chen tapered insertion funnel can be provided. With a guide device designed in this way,  particularly easy detachable connections between belt Manufacture optical fibers and laser modules that are always reliable work casually.

Finally, the invention is also in a lighting device realized that an inventive laser module, a Ribbon optical waveguide with a ferrule according to the invention and / or a connecting device according to the invention points. In addition, a clamping device for solvable ren, non-positive connection of ferrule and laser module be provided, which has holding elements on the Ferrule and / or can be attached to the laser module.

With the invention, ribbon optical fibers can be like Glass tapes as optical fibers in a simple way on high Power laser modules, especially in a standard TO220 Connect the housing. Band optical fibers have in mind preferably dimensions of 4.8 mm in width and 100 µm in the height. The principle of solution of the invention is also different re geometries of glass strips applicable. With the fiction According to ferrules, the ends of such ribbon optical fibers reliably manageable. The invention results in a high coupling efficiency between a laser bar that also out can consist of several individual lasers, and a glass ribbon. In this case, a close tolerance is advantageous of the offset between the outcoupling laser bar and the coupling glass tape adhered to. Result with the invention there are several ways to implement the invention underlying knowledge.

A variety of glass ribbons can be made with the invention a high light output from several lasers to bring it to a predetermined location.

The invention is in the drawing based on Ausführungsbei play illustrated.  

Fig. 1 shows a perspective view of an OF INVENTION to the invention the laser module,

Fig. 2 shows a perspective view of Lasermo duls of Fig. 1 together with a Verbin of the connection device-making apparatus in a state prior to placement on the laser module,

Fig. 3 shows a perspective view of the laser module of FIG. 2 direction with attached Verbindungsein,

Fig. 4 is a perspective view showing a further connecting device,

Fig. 5 is a perspective view showing a ferrule OF INVENTION to the invention,

FIG. 6 shows a perspective illustration of the ferrule from FIG. 5 in a state before being plugged together with a further laser module according to the invention,

Fig. 7 shows the ferrule and the laser module of FIG. 6 in-together state,

Fig. 8 shows a perspective view of a further ferrule according to the invention,

Fig. 9 shows the ferrule of FIG. 8 and the laser module of FIG. 1 in the assembled state,

Fig. 10 is a perspective view showing a wide ren ferrule according to the invention,

FIG. 11 shows the ferrule from FIG. 10 and the laser module from FIG. 1 in the assembled state,

Fig. 12 is a perspective view showing a further connecting device according to the invention,

Fig. 13 shows the connecting means of FIG. 12 and the laser module of FIG. 1 in a state prior to assembly,

Fig. 14 is a perspective view showing a further ferrule of the invention and

FIG. 15 shows the connecting device and the laser module from FIG. 13 and the ferrule from FIG. 14 in the assembled state.

Fig. 1 shows an inventive integrated laser module 1 in a perspective view. The laser module 1 has essentially the shape of a TO220 housing and is divided into a metallic leadframe 2 with a substantially rectangular plan, in a radiation generating device not visible in this view, from which an elongated radiation exit area 3 and a total of three connection contacts 4 are added are seen and in a plastic housing 5 .

The dimensions of the radiation exit area 3 are approximately 4.8 mm × 100 μm. The radiation exit area 3 runs ver on a front edge 6 of the lead frame 2 and is flush with this towards the front.

In the area of the front edge 6 , the plastic housing 5 is designed as an optical waveguide connection area 7 . The light waveguide connection area 7 is divided into two Leadfra measuring areas 8 with a rectangular plan, on which the plastic housing 5 is excluded, so that the leadframe 2 is bare. In the area between the leadframe areas 8 , a connecting platform 9 is formed in such a way that the radiation exit area 3 is encompassed in the center.

The connecting platform 9 has two reference side surfaces 10 , of which only one can be seen in this view. The reference side surfaces 10 are arranged so that they taper ko and form an imaginary cutting edge in the extension. On the upper side of the connecting platform 9 , a seat 11 is also formed, which connects the upper edges of the reference side surfaces 10 to one another. The seat 11 runs parallel to the Leadframeberei chen 8th The connecting platform 9 finally has a bottom end face 12 which , starting from the front edge 6 of the Leadfra mes 2, extends obliquely upwards.

The optical waveguide connection area 7 is closed towards the rear in the direction of the connection contacts 4 by a housing end face 13 which is parallel to the platform end face 12 and to the front edge 6 of the lead frame 2 .

The laser module 1 is configured such that a view in this to not shown band light waveguide pelrichtung in a Ankop which is light illustrated by directional arrow 14, ankop to the optical fiber connection portion 7 Pelbar is.

Fig. 2 shows the laser module 1 of Fig. 1 together with a coupling bridge 15 which is designed so that it leniden in the Lichtwel connection area 7 can be attached to the laser module 1 . The coupling bridge 15 is divided into two Brückenpfei ler 16 , which are connected by a bridge plate 17 . The bridge piers 16 have two horizontal reference surfaces 18 pointing towards one another, of which only one can be seen in this view. The horizontal reference surfaces 18 are designed so that they match in the attached state of the coupling bridge 15 on the optical fiber connection area 7 with the reference side surfaces 10 of the connecting platform 9 , as can best be seen in FIG. 3, that the laser module 1 in assembled state with the Koppelbrüc ke 15 shows.

As can best be seen in FIG. 2, the coupling bridge 15 in the area of the bridge pillar 16 each has a vertical reference surface 19 , which in the assembled state of the coupling bridge 15 lies with the laser module 1 on the leadframe regions 8 . This state is also shown in Fig. 3. In addition, the coupling bridge 15 also has a rear contact surface 20 , of which only an outline edge can be seen in FIG. 2. The contact surface 20 is in the assembled state of the coupling bridge 15 with the laser module 1 on the Ge housing end face 13 , as can best be seen in FIG. 3.

Finally, the bridge piers 16 each have a guide bore 21 extending in the direction of the coupling 14 , into each of which a guide pin 22 can be inserted, as can best be seen in FIG. 4.

In the attached state shown in FIG. 3 of the coupling bridge 15 on the laser module 1 , an adhesive, not shown in this view, is provided on the respective connecting surfaces, which ensures a firm connection between the coupling bridge 15 and the laser module 1 .

Fig. 5 shows a perspective view of a ferrule 23 according to the Invention, which receives a ribbon optical fiber 24 so that an entry region 25 of the ribbon optical fiber 24 closes flush with an end face 26 of the ferrule 23 from. The entrance area 25 coincides with its dimensions substantially with those of the radiation exit area 3 .

The end face 26 is formed as a region of a ferrule housing 27 which points in the direction of the coupling direction 14 . The ferrule housing 27 has on its side facing away from the end face 26 a ferrule base 28 which is widened relative to the end face 26 . In the interior of the ferrule housing 27 , guide bores 29 run out of the end face 26 .

Finally, the ferrule housing 27 still has a ferrule opening 30 which is centered in the ferrule housing 27 and extends transversely to the coupling direction 14 . Adhesive can be filled into the ferrule opening 30 with which the band optical waveguide 24 is glued into the ferrule housing 27 .

Fig. 6 shows the ferrule 23 in a state before the Ankop PelN to the coupling bridge 15 provided with the laser module 1. As can be seen particularly well in this view, the ferrule 23 is arranged in front of the laser module 1 in such a way that the guide bores 29 lie in front of the guide pins 22 . By plugging the ferrule 23 onto the guide pins 22 in coupling direction 14 , the end face 26 is then brought into connection with the pedestal end face 12 , whereby the entry area 25 of the band optical waveguide 24 is brought into the area of the radiation exit area 3 of the laser module 1 .

In the assembled state of ferrule 23 and laser module 1 , these are firmly connected to one another via a plastic clamp 31 shown in FIG. 6, so that the ferrule 23 can no longer be detached from the laser module 1 . For this purpose, the plastic clamp 31 has a holding section 32 which is provided on its side facing the ferrule 23 with two support cams 33 , only one of which is shown in this view. The support cam 33 engages in the ferrule 23 and guides it relatively roughly so that it does not slip out of the outer housing. Furthermore, a helical spring 34 is provided which engages in an opening provided in the ferrule base 28 , not shown in this view and in an opening not shown here in the plastic clip 31 . Two clamp arms 35 adjoin the holding section, each of which is provided with a catch 36 at its end. In the assembled state of the plastic clip 31 , ferrule 23 and laser module 1 , the coil springs 34 press the ferrule 23 against the action of the detents 36 on the back of the housing 5 against the laser module 1 .

Fig. 7 shows a further variant of the connection between the ferrule 23 and the laser module 1. In this embodiment, the housing 5 is encompassed by a metal clip 37 which has egg ne clip base 38 with an opening 39 for the connection contacts 4 and two spring arms 40 connecting to the clip base 38 . Each spring arm 40 is provided at its end with a spring hook 41 , which is formed as a section bent bent schlörför each spring arm 40 . The spring hook 41 engages in a not shown here, provided in the rear of the ferrule base 28 fastening opening. Against the resilient action of the spring hook 41 , the ferrule 23 is pressed against the laser module 1 .

Fig. 8 shows a perspective view of another he inventive ferrule 42 for receiving a band-Lichtwel lenleiters 43 , which has an elongated inlet opening 44 . The ferrule 42 has a plastic housing 45 , which is divided into a holding area 46 for the ribbon optical fiber 43 and a bridge area 47 for coupling to the laser module 1 from FIG. 1. The bridge area 47 corresponds in its outer shape essentially to the Koppelbrüc ke 15 from FIG. 2, so that it cooperates with the connecting platform 9 in such a way that the inlet opening 44 when the ferrule 42 is coupled to the laser module 1 in the region of the radiation exit area 3 of the Laser module 1 comes to rest.

The bridge area 47 is divided into two bridge pillars 48 , which are connected to one another at their top by a bridge plate 49 . The bridge pillars 48 are each formed on their mutually facing inner sides as a horizontal zonal reference surface 50 , of which only one can be seen in FIG. 8. On their underside, the bridges pillars 48 are each formed as a vertical reference surface 51 , which are parallel to one another. The two horizontal reference surfaces 50 intersect in their extension in an imaginary cutting line, which is not shown here. Finally, the ferrule 42 also has a housing face 52 and a bridge face 53 .

In the assembled state of the ferrule 42 with the laser module 1 , which is illustrated in FIG. 9, the bridge end face 53 comes into contact with the housing end face 13 and the housing end face 52 of the ferrule 42 comes into contact with the leading edge 6 of the leadframe 3 . The vertical reference surfaces 51 lie on the leadframe regions 8 and the horizontal reference surfaces 50 contact the Refe rence side surfaces 10 of the connecting pedestal 9 in contact. In this way, a precise guidance and positioning of the inlet opening 54 of the ribbon optical waveguide 43 to the radiation exit region 3 of the laser module 1 is ensured.

In the assembled state according to FIG. 9, the ferrule 42 and the laser module 1 are held together by a metal clip 54 , which is divided into a base region 55 with an opening 56 for the passage of the connection contacts 4 as well as into two spring arms 57 . The spring arms 57 each have a snake-shaped area at their ends to form a spring hook 58 , each of which engages in a recess on the rear side of the ferrule 42 and provides a firm connection between the laser module 1 and the ferrule 42 . An Anpreßvor direction, not shown in this view, which acts on an upper side of the ferrule 42 , prevents the ferrule 42 from detaching from the laser module 1 in the x direction. This effect is illustrated in FIG. 9 by a pressure arrow 59 .

FIG. 10 shows a further ferrule 60 according to the invention, the essential parts of which correspond to the ferrule 42 from FIGS. 8 and 9. The same parts are therefore provided with the same reference numbers.

The ferrule 60 additionally has, in the area of a bridge pier 48, a laterally projecting spring bollard 61 , which is provided with an annular groove 62 .

As best seen in Fig. 11, in the coupled state of the ferrule 60 to the laser module 1 on each Federpol ler 61, a coil spring 63 is attached and hooked to spring bollards, not shown in this view, of a laser cooling provided under the laser module 1 . In this way, a firm yet detachable connection between the ferrule 60 and the laser module 1 is established.

FIG. 12 shows a coupling bay 64 for connecting a ribbon optical waveguide (not shown in this view) to the laser module 1 from FIG. 1. The coupling bay 64 is shown in FIG. 13 in a state before being assembled with the laser module 1 .

The coupling bay 64 is divided into a coupling region 65 for coupling to the optical waveguide region 7 of the laser module 1 and in a receiving region 66 for receiving a ribbon optical waveguide, not shown in this view, with a ferrule, also not shown.

The coupling bay 64 is provided in the receiving area 66 with a ferrule receiving opening 67 with a rectangular cross section, which completely passes through the receiving area 66 in the coupling direction 14 . The ferrule receiving opening 67 has two side surfaces 68 and two longitudinal surfaces 69 , only one of which can be seen in FIG. 12. At the Austrittsbe rich of the ferrule receiving opening 67 of the coupling bay 64 , a circumferential insertion funnel 70 is further formed so that the ferrule receiving opening 67 extends over the introducing judge 70 to the outside. This ensures easy insertion of a ferrule (not shown here) into the ferrule receiving opening 67 .

In the coupling area 65 , the coupling bay 64 is designed as an Ankoppelman tel 71 open at the bottom, as can best be seen in FIG. 13. The coupling jacket 71 is so shaped that when the coupling bay 64 is in the exposed state, the laser module 1 comes into contact with the plastic housing 5 . As can be seen particularly well in FIG. 13, two bridge piers 72 are arranged in the interior of the coupling jacket 71 , only one of which is shown. The bridge pillars 72 essentially coincide with the bridge pillars 16 from FIG. 2. They are designed so that they come into contact with the laser module 1 via a horizontal reference surface 73 and a vertical reference surface 74 with reference side surfaces 10 and lead frame 8 .

Fig. 14 shows a ferrule 75 according to the invention, which is intended for acquisition in the ferrule receiving opening 67 of the coupling bay 64 from FIGS . 13 and 14. The ferrule 75 has a ribbon optical waveguide 76 which has an elongated entry opening 77 which ends with a face 78 of the ferrule 75 . The ferrule 75 is divided into a guide area 79 , the outer contour of which is designed such that it can be inserted with an exact fit into the ferrule receiving opening 67 of the coupling bay 64 . The guide area 79 has two side surfaces 80 and two longitudinal surfaces 81 , of which only one is shown in FIG. 14. In the inserted state of the ferrule 75 in the coupling bay 64 , the side surfaces 80 abut the side surfaces 68 of the ferrule receiving opening 67 . In the same way, the longitudinal surfaces 81 bear against the longitudinal surfaces 69 . The guide area 79 is followed by a ferrule base 82 which is widened relative to the guide area 79 .

FIG. 15 shows the ferrule 75 from FIG. 4 and the coupling bay 64 and the laser module 1 from FIG. 13 in the assembled state. As can be seen particularly well in this view, the ferrule 75 with the guide area 79 is inserted into the ferrule opening 67 of the coupling bay 64 . The coupling jacket 71 of the coupling bay 64 partially covers the plastic housing 5 of the laser module 1 . In this state, the inlet opening 77 of the band optical waveguide 76 lies in the region of the radiation outlet region 3 of the laser module 1 . Ferrule 75 , coupling bay 64 and laser module 1 are held together in this state by a metal bracket 83 , which has a bracket base 84 with a passage opening 85 provided therein for the contacts 4 and two bracket arms 86 , which are based on the Klammerba sis 84 to the ferrule 75 extend. At their ends, the clamp arms 86 are each provided with a spring hook 87 , which engage in the depressions (not shown in this view) in the ferrule base 82 . Due to the resilient action of the spring hook 87 , the ferrule 75 is compressed via the coupling bay 64 with the laser module 1 .

With the invention, a detachable connection of a TO220 Housing with a glass ribbon by means of a ferrule. In a first step, the glass ribbon is converted into a ferrule glued in for this purpose a highly precise recess to hold the glass ribbon. To get an exact guide later to achieve a housing of a laser the ferrule has two guide holes for guide pins. The posi tion of the guide holes is in relation to the position of the adhered glass tape to within a few micrometers bar.

A bridge is glued to the housing of the laser itself, which also has guide holes on the side of the laser. Further versions of this bridge can already contain the required guide pins. The guide pins can also form a unit together with the component to be glued on, for example as a one-piece injection molded component. The position of the guide pins can be maintained with very high accuracy in relation to the component to be glued. The exact position of the bridge to be glued in relation to a laser bar of a laser module is determined in the horizontal direction by the side geometry of the TO220 housing and in the vertical direction by the lead frame of the laser, which also serves as a reference edge for individual lasers and also for the optical fiber ribbon can. A ferrule assembled with the waveguide tape is now pressed onto the laser module either by means of a spring in a housing or with a spring plate. The exact positioning of the glass ribbon is ensured via the guide pins already mentioned. The configurations listed above are shown in FIGS. 1 to 7.

Detachable connections between the glass ribbon and the laser module can be easily created using the versions shown in FIGS. 8 to 11. Components of the laser module, such as cooling fins and the like, can be used to press the ferrule onto the laser module.

In another version, shown in FIGS. 12 to 15, no guide pins are required for the exact guidance of a ferrule. Instead, a coupling bay to be glued to a TO220 housing is designed such that it has a plug-in bay or a ferrule receiving opening. The interior dimensions of this plug-in bay should be adhered to with great accuracy in this variant. A ferrule is inserted from the outside, which advantageously does not require any guide holes. The outer dimensions of the ferrule should only have small tolerances. When plugged in, the ferrule is guided precisely via its outer geometry and the inner geometry of the coupling bay. The assembled ferrule can either be pressed against the housing of the laser via a further structure with a spring or with a spring plate. The coupling bay is aligned relative to the individual lasers of the laser module on the one hand via the geometry of the TO220 housing and on the other hand via the lead frame of the laser module.

In a non-releasable version, the coupling bay and the ferrule can also be glued to the laser module 1 using an adhesive which is particularly index-adapted. This results in particularly good attenuation values and low values for light loss.

In a further embodiment of the invention, the Coupling bay and the ferrule combined one component, being completely as a non-detachable connection to the laser housing be stuck on.

Claims (20)

1. Integrated laser module ( 1 ), which has the following features:

• - A line-shaped outlet opening ( 3 ) for radiation, to which a ribbon optical waveguide ( 24 ; 43 ; 76 ) can be coupled in a coupling direction ( 14 ),
• - In the area of the outlet opening ( 3 ) at least a first module reference surface area ( 8 ) is provided, which is designed such that the band-optical fiber to be coupled ( 24 , 43 ; 76 ) in a first direction transversely to the coupling direction ( 14 ) with respect From the opening ( 3 ) can be determined,
• - In the area of the outlet opening ( 8 ) at least a second module reference surface area ( 10 ) is provided, which is designed such that the band optical fiber to be coupled ( 24 ; 43 , 76 ) transversely in a second direction different from the first direction to the coupling direction ( 14 ) with respect to the outlet opening ( 3 ) can be determined.

2. Integrated laser module according to claim 1, characterized in that a lead frame ( 2 ) with a housing sheath ( 5 ) is vorgese hen, the first module reference surface area ( 8 ) being formed as a housing recess in the area of the lead frame ( 2 ) and wherein the second module reference surface area ( 10 ) is designed as a housing shape ( 9 ) in the area of the outlet opening ( 3 ). 3. Integrated laser module according to one of the preceding claims, characterized in that the first module reference surface area and the second module module reference surface area are each formed as guide surfaces ( 8 , 10 ) which have a common cutting edge in coupling direction ( 14 ) exhibit. 4. Integrated laser module according to claim 2 or claim 3, characterized in that the housing shape ( 9 ) has two wedge-shaped mutually ver horizontal reference surfaces ( 10 ). 5. Integrated laser module according to one of claims 2 to 4, characterized in that the housing recess has two mutually parallel de vertical reference surfaces ( 8 ). 6. Integrated laser module according to one of claims 3 to 5, characterized in that each a housing recess ( 8 ) to each of a housing formation ( 10 ) connects. 7. ferrule ( 42 ; 60 ) for receiving a ribbon optical fiber ( 43 ), which has the following features:

• - A linearly extending Lichtwellenlei ter Opening, in which in a coupling direction ( 14 ) of the ribbon optical fiber ( 43 ) can be provided,
• - At least a first ferrule reference surface area ( 50 ) which is designed such that the ferrule ( 42 ; 60 ) in a first direction transverse to the coupling direction ( 14 ) with respect to a first module reference surface area ( 10 ) of a laser module ( 1 ) can be determined is
• - At least one second ferrule reference surface area ( 51 ), which is designed such that the ferrule ( 42 ; 60 ) in a second, from the first direction different direction to the coupling direction ( 14 ) with respect to a second module reference surface area ( 8 ) of the laser module ( 1 ) can be firmly placed.

8. Ferrule according to claim 7, characterized in that the first ferrule reference surface area ( 50 ) and the second ferrule reference surface area ( 51 ) are each formed as a ferrule recess. 9. Ferrule according to claim 7 or claim 8, characterized in that the first ferrule reference surface area ( 50 ) and the second ferrule reference surface area ( 51 ) are each formed as guide surfaces which have a common, in the coupling direction ( 14 ) extending cutting edge. 10. A ferrule according to claim 8 or claim 9, characterized in that the ferrule recess has two wedge-shaped horizontal reference surfaces ( 50 ). 11. Connection device ( 15 ; 64 ) for connecting an integrated laser module ( 1 ) with a ribbon optical fiber ( 24 ; 76 ), the ribbon optical fiber ( 24 , 76 ) with a ferrule ( 23 ; 75 ) being provided,
the connecting device ( 15 ; 64 ) having the following features:

• - At least one first connecting device reference surface area ( 18 ; 73 ), which is designed such that the connecting device ( 15 ; 64 ) in a first direction transverse to the coupling direction ( 14 ) with respect to a first module reference surface area ( 10 ) of a laser module ( 1 ) can be determined,
• - At least one second connecting device reference surface area ( 19 ; 74 ), which is designed such that the connecting device ( 15 ; 64 ) in a second direction different from the first direction transversely to the coupling direction ( 14 ) with respect to a second module reference surface area ( 8 ) the laser module ( 1 ) can be determined,
• - At least one guide device ( 21 , 22 ; 67 ) for receiving the ferrule ( 23 ; 75 ).

12. Connecting device according to claim 11, characterized in that the guide device is designed as a guide pin ( 22 ) for connection with a Ver in a ferrule ( 23 ) provided Füh approximately bore ( 29 ). 13. Connecting device according to claim 11 or claim 12, characterized in that the guide device as a guide hole for connection with a guide provided in a ferrule pin is formed. 14. Connecting device according to one of claims 11 to 13, characterized in that the guide device is designed as a guide shaft ( 67 ) extending in the coupling direction ( 14 ) for receiving a ferrule ( 75 ). 15. Connecting device according to claim 14, characterized in that the guide shaft ( 67 ) has an essentially conically tapering insertion funnel ( 70 ). 16. Illuminating device which has the following features:

• - An integrated laser module ( 1 ), which has a linearly extending outlet opening ( 3 ) for radiation, to which in a coupling direction ( 14 ) a band optical fiber ( 43 ) can be coupled,
  and which has at least a first module reference surface area ( 10 ) in the area of the outlet opening ( 3 ), which is designed such that the band optical waveguide ( 43 ) to be coupled in a first direction transverse to the coupling direction ( 14 ) with respect to the outlet opening ( 3 ) can be determined,
  and in the area of the outlet opening ( 3 ) has at least a second module reference surface area ( 8 ) which is designed such that the band optical waveguide ( 43 ) to be coupled in a second direction different from the first direction transverse to the coupling direction ( 14 ) can be fixed in relation to the outlet opening,
• - A ribbon optical waveguide ( 43 ) which has an inlet opening ( 44 ) arranged in the region of the outlet opening ( 3 ), the ribbon optical waveguide ( 43 ) being provided with a ferrule ( 42 ; 60 ) in the region of the inlet opening ( 44 ) , the
  has a first ferrule reference area ( 50 ) in the area of the first module reference area ( 10 ), the first module reference area ( 10 ) and the first ferrule reference area ( 50 ) being designed in such a way that the band optical waveguide ( 43 ) in a first direction transverse to the coupling direction ( 14 ) with respect to the outlet opening ( 3 ), and
  wherein said ferrule (42; 60) (8) further comprises in the range of the two-th module reference surface area a second ferrule reference surface area (51), wherein the second module reference area (8) and the second ferrule reference surface area (51) so out forms that the band optical waveguide ( 43 ) in a second, different from the first direction transverse to the coupling direction ( 14 ) with respect to the outlet opening ( 3 ) is fixed.

17. Illuminating device according to claim 16, characterized in that
an integrated laser module according to one of claims 2 to 6 is provided, and / or that
a ferrule is provided in particular according to one of claims 8 to 10. 18. Lighting device which has the following features:

• - An integrated laser module ( 1 ), which has a linearly extending outlet opening ( 3 ) for radiation, to which in a coupling direction ( 14 ) a band optical fiber ( 24 ; 76 ) can be coupled,
  and in the area of the outlet opening ( 3 ) has at least a first module reference surface area ( 10 ) which is designed such that the band optical fiber ( 24 ; 76 ) to be coupled in a first direction transverse to the coupling direction ( 14 ) with respect to Can be determined from the outlet opening ( 3 ),
  and which has at least one second module reference surface area ( 8 ) in the area of the outlet opening ( 3 ), which is designed in such a way that the band optical waveguide ( 24 ; 76 ) to be coupled is transverse to the coupling direction in a second direction which is different from the first direction ( 14 ) can be defined with respect to the outlet opening,
• - A connecting device ( 15 ; 64 ) for connecting the integrated laser module ( 1 ) with the ribbon optical fiber ( 24 ; 76 ), the connecting device ( 15 ; 64 ) having the following features:
  at least one first connecting device reference surface area ( 18 ; 73 ), which is designed such that the connecting device ( 15 ; 64 ) in a first direction transverse to the coupling direction ( 14 ) with respect to the first module reference surface area ( 10 ) of the laser module ( 1 ) is determinable
  at least one second connecting device reference surface area ( 51 , 74 ), which is designed such that the connecting device ( 15 ; 64 ) in a second direction different from the first direction transversely to the coupling direction ( 14 ) with respect to the second module reference surface area ( 18 ) of the laser module ( 1 ) can be determined,
• - at least one guide device ( 21 , 22 ; 67 ) for receiving a ferrule ( 23 , 75 ),
• - A ribbon optical waveguide ( 24 ; 76 ), which has an opening ( 25 ; 77 ) arranged in the area of the outlet opening ( 3 ), the ribbon optical waveguide ( 24 ; 76 ) in the region of the entrance opening ( 25 , 77 ) with a ferrule ( 23 ; 75 ) is seen ver.

19. Lighting device according to claim 18, characterized in that
an integrated laser module according to one of claims 2 to 6 is provided, and / or that
a connecting device according to one of claims 12 to 15 is provided, and / or that
a ferrule is provided in particular according to one of claims 8 to 10. 20. Lighting device according to one of claims 16 to 19, characterized in that a clamping device for releasable non-positive Ver Binding of ferrule and laser module is provided.