DE19840935B4 - End piece for optical fibers - Google Patents

Abstract

Termination piece for coupling radiation into an optical fiber (5, 28) and for decoupling radiation from an optical fiber (5, 28), the termination piece (26, 94) consisting of an elongated housing (132) which has a continuous, in Axially extending, cylindrical opening (130) for receiving the optical fiber (5, 28), from which the radiation emerges as a beam (144) from the end piece (26, 94) for connecting the optical fiber to other components, at the end of the Housing (132), to which the optical fiber (5, 28) enters, the optical fiber (5, 28) is received and guided within the housing, at the other end of the housing (132) a short focal length lens (133) is attached, the end the optical fiber (5, 28) within the continuous, axially extending, cylindrical opening (130) and the converging lens (133) are aligned and fixed relative to each other and that the exit point the radiation from the optical fiber (5, 28) lies approximately at the focal point of the converging lens (133) ...

Description

The invention relates to an end piece for coupling of radiation into an optical fiber and for coupling out radiation from an optical fiber, the end piece consisting of an elongated housing, which has a continuous, axially extending, cylindrical opening for Includes the optical fiber from which the radiation as ray beam from the end piece for connection the optical fiber emerges with other components at the end of the housing, at which the optical fiber enters, the optical fiber is recorded and inside the case guided is at the other end of the case a short focal length lens is attached to the end of the optical fiber within the continuous, axially extending, cylindrical opening and the converging lens aligned and fixed relative to each other are, and that the Exit point of the radiation from the optical fiber at about the focal point the converging lens lies and the bundle of rays emerging from the collecting lens Laser beam is aligned, and a socket for such Terminator.

A termination piece of this type is known ( DE-C-31 21 287 ). The exchange is to be facilitated by means of the known end piece in the case of optical fiber optics for the transmission of a high-energy laser beam by means of individual optical fibers. In order to couple radiation into the optical fiber, the arrangement of the optical fiber should be exactly aligned with the optical axis of the converging lens or both should be aligned - if not necessarily with the same accuracy as the optical fiber and the converging lens with one another - with the optical exit file of the laser. The measure which is provided in the known connector, to arrange the optical fiber in alignment with the optical axis of the converging lens, is brought about by the fact that the coupling and the coupling member are aligned coaxially with one another, ie they should fit coaxially into one another.

With the constructive design of the known end piece neither a precise one Coupling into the optical fiber still a precise coupling out of the optical fiber possible.

From the DE-A-29 38 910 a coupling piece is known. A sheath is applied to the fiber end of an optical fiber. The provision of this sheath is due to the fact that, due to manufacturing tolerances in the case of optical fibers, the fiber ends are provided with the said sheath when the fiber ends have been moved in a separate device in two directions perpendicular to one another and transverse to the light beam until a light beam has determined a particular one Takes up position in relation to an axis of perception. The sheath is only applied when an undesirable eccentricity of one optical fiber core relative to the other optical fiber core has been completed by appropriate processing of the optical fiber ends. After the measurement process in the device, which determines the respective eccentricities, the sleeves are thus provided with surfaces which are concentric to the light guide cores of the two optical fibers to be aligned, two fiber ends processed in this way, provided with respective sleeves, then being coupled using methods known per se ,

An object of the invention is to End piece for optical fibers to create, which is easy to manufacture and a very precise coupling into the optical fiber and / or a very precise coupling of the radiation from the optical fiber. Another object of the invention is to provide the fiber laser Optimal coupling of pump radiation into the laser fiber and / or the Optimal coupling of laser radiation from the laser fiber. In doing so the laser beam with defined values with regard to beam diameter, beam divergence, Centering and angular direction are decoupled. Should continue the end of the laser fiber into which the pump radiation enters, and that End from which the laser radiation emerges can be grasped precisely and permanently, in order to receive a module suitable for production and service. The radiation can according to the invention Use case z. B. coupled as a pump leak into the fiber and / or are coupled out as a parallel laser beam at the exit point diverge or e.g. at a certain distance from the exit point be focused. There is a desire to have the end piece as possible training small and with one or more fits as a reference surface or reference surfaces for the To provide alignment of the laser beam.

The task is solved according to the Invention in that an outer fit or more external fits as a reference surface or reference areas for the Alignment of the beam the laser beam is or are provided on the connector, which is defined in relation to the fit or fits is, with means in the connector to adjust the position of the optical fiber in relation to the fit or fits are provided.

Important features of the invention are specified in claim 1. Advantageous further developments of Invention emerge from the subclaims 2 to 27.

The invention is based on the following 1 to 13 explained in more detail. Show it:

1 a schematic diagram of a fiber laser (prior art),

1a an abbreviated representation of the fiber of the fiber laser (prior art),

2 an example of a termination piece (terminator) for coupling out the radiation from a fiber or the fiber of a fiber laser,

2a an example of a multiple arrangement for several end pieces,

3 an example of an end piece with adjusting screws,

3a a cross section through the end piece 3 in the area of the adjustment screws,

4 an example of an end piece with spherical adjusting elements,

4a a cross section through the end piece 4 in the area of the spherical adjustment elements,

5 an example of an embodiment of a closure piece with a conical fit for use in a socket,

6 an example of a multiple version for several end pieces,

6a the rear attachment of the end pieces according to 6 .

7 an example of an end piece with a rectangular cross section and a trapezoidal plan view,

7a a longitudinal section through the end piece according to 7 .

7b a cross section through the end piece 7 .

8th an example of an embodiment with a square cross section,

8a a cross section through the end piece according 8th .

9 an example of an end piece with a trapezoidal cross section,

9a an example of an end piece with a triangular cross section,

9b an example of an end piece with a honeycomb cross section,

10 a modular version of the fiber of the fiber laser according to 1 .

11 an example for the coupling of the pump energy into the fiber of the fiber laser according to 10 .

12 an example of a fiber laser with two outputs and

13 an example for merging two fiber lasers.

The invention is illustrated below an application example in the coupling of the pump radiation and the extraction of laser radiation in a fiber laser. The However, the invention is not limited to use in fiber lasers, but rather can be anywhere are used where radiation is coupled into an optical fiber or radiation from an optical fiber is to be coupled out, or where radiation emerges from an optical fiber.

In the 1 and 1a becomes the basic structure of a fiber laser arrangement 2 , also called fiber laser. In 1 is the energy of a pump source such. B. a laser diode, here pump source 18 called, via a coupling optics 3 to a suitable pump stain 4 shaped and into the laser fiber 5 coupled.

Such pump sources are for example in the parallel German patent application with the file number P 196 03 704 described. Typical pump cross sections of the laser fibers are approximately between 100 μm and 600 μm in diameter with a numerical aperture of approximately 0.4. The laser fiber 5 is on the coupling side 6 with a coupling mirror 7 provided that the pump radiation passes unhindered, but has a 100% reflection for the laser radiation. The coupling mirror 7 can be attached to the fiber end with a suitable holder or by gluing, but it can also be realized by direct vapor deposition of a suitable layer, such as is used in coupling mirrors for lasers, on the fiber end. On the decoupling side 11 the laser fiber 5 is a coupling mirror that is partially transparent to the laser radiation 12 attached through which the laser radiation 13 is decoupled. The decoupling mirror for the pump radiation advantageously has a 100% reflection. As a result, the remaining pump radiation is reflected back into the optical fiber, which is advantageous since the pump energy is better utilized and also does not interfere with the use of the laser radiation. The coupling-out mirror, like the coupling-in mirror, can also be produced by vapor deposition. The relatively large pump cross section 14 simplifies the coupling of pump energy and enables the use of an easily detachable connection between pump source and laser fiber, as in the 10 and 11 will be shown. The end piece of the laser fiber on the pump source side can advantageously be identical to the end piece on the outcoupling side, but it does not have to be. A precise plug connection between pump source and laser fiber offers considerable advantages in the manufacture of fiber lasers and in the event of service. The laser fiber can also be permanently connected to the pump source to form a laser module. As a result of the specifically produced, very small fiber core diameter, the fiber laser delivers practically diffraction-limited laser radiation at the exit 13 ,

In 1a is the coupling process of the pump radiation into the pump cross section 14 the laser fiber 5 , which is also referred to as double core fiber. The energy in the pump spot 4 stimulates the laser radiation in the core of the laser fiber on its way through the fiber 15 on. The pump core 16 is from a coat 17 surround. The approximately 5 μm to 10 μm thick core 15 the laser fiber 5 is predominant endowed with rare earths. As under 12 and 13 Described in more detail, passive fibers can also be connected to the active output of fiber lasers 28 Docking.

In 2 is a preferred embodiment of an end piece 26 (Terminator) for a fiber 28 or laser fiber 5 , which is also a fiber. Such end pieces can be used advantageously for the extraction of laser radiation from a fiber 5 . 28 are used, as described and used in the parallel German patent application "Process and arrangement for material processing by means of laser beams", filed by the applicant 98/1035 and filed simultaneously with the present application. This end piece 26 can basically be used for all applications where it comes down to the one fiber 5 . 28 Coupling emerging bundles of rays precisely with a detachable connection. It is also possible with the help of this end piece, a precisely detachable connection of the fiber 5 . 28 with the rest of the optics. The end piece consists of an elongated housing 132 , which has a continuous, axially extending, cylindrical opening 130 having. The housing is preferably made of prefabricated, for example drawn material, which can preferably consist of glass. The laser fiber 5 The fiber laser is preferably freed of its cladding on its last end and roughened on its outer surface, as is the case in the German patent application P 197 23 267 is described, so that the remaining pump radiation leaves the laser fiber before the laser fiber enters the end piece. The fiber 5 . 28 can also be used with a single or multi-layer protective cover 131 be surrounded by the housing 132 the end piece, for example by means of an adhesive 142 can be connected. The housing 132 shows fits 134 with which the housing in a socket 29 ( 2a . 5 . 6 . 11 ) can be used exactly. The fits can extend over the entire length of the housing ( 2 . 7 . 8th ), but they can also be installed in limited areas of the housing ( 3 . 4 . 5 ). There can be one or more seals 36 be provided, for example, by means of bonds 142 with the housing 132 are connected. The task of the seals is to create a gas-tight connection between the end pieces and the sockets 29 to enable. The housing can be in the area of the protective jacket 131 and the seal 36 have a different, for example smaller diameter than in the area of the fits. At one end of the case 132 becomes the end of the fiber 28 or the laser fiber 5 recorded and inside the housing in the opening 130 guided. At the other end of the case 132 is a short focal length lens 133 attached, the housing being a conical extension 139 can have to the laser radiation 13 not to hinder. Means can be used to adjust the position of the fiber 5 . 28 be provided within the end piece to the location of the fiber to the lens 133 within the end piece and in terms of fits 134 to adjust as in the 3 . 3a . 4 . 4a . 5 . 7a . 7b . 8th . 8a . 9 . 9a and 9b will be shown. It can also change the radial location of the fiber 5 . 28 through the cylindrical opening 130 can be determined, the fiber being axially displaceable within the opening. The location of the lens 133 can either be mounted with sufficient precision during assembly or by suitable means, not shown, with respect to the fiber 5 . 28 and on the fits 134 axially and / or radially adjusted and fixed, the fiber also being axially displaceable ( 2 ). The adjustments are advantageously made with a measuring and adjusting device. The aim of the adjustment is to ensure that this is out of the lens 133 emerging rays of radiation 144 to the fits 134 is brought into a predetermined axis and focus position with a defined cone. After fixing the fiber 5 . 28 inside the case 132 and the lens 133 the measuring and adjusting device is removed from the housing. According to the invention, it is also possible to end the fiber 5 . 28 in the area of the end piece before assembly with a suitable coating, for example a correspondingly thick metallization 141 in order to improve the durability of the adjustment. The fixation of the fiber 5 . 28 inside the case 132 can be done with suitable means such as gluing, soldering or welding. At the transition point between the housing 132 and the protective cover 131 is preferably an elastic mass 138 provided that provides additional protection for the fiber. It is also possible according to the invention, the lens 133 preferably on their ropes facing the fiber end by appropriate shaping and vapor deposition of an appropriate layer so that they perform the function of the coupling mirror 12 for the fiber laser.

2a shows a multiple arrangement of fiber laser outputs by means of the end pieces 2 , In one case 145 are holes 150 to hold two end pieces 26 intended for two tracks. Furthermore, the holes in the housing are extended 145 three pens each 148 and 149 attached in rows so that they have a lateral border as a socket 29 represent the end pieces and ensure precise guidance and alignment of the end pieces. The diameter of the pins 148 are denoted by d, and are preferably identical to one another. The diameter of the pins 149 are denoted by d ₂ and are preferably also identical to one another. If the diameter of the pins 148 equal to the diameters of the pins 149 would be the axes of the beams of both tracks in the drawing next to each other parallel because the end pieces 26 cylindrical fits 134 exhibit. But they are in 2a the diameter of the pins 149 larger than the diameter of the pins 148 shown, which leads to the fact that the axes of the two beams are at an angle to each other in the plane of the drawing. The angle between the beams depends on the diameter difference d ₂ - d ₁ and on the center distance M of the two rows of sifts. The end pieces are on the bottom in one plane through the housing 145 out and are guided from above through a cover, not shown, of the housing, which is fastened to the housing and can be closed gas-tight by means of a seal, not shown. The housing 145 can be part of a receptacle for an optical unit for shaping the laser radiation. The end pieces are by means of tabs 147 and screws, not shown, on the housing 145 attached, with the seals 36 ensure a gas-tight seal. The arrangement is not limited to two tracks, additional holes can be made 150 be provided and more pens 148 and 149 can be used to insert further end pieces for further tracks. The arrangement is also not limited to the one level described, further holes can be made 150 in the housing 145 in further tracks and in one or more other levels that are above or below the drawing level and thereby the pens 148 and 149 be extended to the extent that they are versions 29 for all tracks and all levels. According to the invention, pins are also used to generate a defined distance between the levels 148 and 149 used. In this case the pins run horizontally between the end pieces. For example, the horizontally arranged pins run 149 between the wall of the case 145 in which the holes 150 lie and the row of vertically arranged pins shown 149 , The horizontally arranged pens 148 preferably run at a distance M parallel to the horizontally arranged pins 149 , Horizontal pens are in 2a not shown. The pencils 148 . 149 are preferably made from drawn steel wire, but they can also consist of other materials, for example drawn glass. An advantage of the arrangement with multiple tracks and / or multiple levels in the manner shown is that the bars 148 . 149 have some flexibility. This makes it possible to compress the entire package from the end pieces in the direction of the tracks and in the direction of the planes in such a way that the end pieces 26 with their fits 134 rest on the pins without spacing, which is desirable for maximum precision.

In 3 is a final piece 26 shown with the means for adjusting the position of the fiber 5 . 28 are provided within the end piece to the location of the fiber 5 . 28 to the lens 133 within the end piece and in terms of fits 134 to adjust. The position of the lens can also be adjusted. The adjustments are advantageously carried out using an adjusting device. You can use it to adjust the position of the fiber 5 . 28 in the housing 132 adjusting screws 135 . 136 ( 3 . 3a . 7a . 7b . 8th . 8a . 9 . 9a . 9b ) and / or or balls 137 ( 4 . 4a . 5 ) be provided. Inside the adjustment screws 135 . 136 or bullets 137 can the fiber 28 or laser fiber 5 also be moved axially. The location of the lens 133 can either be assembled with sufficient precision during assembly or by means not shown in relation to the fiber 5 . 28 and on the fits 134 axially and / or radially adjusted and fixed, the fiber can also be axially displaced. The adjustments are advantageously made with a measuring and adjusting device. The aim of the adjustment is to ensure that this is out of the lens 133 emerging rays of radiation 144 by means of a relative delivery of lens 133 and fiber 5 . 28 to the fits 134 is brought into a predetermined axis and focus position with a defined cone. After fixing the fiber 5 . 28 inside the case 132 and the lens 133 the measuring and adjusting device is removed from the housing. Furthermore, the below applies to this and the further embodiments 2 Said, for example for the metallization 141 , the elastic mass 138 and the use of the lens 133 as a laser mirror.

In 3a is a cross section through the end piece 26 shown in the area of the adjusting screws, from which it can be seen that distributed around the circumference, preferably 3 adjusting screws 135 are provided with which the fiber 28 or the laser fiber 5 is finely adjustable in the housing. Furthermore, at the end of the end piece 26 on which the fiber 28 or the laser fiber 5 occurs, further adjusting screws within the end piece 136 be provided as in 3 are shown. These adjustment screws are like the adjustment screws 135 educated. Will only one set of adjusting screws 135 used, you can use the fiber 28 or the laser fiber 5 adjust only with respect to the angle. If two sets of adjusting screws are used, they can also be moved parallel to their axis. The fixation of the fiber 5 . 28 inside the case 132 can be done with suitable means such as gluing, soldering or welding.

4 shows an embodiment of the end piece 26 , where small balls instead of adjusting screws 137 made of metal or preferably metallized glass are used, which are brought into position in the housing and then glued or soldered. Several sets of balls can also be attached.

4a shows a cross section through the end piece in the region of the balls 137 ,

To prevent the optical surfaces chen on the optical fiber and the side of the lens 133 , which faces the optical fiber, can be contaminated by particles in the surrounding air 2 . 3 . 3a . 4 . 4a . 5 . 7a . 8th . 8a . 9 . 9a , and 9b shown connections between the lens 133 and the housing 132 as well as between the adjusting screws 135 and 136 or the balls 137 and the housing 132 be hermetically sealed. This can be done using suitable adhesive or soldered connections 142 respectively. In the event that a soldered connection is preferred, the glass parts are in the appropriate places 141 previously metallized. To achieve greater strength, the adhesive or soldered connections can also use the remaining gap between the fibers 28 or the laser fiber 5 and the housing 132 or the protective cover 131 Fill in all or part of what is in the vicinity of the end piece 2 is shown. It is also possible to change the interior 143 evacuate the housing permanently or fill it with a protective gas.

5 shows a further embodiment of an end piece 26 that in a housing 145 with a frame 29 is used. In this embodiment, the front outer fit is 134 in the area of the lens 133 conical for better sealing and better heat dissipation. In addition, a seal 146 be provided, which can be attached to the fiber-side end instead of as shown on the lens-side end of the end piece.

In 6 are versions 29 in one housing 145 for several conical end pieces 26 according to 5 shown. Such sockets are advantageous if several outputs of fibers or fiber lasers are to be arranged next to one another or next to and above one another. The housing can be used to dissipate the heat loss 145 According to the invention be provided with holes through which a coolant is passed.

6a shows the rear attachment of the end pieces 26 in the housing 145 , For fixing the end pieces 26 . 94 are tabs 147 provided the ends of the end pieces at the points where the fibers each in the housing of the end pieces 26 . 94 enter using screws 151 lock in the housing.

7 shows an embodiment of the end piece 94 with a rectangular cross-section, two opposite outer surfaces being trapezoidal and two opposite outer surfaces running parallel to one another. All opposite outer surfaces can also run in a trapezoidal shape with respect to one another. The outer surfaces can fit 134 his.

In 7a is a longitudinal section and in 7b is a cross section through the end piece according to 7 shown.

The 8th shows an embodiment of an end piece 26 with a square or rectangular cross-section, in which all opposite outer surfaces run parallel and fits 134 could be.

8a shows a cross section through the end piece 26 to 8th with a square cross section.

In 9 are end pieces 26 shown with trapezoidal cross-sections, so that when a number of end pieces are lined up by successively rotating the end pieces by 180 °, a series of end pieces is formed in which the centers of the end pieces lie on a central line. If desired, several such rows can be arranged one above the other, which in 9 is indicated by dashed lines.

In 9a are end pieces 26 shown with a triangular cross section, which can also be arranged in several rows one above the other, which is indicated by dashed lines.

9b shows end pieces 26 with hexagonal cross-section, which can be arranged in a honeycomb shape to increase the packing density.

10 shows an application example for the end piece 26 . 94 with a fiber 28 or a laser fiber 5 , which are provided at both ends with an end piece according to the invention and thus represent a fiber module.

It is possible according to the invention, the lens 133 preferably on its side facing the fiber end by appropriate shaping and vapor deposition of a corresponding layer so that it performs the function of the coupling mirror 12 with takes over. It is also possible according to the invention, the lens 3 . 154 by appropriate shaping and vapor deposition of a corresponding layer so that they perform the function of the coupling mirror 7 with takes over.

It is basically possible to use several of the above described end pieces in several Tracks side by side and in several levels one above the other to form a package summarize.

It is also possible to design the shape of the end pieces differently than shown in the figures, e.g. B. that a cylindrical shape after 6 trapezoidal or rectangular fits 7 or 8th receives.

11 shows a coupling of the laser fiber 5 to a pump source by means of the end piece 26 over the housing 152 in which the pump source 18 in a recess 153 is preferably housed gastight. Through a sealing ring 146 ensures that the end piece 26 also seals gas-tight, so that no dirt particles can penetrate from outside and it can be evacuated or filled with a protective gas if necessary. There can also be a constant flow of a protective gas through the recess 153 flow, especially with temporary Ent removal of the end piece 26 , About a lens 154 becomes the radiation from the pump source 18 on the pump cross section of the laser fiber 5 focused. The pump source can consist of one or more laser diodes, but it can also consist of an arrangement of one or more lasers, in particular also fiber lasers, the output radiation of which has been combined with suitable means so that a suitable pump leak occurs.

12 shows the branching of the output radiation from the laser fiber 5 a fiber laser using a fiber fusion coupler 155 , Such fiber fusion couplers are described in the catalog of the company Spindler and Hoyer, Göttingen, on page G16 for single-mode fibers and can be directly aligned to the output of the laser fiber after a correspondingly precise alignment 5 to melt. The end piece 26 . 94 is in this case to a passive single mode fiber or to another fiber 28 and not directly to a fiber laser with the active laser fiber 5 connected.

13 shows the combination of the radiation from the laser fibers 5 two fiber lasers via a fiber fusion coupler 156 , In the fiber fusion coupler 156 the cross sections of the two input fibers are combined into one fiber. For example, the diameter of the fibers at the two inputs of the fiber fusion coupler is 6 μm and the core diameter of the two laser fibers to be melted is also 6 μm. The core diameter of the fiber at the output of the fiber fusion coupler thus becomes 9 μm, which still allows a single mode to be guided properly for the wavelength in question. The diameter at the output of the fiber fusion coupler can also be greater than 9 μm and more than two outputs from fiber lasers or fibers can be combined. The end piece 26 . 94 in this case is a passive single mode fiber or other passive fiber 28 and not a fiber laser with the active laser fiber 5 connected. However, all other types of optical fibers can also be welded to the fiber laser or connected in some other way, for example via optics

You can also connect a single fiber mode to a passive single-mode fiber or another passive fiber 28 instead of a branch 12 or a union 13 couple to this single mode fiber or other fiber 28 then connect to the end piece. However, it is also possible to combine the outputs of a plurality of fiber lasers or single-mode fibers or other suitable fibers into which laser radiation can be coupled, via wavelength-dependent or polarized beam combiners or other suitable measures, and in turn to couple them into single-mode fibers or other fibers that are connected at one or both ends can be provided with a corresponding end piece.

Claims (27)

End piece for coupling radiation into an optical fiber ( 5 . 28 ) and for coupling out radiation from an optical fiber ( 5 . 28 ), the end piece ( 26 . 94 ) from an elongated housing ( 132 ) there is a continuous, cylindrical opening extending in the axial direction ( 130 ) to accommodate the optical fiber ( 5 . 28 ) from which the radiation acts as a beam ( 144 ) from the end piece ( 26 . 94 ) for connecting the optical fiber to other components, at the end of the housing ( 132 ) on which the optical fiber ( 5 . 28 ) occurs, the optical fiber ( 5 . 28 ) is received and guided inside the housing, at the other end of the housing ( 132 ) a short focal length converging lens ( 133 ) is attached, the end of the optical fiber ( 5 . 28 ) inside the continuous, axially extending, cylindrical opening ( 130 ) and the converging lens ( 133 ) are aligned and fixed relative to each other and that the point of exit of the radiation from the optical fiber ( 5 . 28 ) around the focal point of the converging lens ( 133 ) and the beam of the laser beam emerging from the converging lens ( 144 ) is characterized in that one outer fit or several outer fits ( 134 ) as a reference surface or reference surfaces for the alignment of the beam ( 144 ) of the laser beam from the end piece ( 26 . 94 ) is or are provided, which is defined in relation to the fit or fits, whereby in the end piece ( 26 . 94 ) Means for adjusting the position of the optical fiber ( 5 . 28 ) in relation to the fit or fits ( 134 ) are provided. End piece according to claim 1, characterized in that the axis of symmetry of the fit or fits ( 134 ) with the axis of symmetry of the fiber ( 5 . 28 ) coincides. End piece according to claim 1 or 2, characterized in that the axis of symmetry of the fit or fits ( 134 ) with the symmetry axis of the converging lens ( 133 ) coincides. End piece according to one of claims 1 to 3, characterized in that the axis of symmetry of the mating surfaces with the axis of symmetry of the from the converging lens ( 133 ) emerging laser beam ( 144 ) coincides. End piece according to one of claims 1 to 4, characterized in that the distance from the end of the fiber ( 5 . 28 ) to the converging lens ( 133 ) is selected so that the one from the converging lens ( 133 ) emerging laser beam ( 144 ) outside the end piece ( 26 . 94 ) is divergent. End piece according to one of claims 1 to 5, characterized in that the distance from the end of the fiber to the converging lens ( 133 ) is selected so that the one from the converging lens ( 133 ) emerging laser beam ( 144 ) outside the end piece ( 26 . 94 ) at a predetermined distance from the converging lens ( 133 ) is convergent. End piece according to one of claims 1 to 6, characterized in that the distance from the end of the fiber to the converging lens ( 133 ) is selected so that the one from the converging lens ( 133 ) emerging laser beam ( 144 ) outside the end piece ( 24 . 96 ) at a predetermined distance from the converging lens ( 133 ) is almost parallel. End piece according to one of claims 1 to 7, characterized in that within the housing ( 132 ) several adjusting screws distributed around the circumference ( 135 ) are provided with which the optical fiber ( 5 . 28 ) in the housing ( 132 ) is finely adjustable. End piece according to one of claims 1 to 8, characterized in that at the end of the end piece ( 26 . 94 ) on which the optical fiber ( 5 . 28 ) occurs, further adjusting screws ( 136 ) are provided. End piece according to one of claims 1 to 9, characterized in that small balls ( 137 ) made of metal or metallized glass, which are fixed after the adjustment. End piece according to one of claims 1 to 10, characterized in that the connections between the optical fiber ( 5 . 28 ) and the housing ( 132 ), the converging lens ( 133 ) and the housing ( 132 ) and the adjustment screws ( 135 ) and ( 136 ) or balls ( 137 ) be hermetically sealed and that the cavity ( 143 ) inside the housing ( 132 ) remains, preferably filled with protective gas. End piece according to one of claims 1 to 11, characterized in that the sealing points on the housing ( 132 ) are glued, soldered or welded. End piece according to one of claims 1 to 12, characterized in that the end of the optical fiber ( 5 . 28 ) in the end of his coat ( 17 ) is freed and preferably roughened on its outer surface. End piece according to one of claims 1 to 13, characterized in that the end of the optical fiber ( 5 . 28 ) is mirrored in such a way that the pump radiation is reflected and that the laser radiation is partially transmitted. End piece according to one of claims 1 to 14, characterized in that the end piece ( 26 . 94 ) at its front end in the area of the converging lens ( 133 ) is conical ( 5 ). End piece according to one of claims 1 to 15, characterized in that the end piece ( 94 ) in the area of fit or fits ( 134 ) has a rectangular cross section and that two of the longitudinally extending outer surfaces in the area of the fit or fits ( 134 ) trapezoidal to each other ( 7 . 7a . 7b ). End piece according to one of claims 1 to 16, characterized in that the end piece ( 26 ) in the area of fit or fits ( 134 ) has a square or rectangular cross-section and that the longitudinally extending outer surfaces in the area of the fit or fits ( 134 ) run parallel to each other ( 8th . 8a ). End piece according to one of claims 1 to 17, characterized in that the end piece ( 26 ) in the area of fit or fits ( 134 ) has a trapezoidal cross-section ( 9 ). End piece according to one of claims 1 to 18, characterized in that the end piece ( 26 ) in the area of fit or fits ( 134 ) has a triangular cross-section ( 9a ). End piece according to one of claims 1 to 19, characterized in that the end piece ( 26 ) in the area of fit or fits ( 134 ) has a hexagonal cross section ( 9b ). End piece according to one of claims 1 to 20, characterized in that the end piece ( 26 . 94 ) in the area of fit or fits ( 134 ) is cylindrical or conical. Socket for end pieces according to one of claims 1 to 21, characterized in that the socket ( 29 ) is designed so that the end pieces ( 26 ) inside the frame using pins ( 148 . 149 ) on the mating surfaces ( 134 ) are kept at a distance. Socket for end pieces according to claim 22, characterized in that the pins ( 148 . 149 ) have the same distance (M) from each other. Socket for end pieces according to claim 23, characterized in that the pins ( 148 . 149 ) have the same diameter. Socket for end pieces according to claim 23, characterized in that the pins ( 148 ), which are arranged at the beam outlet, have a different, preferably smaller diameter than the pins, which are located at the end of the end pieces, on which the fiber ( 5 . 28 ) entry. Version for End pieces after one of the claims 22 to 25, characterized in that the pins between the end pieces horizontally in Layers and / or arranged vertically in tracks. Socket for end pieces according to one of claims 22 to 26, characterized in that the socket in a housing ( 145 ), which has bores for receiving the end pieces, is arranged, the bores being sealed gas-tight by seals between the housing and the end pieces.