DE102007009819A1 - Light coupling device for optical fiber splicer, has illuminating device provided for coupling light into bend area of optical fiber, and light detecting device detecting light portion, which is decoupled through bend of another fiber - Google Patents

Abstract

The device has holding devices (21, 22) for retaining an optical fiber (18a) and another optical fiber (18b), and a bending device i.e. bending beam (20), for creating a bend of the optical fibers in the holding device. An illuminating device (10) e.g. LED, is provided for coupling light into a bend area of the optical fiber (18a). A light detecting device (11) detects a light portion, which is decoupled through the bend of the optical fiber (18b). The holding device comprises partial areas for retaining the optical fibers.

Description

The The invention relates to a light coupling device and in particular a light coupling device for an optical fiber splicer.

There are processor-controlled splicing known, which serve to produce mechanically strong, long-term stable and low-loss connections of optical fibers. 1 shows a schematic representation of such a device. This contains a display 27 as well as a panel 28 with various buttons in which a user can select the desired applications and splicing programs. For the splicing process, the ends of two fibers F and F0 are exactly aligned with respect to each other. For this purpose, the two fibers are fixed in clamp brackets, which under the cover shown 8th lie. Positioning of the fibers with respect to each other can be done manually or fully automatically by the user. After a precise alignment, the fibers are welded by means of an arc, which is between two under the lid 8th located electrodes is generated. The welding process is fully automatic, ensuring consistently good results regardless of the operator.

In order to check a splice quality, in addition to a visual evaluation of the actual splice connection, these devices often use an LID unit (Local Injection and Detection). This unit is under the operator-operated covers 7 and 9 , To insert a fiber, for example, the right fiber F0 this is in one of the cover flaps 8th and 9 located fiber guide so that they are the actual splice near the electrodes under the cover 8th protrudes. The cover 9 is then closed by rotation about an axis, so that the fiber F0 in a below the cover 9 existing groove is held. On the left side, the fiber F is moved accordingly.

2A shows the principle of a known LID system. By closing the covers 8th respectively 9 generates a connected bending coupler or bending beam a curvature in the optical fibers F0 and F. At this curvature or bending light is now coupled via a light source in the first fiber F0. During the splicing process, the resulting splice connection causes light to enter the second optical fiber F and is decoupled at the second curve and detected by a receiver and forwarded to the microprocessor. This controls the splicing process and can evaluate the quality of the splice connection by evaluating the level of the coupled-out light in the second fiber F. The diagram according to 2 B shows the light path of the coupled-out light as a function of the splicing time. Accordingly, to produce a good splice, the splicing process should be stopped when the maximum light level is reached.

This in 1 Splicer shown with the LID system, however, is complicated to use and requires by the flaps used 1 . 11 and 10 a particularly fine mechanism. Thus, the flaps may have little leeway, so that this costly and expensive manufacturing processes are necessary.

It There is therefore a need the operating costs for to reduce a LID system on the user side and the cost and Reduce production costs.

Of the Subject of the independent Claim 1 meets this need. further developments and embodiments are the subject of the dependent claims.

One Aspect of the invention is that the number of so far used flaps can be reduced, so that in the production lower production costs incurred. In addition, the operation simplified, as having access to the essential elements of the splicer Advantage by pressing a single flap is reached.

According to the invention a light coupling device, in particular for an optical fiber splicer, a holding device, which is equipped, at least a first optical fiber and at least to record a second optical fiber. A bending device is executed a bend or a bend the at least one first optical fiber and the at least one cause second optical fiber in the holder. Furthermore contains the light coupling device according to the invention a lighting device for coupling light in one bent portion of the at least one first optical fiber as well a light detecting device for detecting a by the curvature of at least one second optical fiber coupled out light component.

With the invention it is achieved that a holding device receives a plurality of optical fibers, which are bent by a Biegevorrich device for a light coupling or a light extraction in the holding device. This can be saved in contrast to the known light coupling devices a holding and a bending device. Furthermore, it is possible for the user to produce with a bending device alone the required curvature in both optical fibers in the holding device and thus both easier than faster to complete the preparatory measures for the splicing process.

In According to one embodiment of the invention, the holding device comprises a first guide groove for receiving the at least one first optical fiber and a second guide groove for receiving the at least one second optical fiber. The user can put the optical fibers in the guide groove. This will the operation simplified, mistakes avoided, and accuracy later LID measurement improved. Also, the guide groove is used with advantage to one improved positioning for a light coupling or light extraction.

The Light coupling device is both for the holder and generation a curvature in two optical fibers as well as for optical fiber bundles suitable. In a corresponding embodiment, the holding device contains several Subregions or guide elements for receiving in each case an optical fiber of the optical fiber bundle. to Improvement of the bending in the individual optical fibers is in another embodiment of the invention an additional Recess provided in the holding device, which is suitable to receive the bending device at least partially. In this embodiment becomes the one to be bent Optical fiber over led the depression away and subsequently Press the bending device into the recess so that the desired bend is generated in the optical fiber.

In a development of the invention is the lighting means as also the light detection device at least partially below the depression arranged. As a result, on the one hand, light from the Lighting device very simply coupled into the optical fiber and decoupled by the curvature Be measured by the detection device light. As a lighting device For example, a light emitting diode or a laser is suitable. In both cases it is expedient to have a focal point for that of the light source to produce emitted light in a region of the optical fiber, which includes the fiber optic core. This is also true at a bend or a slight shift of the core from its symmetrical Position out a sufficient coupling of a light component guaranteed. Likewise, slight shifts of the fiber within the holding device can be compensate.

In another embodiment of the invention are the at least one first optical fiber and the at least one second optical fiber arranged substantially perpendicular to the bending device. By becomes a vertical arrangement with respect to the bending device a strong curvature and thus achieved a good Lichtein- and light extraction. in this connection For example, the bending device may be formed as a bending beam be. It is also possible a V- or U-shaped Provide bending beam.

Next the bending beam can additional deflection devices be provided, which change the direction of the optical fiber, characterized Is it possible, for example, to attach the bending beam to a main lid, which also provides access to the actual splicing device with the electrodes allows. In this way, a user can easily open and Shut down a lid for the splicing process necessary measures take. In particular, by closing the single lid the for the LID system required curvature be generated.

in the Further, the invention with reference to the drawings based on several embodiments explained.

So demonstrate:

1 a known embodiment of a splicer,

2A the block diagram of a LID system with separate bending beam for coupling and decoupling of light,

2 B a time-intensity diagram for displaying a profile of the decoupled light component,

3 a schematic representation of a first embodiment of the invention,

4 a schematic representation of a second embodiment of the invention,

5 a section of a splicer for a representation of a third embodiment of the invention,

6 a representation of a fifth embodiment of the invention,

7 a representation of a sixth embodiment of the invention for optical fiber bundles.

3 shows a first embodiment of the light coupling device, as used for example in splicing devices for optical fibers. The light coupling device 19 contains a bending beam 20 , which is designed as a cylindrical tube or a simple cylinder. The cylinder 20 has in this embodiment a circular diameter R, which is slightly smaller than the distance between two substantially mutually parallel white stronger supports 21 . 22 , which are also designed as a cylinder. This creates between the surfaces of the columns 21 and 22 and the middle cylinder 20 a narrow space. Next to the circular cylinder shown here 20 can also be another form of the element 20 be used. For example, an elliptical cross section would be possible. This would create a different curvature in the optical fiber. Likewise, the supports may be a different shape, for example, semicircular or executed only with a partially curved course. The support and the bending beam cooperate in such a way that they cause a curvature of an inserted and fixed optical fiber.

In the arrangement are the two optical fiber 18A . 18B inserted by the bending beam 20 a curvature substantially in the size of the radius r of the bending beam 20 exhibit. The curvature is created by the bending beam on the two supports 21 and 22 applied fibers 18A . 18B in the interposed depression presses.

Furthermore, a light-emitting diode 10 as well as a photodetector 11 intended. The light-emitting diode 10 is arranged so that the light emitted by it by one in front of the light emitting diode 10 arranged lens 10a is focused. The focal point lies in a region of the curvature of the first optical fiber 18A such that light from the diode 10 in the conductor core of the optical fiber 18A couples. The photodetector is corresponding 11 near the optical fiber 18B arranged so that by the curvature of the optical fiber 18B decoupled light directly onto the photodetector 11 falls and generates a level-dependent signal.

The in the 3 illustrated embodiment thus allows it with the help of a single bending beam 20 in at least two optical fibers 18A and 18B to cause a corresponding curvature for coupling or decoupling of light. This can be the supports 21 and 22 as support surface for the optical fibers 18A and 18B also by corresponding semicircular or elliptical arches replace. Likewise, they may include guide grooves arranged such that an optical fiber is directly above the diode 10 and / or the photodetector. This simplifies operation. The radius r of the columns 21 and 22 and the radius R of the bending beam 20 and the distance between the elements is chosen such that the curvature caused thereby in the optical fibers 18A and 18B is sufficient for the generation of an input or light outcoupling.

4 shows a further embodiment of the invention. Here is a semicircular or an elliptical recess 24 intended. This has at its two end regions V-shaped grooves 25 for receiving and guiding the optical fibers 18A and 18B are designed. An operator can insert the optical fibers to be spliced into the corresponding guide grooves. Subsequently, the bending beam 20 pressed into the recess, whereby the optical fibers are curved and fixed accordingly. Again, the radius of the bending beam is 20 as well as the depression 24 chosen such that the curvature caused by the bending beam in the optical fibers for a coupling or decoupling of light is sufficient. The holding device 24 is made of a transparent material. Below the device 24 are the light emitting diode 10 as well as the photodetector or another light detection means 11 arranged below a connecting line between the guide grooves. This allows a focus of the light for the coupling into one of the two glass fibers due to the guidance of the guide easier to realize.

The optical fibers to be spliced into the guide grooves 25 along the depression 24 inserted. Then they are in the holding and positioning units 16 attached, with part of the optical fibers on the positioning 16 also available. The units 16 position the ends of the two optical fibers to be spliced to each other between the two electrodes 12 the splice unit. Of course, the two steps can also be exchanged.

Then the covers are closed and the splicing process started and light through the diode 10 in for example the glass fiber 18B coupled. During the splicing process, more and more light now passes from the first optical fiber 18B in the second optical fiber 18A about the newly developed splice connection. This light is at least partially decoupled by the curvature generated by the bending beam and the detector 11 detected. The detected signal is fed to a microprocessor, which adjusts the splicing time and the other splicing parameters on the basis of the signal curve. As soon as the intensity of the decoupled light component no longer increases, the splicing operation can be ended.

5 shows a further embodiment. Here is the bending beam 20 on a lid 60 attached, which is rotatable about an axis 63 is stored. This cover is part of the splicer and protects the splice area and the electrodes. It contains additional elements on its inside, such as mirrors or prisms. These are needed to the ends of the two optical fibers relative to the electrode tips 14 each other to position on the opposite side. At the same time it protects the electrodes and the glass fiber ends against possible damages or impurities during the splicing process. For a splicing process, the lid 60 opened and the optical fibers 18A such as 18B in the guide grooves of the holding device 24 inserted. In addition, the splicer contains additional guide elements 30 , which is a deflection of the two optical fiber 18A and 18B cause them to be in the positioning units 16 can be attached. The from the deflectors 30 however, the curvature produced is less than that caused by the bending beam 20 and the LID system caused, so that no light is coupled or disconnected here.

If necessary, these can also be omitted, provided that sufficient space for the attachment of the optical fibers in the positioning 16 is available. After locking in the positioning units 16 and in the guide grooves of the holding device 24 becomes the lid 60 around his axis 63 turned and closed. For this purpose, for example, the bending beam may comprise a magnetic material, so that it is fixed in the holding device. Through the bending beam 20 in the recess of the holding device 24 In addition, a curvature in the two optical fibers 18A and 18B generated. Subsequently, with the aid of a camera positioning system, the ends of the two optical fibers are in relation to each other and to the electrode tips 14 aligned. These are the positioning units 16 Positionable along the x and y directions. After completion of positioning, light is coupled in one of the two optical fibers via the generated curvature and the splicing process by generating an arc between the electrode tips 14 started.

6 shows a further embodiment in which the bending beam is fixed in the form of an open "V" on the cover of the splicer. The execution by means of a "V" as a bending beam allows, possibly less additional guide elements 30 to use. In the embodiment, the optical fibers 18A and 18B substantially perpendicular to the corresponding portion of the bending beam 21 arranged. A vertical arrangement is advantageous in that it generates the largest curvature in the respective optical fibers with a fixed radius of the bending beam. Here, too, of course, further fixing elements or guide grooves may be provided, which allow a simplified operation and in particular a simple locking and alignment of the optical fibers in the splicer.

In addition to alignment and locking of only two optical fibers, the arrangement according to the invention is also suitable in LID systems for optical fiber bundles. 7 shows such an embodiment. This is a first Lichtleitbündel 18 with a variety of individual optical fibers 18A and a second Lichtleitbündel 18C with a variety of optical fibers 18B in each case a positioning unit 16 attached. This is displaceable along the z-direction and the x-direction, so that the ends of the individual optical fibers of the two light bundles 18 and 18C in the area of the electrode tips 14 can be positioned to each other. Subsequently, the individual optical fibers of the bundle 18 and 18C in a variety of positioning grooves 17 a holding device 24 inserted. The holding device is designed as a recess. To generate a curvature in the individual optical fibers 18A and 18B becomes a first bending beam 20A with elliptical shape and a second bending beam 20C in the recess of the holding device 24 introduced.

Below the recess light emitting diodes are mounted which couple light into the curved fibers. For this purpose, a common diode for all optical fibers, but also multiple diodes for individual groups of fibers or even individual fibers can be used. Likewise, corresponding lenses are conceivable which distribute the light generated by the diode to a plurality of focal points in which the cores of the optical fibers extend for the coupling. In the same way, a plurality of detectors for the coupled-out light can be provided. In the embodiment, the two bending beams 20A and 20B executed for weight reasons as separate bars. These produce the same curvature, but can also produce different curvature. However, it is also conceivable to use only a single bending beam for generating a curvature in all optical fibers.

By the use of a single holding device and a bending beam for the Generation of curvatures in at least two splices to be spliced Optical fibers is an operation of a LID system and the Splicer on the part simplified by the user. In addition, if the bending beam on the lid is fixed, can by the inventive design of the light coupling device the number of covers required to be reduced. Thereby Reduce the manufacturing costs and the cost of precision engineering Processing.

1

microprocessor

2

Spleißgenerator

7, 8, 9

cover

10

Illumination means led

11

Light detection device photodetector

12

Electrode tip holder

14

electrode tip

16

positioning

18 18C

optical fiber bundle

18A, 18B

optical fiber

19

LID-System

20

bending beam

21 22

Holder, cylinder

24

holder

25

guide

27

display

28

Control panel

30

guide elements

60

cover

63

axis of rotation

Claims (17)

Light coupling device, in particular for an optical fiber splicer comprising: - a holding device ( 21 . 22 . 24 ), which is configured, at least a first optical fiber ( 18a ) and at least one second optical fiber ( 18b ); A bending device ( 20 . 20a . 21 ), which is configured, a curvature of the at least one first optical fiber ( 18a ) and the at least one second optical fiber ( 18b ) in the holding device ( 21 . 22 . 24 ) to cause; A lighting device ( 10 . 10a ) for coupling light into a curved region of the at least one first optical fiber ( 18a ); A light detection device ( 11 ) for detecting a by the curvature of the at least one second optical fiber ( 18b ) decoupled light component. A light coupling device according to claim 1, wherein the holding device ( 21 . 22 . 24 ) a first subregion ( 25 ) for receiving the at least one first optical fiber ( 18a ) and a second subregion for receiving the at least one second optical fiber ( 18b ). Light coupling device according to one of claims 1 to 2, wherein the holding device ( 24 ) a first guide groove ( 25 ) for receiving the at least one first optical fiber ( 18a ) and a second guide groove for receiving the at least one second optical fiber ( 18b ) having. Light coupling device according to one of claims 1 to 3, wherein the holding device ( 24 ) comprises a recess leading to a partial reception of the bending device ( 20 . 21 ) is executed. A light coupling device according to any one of claims 1 to 4, wherein the bending device ( 20 . 21 ) at least partially comprises a circular segment-shaped surface, which faces the curved region in a recording of the at least one first optical fiber. A light coupling device according to any one of claims 1 to 4, wherein the bending device ( 20 . 21 ) comprises at least partially an elliptically extending surface which corresponds to the curved region of the at least one first optical fiber ( 18a ) is opposite. Light coupling device according to one of claims 1 to 6, wherein the holding device ( 21 . 22 . 24 ) two spaced support elements ( 21 . 22 ) for supporting the at least one first and at least one second optical fiber. A light coupling device according to any one of claims 1 to 7, wherein the at least one first optical fiber ( 18a ) and the at least one second optical fiber ( 18b ) substantially perpendicular to the bending device ( 20 . 21 ) are arranged. Light coupling device according to one of claims 1 to 8, wherein the illumination device ( 10 . 10a ) comprises a light emitting diode. A light coupling device according to any one of claims 1 to 9, wherein the illumination device ( 10 . 10a ) a focusing device ( 10a ) comprising a directed light beam having a focus in a region of a fiber core of the at least one first optical fiber. A light coupling device according to any one of claims 1 to 10, in the light-detecting device (10). 11 ) comprises a photodetector. Light coupling device according to one of claims 1 to 11, wherein the holding device ( 21 . 22 . 24 ) one for light of the illumination device ( 10 . 10a ) has transparent material. A light coupling device according to claim 12, in which the illumination device ( 10 . 10a ) and / or the light detection device ( 11 ) is at least partially disposed below a surface of the holding device opposite the optical fibers. A light coupling device according to one of claims 12 to 13, in which the illumination device ( 10 . 10a ) and / or the light detection device ( 11 ) below a connecting line of two guide elements ( 25 ) of the holding device ( 24 ) are arranged. A light coupling device according to claim 12, wherein between the holding device ( 21 . 22 . 24 ) and the optical fibers ( 18a . 18b ) a transparent gel-like material is arranged. A light coupling device according to any one of claims 1 to 15, further comprising: - a splice region; - a cover ( 60 ) around an axis ( 63 ) is rotatably mounted and covers the splice region, wherein the bending device ( 20 . 21 ) is attached to the cover. Splicer with one A light coupling device according to any one of claims 1 to 16, wherein the holding device and the bending device on the splicer for connecting optical fibers are attached.