Abstract:
The crimp splice serves the purpose of connecting light waveguide fibers which are fixed by radial pressure. For this purpose, the light waveguide fibers are placed in a guide channel in the base surface or area of, for example, an outer part, are pressed against one another, and are fixed by a clamping action between an inner part and the outer part. A required pressing power for the clamping is achieved by pressing legs of the two parts together. The crimp splice is simple to produce and permits easy assembly.

Description:
BACKGROUND OF THE INVENTION 
     Various mechanical splice connections for light waveguides are known. Thus, U.S. Pat. No. 4,818,055, incorporated herein, discloses a splice connection wherein the light waveguide fiber (core and sheath) is guided and clamped in a splice element which is bent U-shaped The splice element is part of a splice connection that also contains housing and fastening devices for the splice element and the light waveguides. This splice connection is extremely involved. Moreover, strict tolerancing of the components is required in order to fix the light waveguide fibers with a defined pressing power. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of the invention to specify a mechanical splice that can be simply produced. 
     This object is achieved by a crimp splice according to the invention wherein an oblong outer part is provided which has a base portion designed as a surface, and which also has two angled-off legs that can be bent together. An inside part is fitted into the outside part. A guide channel for acceptance of light waveguide fibers between the inner part and outer part is provided. This guide channel is located in a direction of a longitudinal axis in the base portion surface of the outer part or a base portion surface of the inner part. The guide channels at opposite ends of the crimp splice are enlarged for acceptance of a relatively thicker coated portion of the respective light waveguides. 
     The simple structure of the crimp splice is advantageous. This also guarantees a simple splicing of the light waveguides with a simple tool. 
     It is especially advantageous when the inner part and the outer part of the crimp splice (crimping=pressing) is produced of sheet metal bent in U-shaped fashion. After the introduction of the light waveguide, the legs of the two parts are bent together. The required radial pressing power for the light waveguide fibers is thereby produced. 
     It is advantageous when one part, for example the outer part, is designed longer than the other part and comprises guide means for the light waveguide fibers. The insertion into the guide channel is thus considerably facilitated. 
     It is advantageous when the base of the outer part is inwardly arced and/or the base of the inner part is outwardly arced. Cavities in the corners of the U-shaped parts thus arise which, due to the capillary effect, prevent an emergence of the coupling fluid required for the splicing that is adapted to the refractive index of the light waveguide cores. 
     A mechanical fastening of the inner and of the outer part with form-fitting joining elements such as, for example, folds, clips, recesses, eyelets or beads is expedient. Screwed or riveted connections can thus be foregone and the splicing is merely comprised in pressing the inner part further into the outer part and bending the legs together. 
     It is expedient to provide two catch steps between the inner and the outer part. The introduction of the light waveguide fibers occurs in the first catch step, and the light waveguide fibers are already pre-fixed in the second catch step. The required pressing power for fixing the fibers is produced by pressing the legs of the outer part together. 
     It is advantageous when the inner part is produced of a thinner, elastic sheet metal, whereas the outer part is fabricated of a bendable sheet metal having lower elasticity. 
     It is also possible to manufacture the inner part as a cuboid or as a hollow profile, for example of plastic material as well. The outer profile can have a significantly broader base than the inner profile around which it is then bent. 
     It is preferable when the sheet metals employed have a low coefficient of thermal expansion. As a result thereof, the pressing power changes only slightly, given temperature fluctuations. 
     It is advantageous when the guide channels provided in the inner part or in the outer part for the insertion of the light waveguide fibers are widened at their ends such that the light waveguide fibers with a coating thereon are guided and, as warranted, can also be pressed for strain relief. This not only facilitates the introduction of the light waveguide fibers; a protection against buckling and, potentially, a strain relief, also automatically results due to the widened guide channels. 
     It is preferable to provide two or more different steps in the widened guide channel for various light waveguide diameters. As a result thereof, light waveguides having different outside diameters can be employed for splicing, or a single embodiment of the crimp splice can also be employed for different light waveguides. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a side view of the crimp splice; 
     FIG. 2 is a sectional view of the crimp splice; 
     FIG. 3 is a completely assembled crimp splice; 
     FIG. 4 is a first form-fitting possibility for joining; 
     FIG. 5 is a further form-fitting possibility for joining; 
     FIG. 6 illustrates the employment of beads for achieving a further catch step; 
     FIG. 7 shows the use of a cuboid or hollow member as an inner part; 
     FIG. 8 is a version of the finished crimp splice; 
     FIG. 9 is a version of the outer part; 
     FIG. 10 is a view of the guide channels; 
     FIG. 11 is a plan view of a version of the outer part; 
     FIG. 12 is a bottom view of the corresponding version of the inner part; 
     FIG. 13 is a section through the crimp splice with bent-off legs; 
     FIG. 14 shows a side view of the crimp splice; and 
     FIG. 15 illustrates details of the crimp splice after the mounting of the light waveguide fibers. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 shows the side view of a crimp splice. Its outer part 1 is connected to an inner part 8 at the legs by clips 2, 3 (and further clips that are not visible in this view). Two light waveguides 6 and 7 whose fibers abut in a guide channel (not shown here for reasons of clarity, but shown below at 24 in FIG. 3 or 12 in FIG. 2) are fixed between the bases of the two parts 1 and 8. The inner part is positioned in the outer part by two lateral guides 26. 
     FIG. 2 shows the crimp splice in section. The outer part 1 is formed by a base portion 36 and the legs 28 and 29. A light waveguide fiber 10 (fiber; core and sheath) is fixed in a guide channel 12 in inner part 8 (only schematically shown) by the outer part 1 pressing against the fiber. The fiber 10 is fixed between the base areas 31 and 32 of the outer part 1 and of the inner part 8, which, for example, are each respectively produced of sheet metal bent in U-shaped fashion or trapezoidally, namely in the middle of the base area 32 of the inner part. The inner part is connected to the outer part by angled clips 2 and 14 that project into recesses 9 and 5 of the inner part. Longitudinal beads 11 and 15 which initially project into the clips of the outer part 1 provide a first catch position of the inner part in the outer part when the light waveguide fibers are being first introduced between the base areas of the outer and inner parts. The crimp splice is supplied for mounting of the light waveguides in this first catch position. 
     The light waveguide fibers whose coating was removed over a length given by the dimensions of the crimp splice are pushed against one another in the guide channel 12 and are then fixed by pressing the inner part into the second catch position wherein the inner part 8 is joined to the outer part 1 at the legs with clips 2 in recesses 9. Subsequently, the legs of the crimp splice are bent together in order to achieve a higher radial pressing power, as a result whereof the inner part is crushed or clenched, and the outer part is stretched. The fixing occurs entirely or partially on the basis of the pressure exerted onto the light waveguide fibers. 
     The legs 28 and 2 of the crimp splice are bent together in FIG. 3. Two clearances 16 and 17 thus derive such that, due to the capillary effect, they prevent the coupling fluid, required in assembly for joining the light waveguide fibers, from emerging. This coupling fluid is already applied when delivering the crimp splice to the junction location of the light waveguides. 
     The outer part 1 can be fabricated of any plastifiable material. After the legs are pressed together, they should not spring back too greatly. Thin and elastic material can be employed for the inner part 8. It thus exerts low force onto the legs of the outer part and manages a constant pressing power against the light waveguide fibers. A guide channel 13 for the light waveguide fibers as shown in FIG. 10 proceeds in the base part 36 of the outer part here in this alternate embodiment for the guide channel. As a result of the sectional view shown here that proceeds through a widened guide channel 24, however, it cannot be seen; it can, however, be derived from FIG. 10 showing both the narrower guide channel 13 and widened guide channel 24. 
     The widened guide channel 24, and an upper guide channel 33 widened because of manufacturing tolerances, serve for the acceptance of the coated light waveguide in the FIG. 3 embodiment. The light waveguide is conducted through these channels in order to achieve an anti-buckling protection for the respective fiber, and may potentially be pressed thereagainst for strain relief. 
     On the basis of incisions into the legs and into the base area, the inner part and the outer part can be designed such that a largely separate pressing of the coating and of the fiber occurs. 
     FIG. 4 shows a further possibility for achieving a form-fitting connection. The clip 2 here projects into an eyelet 18 of the inner part. When the eyelet is applied more deeply, or given a recess, the clip can also proceed obliquely relative to the plane of the legs in order to always guarantee a reliable connection. The mechanical strength is deteriorated less given the employment of eyelets instead of recesses. 
     In FIG. 5, two half-beads 19 and 20 engage into one another. The mechanical stability of the crimp splice is thereby further enhanced. 
     FIG. 6 shows a further possibility for achieving a further catch position. A bead 4 (also shown in FIG. 1) in the leg of the outer part engages into a bead 34 of the inner part at the first catch position; it is accepted by a second bead 35 of the inner part in the second, ultimate catch position so that the legs of the two parts can lie intimately against one another. 
     A cuboid inner part 21 that also comprises the guide channel 12 for the acceptance of the light waveguide fibers 10 is provided in the crimp splice shown in FIG. 7. For example, this inner part can be fabricated of plastic. The light waveguide fibers are fixed by bending the legs of the outer part 1 over. In order to obtain a constant pressing power that is largely independent of the assembly, an elastic transition piece 22 can also be placed under the legs (FIG. 8). 
     FIG. 9 shows a crimp splice whose outer part 23 has a broadened base area. A simpler, defined pressing is possible in this version. The broadening can also be at both sides when a guide for the inner part is provided in the outer part. The inner part is fabricated of a hollow profile 30 here. The guide channel schematically shown in FIGS. 7 through 9 can be designed in accordance with the exemplary embodiment of FIG. 3. 
     The guide channels in the outer part of the crimp splice of FIG. 1 are enlarged and not shown true-to-scale in FIG. 10. The first guide channel 13 serves the purpose of accepting the light waveguide fibers. The second guide channel 24 is provided for a light waveguide (including coating) having a smaller outside diameter; and the third guide channel 25 is matched to the diameter of a light waveguide having a larger outside diameter. 
     The light waveguide fibers can be placed from above into the largest guide channel in order to then be pushed into the narrower guide channels for splicing. Due to a widened portion 27, the light waveguide having a coating can also be easily pushed into the second or third guide channel. The guide channels including the widened portion can be produced by stamping or by etching. As intrinsically known, the guide channels can comprise a V-shaped or trapezoidal cross section, and can be provided in the outer part or inner part, or in both parts. 
     FIG. 11 shows a version of the outer part 1V wherein the legs 28, 29 are subdivided by two incisions 37 and 38 or 39 and 40 to form three leg portions. The middle leg portions 49 and 50 later serve the purpose of producing the necessary pressing power for the light waveguide fibers. In order to facilitate a bending of the leg portions, shaped passages 41 are always provided. However, a plurality of bores can also be employed. The base portion also comprises spacers 42, 48 that are designed as beads. 
     The inner part 8V shown in FIG. 12 is designed in conformity with the outer part. The incisions 43 through 46 in the legs 53, 54 nearly coincide with the incisions of the outer part 1V. Corresponding passages 47 are also again provided with which the legs 53, 54 are respectively divided into three leg portions. The middle leg portions 51 and 52 in the inner part 8V have a somewhat greater length than the middle leg portions 49, 50 in the outer part 1V. The outer leg portions of the inner part 8V, by contrast, are shorter than the outer leg portions of the outer part 1V as shown most clearly in FIG. 13. 
     FIG. 13 shows a section through the longitudinal axis of the outer part 1V with the inserted inner part 8V, given legs bent up at right angles. Since the middle leg portions 51, 52 of the inner part 8V are slightly longer than the middle leg portions 49, 50 of the outer part 1V, only a narrow gap can be respectively seen. The introduction openings for the light waveguide fibers can also be seen. 
     FIG. 14 shows the condition in which the crimp splice is delivered. The outer leg portions are inwardly angled off so that the inner part 8V is held in non-slidable fashion in the outer part 1V in a longitudinal direction as well. The light waveguide fibers can be introduced in this condition. Subsequently, the middle leg portions 49, 50 and 51, 52 are also bent together, as shown in FIG. 15. The pressing power is thereby arising in the middle portion of the crimp splice which presses against the light waveguide fibers and fixes them. The outer regions of the crimp splice can be designed such that a fixing of the coating occurs when one continues to press the outer leg portions together. Dependent on the materials employed, it may be more expedient to fix only the light waveguide fibers in order to avoid stresses caused by temperature fluctuations. 
     Although various minor changes and modifications might be proposed by those skilled in the art, it will be understood that I wish to include within the claims of the patent warranted hereon all such changes and modifications as reasonably come within my contribution to the art.