DE4130706A1 - Optical jack-plug incorporating optical coupler - has optical fibre inserted in capillary provided by jack-plug pin and divergent optical paths coupled to rear optical fibres - Google Patents

Abstract

The optical jack-plug has a optical fibre (5) providing the base arm of a Y coupler (6) at the front end of the jack-plug and two further diverging optical paths providing the Y arms of the coupler (6) at the rear end of the pack-plug. Pref. the pack-plug pin (2) has a central capillary (7) receiving the first optical fibre (5), with a flange (3) at the rear and of the pin (2) provided by a sleeve (8) receiving a holder (4) enclosing the optical coupling (6) and supporting the optical fibres (10, 11) spliced to the ends of its diverging optical paths. USE/ADVANTAGE - For bidirectional data transmission. Suitable for low-cost mass prodn.

Description

Plugs with couplers of the present design are used for Use in systems of optical communication technology, for example for data transmission by means of bidirectionally used Transmission links.

From DE-OS 23 12 015 is a connector with an optical Fibers manufactured coupler in Y configuration known, in which the Base branch led out at the rear of the connector as connecting fiber serves while the other two fiber branches on the front of the Connector ends. This consists of two cuboids Pre-assembled half shells, between which the coupler is set. The two half-shells form one on the coupling side protruding rib that is used when grinding and polishing the End faces of both fiber ends is removed. After this The front of the front housing is polished by upper shaping finished into a manageable housing. This happens in the Way that a groove is formed on two diametrical sides is used to guide the locking fingers of a complementary connector serve. Its housing contains e.g. B. a light emitting and a Light receiving diode, which after connecting both plugs on the end faces of the two fiber branches of the coupler are aligned.

The invention has for its object a plug to create integrated optical coupler that with the Optical fiber of a transmission link is connectable. For The task also includes a method for producing such Specify connector. This object is achieved with the Features of claim 1 and those specified in claim 8 Process features resolved. Appropriate individual features of the invention can be found in the subclaims.

The solutions have the advantage that the connector is very structurally is simple and without difficulties with tools, devices and measuring devices that can be manufactured in manufacturing plants for Optical communications technology already available are or can be made. The plug is characterized by a small size and can be used in series production be produced inexpensively.

The invention is illustrated by means of a drawing Embodiment described in more detail as follows. The drawing shows a top view of a connector with integrated coupler, cut lengthways.

In the drawing, the connector for optical fibers is designated by 1 in total. The plug 1 essentially consists of a plug pin 2 with a rear flange 3 and a holding part 4 arranged in the rear extension of the plug pin 2 and a glass fiber 5 fixed centrally in the plug pin 2 , which forms the extended base branch of an optical coupler 6 fastened in the holding part 4 , which in the illustrated embodiment has a Y configuration, but can also have three or more rear fiber branches with connecting fibers. The plug is designed for use in a commercially available coupling housing, in which it is held by a union nut and can be connected to a complementary fiber optic plug without an optical coupler.

A central capillary 7 passes through the plug pin 2 , the diameter of which is matched to the diameter of the glass fiber 5 used and which contains the glass fiber 5 fixed therein with an adhesive. The plug pin 2 can be made of metal, such as. B. stainless steel, ceramic or glass. If a version made of metal is used, the flange 3 is preferably part of the connector pin. If the plug pin 2 consists of a commercially available ceramic part, the flange 3 , as the embodiment shown in the drawing shows, as a one-piece, separately from z. B. stainless steel or nickel silver bushing 8 is formed. In this case, the rear end of the plug pin 2 is fastened, for example by means of a press fit, in a front socket half having the flange 3 and has a larger diameter. The rear half of the bushing of smaller diameter serves to receive and fix the holding part 4 , which consists of a tube with a longitudinal slot and is made of Kovar. Socket 8 and holding part 4 are z. B. attached to each other by welding at 9 . If necessary, the socket 8 and the holding part 4 can, however, also be made in one piece.

In the slotted tube of the holding part 4 , the optical coupler 6 z. B. attached with epoxy adhesive. The holding part 4 is preferably dimensioned so long that the two rear connecting fibers 10 , 11 with the outer sheath 12 can still be fixed at the free end in the holding part. This is done in such a way that the adhesive covers both the end of the sheath 12 of both connecting fibers 10 , 11 and a piece of the bare glass fibers protruding therefrom. The remaining space of the tube, in particular between the glue point and the plug pin 2 , is poured out with silicone gel. A mechanical strain relief and anti-kink protection is a shrink tube pushed onto the holding part 4 and the connecting fibers 10 , 11 with a surrounding shrink tube, which can also serve to identify the connector type (not shown).

In the manufacture of the plug 1 shown in the drawing, the separately manufactured parts, such as plug pin 2 , socket 8 with flange 3 and holding part 4 , are first attached to one another in the manner described above, and the optical coupler 6 is then produced in parallel therewith. This is a fusion coupler that is pulled out of single-mode or multi-mode fibers as required. For this purpose, the ends of two or more connecting fibers 10 , 11 are prepared in a known manner, the glass jacket enclosing the fiber core being etched off when using multimode fibers. The prepared fiber ends are then placed in a drawing device (not shown), so that they lie parallel or rotationally symmetrically at the point forming the later fusion area. They are then fixed in the pulling device without torsion, fused together at the point of contact under the action of heat, and the fiber arrangement is drawn out in the axial direction to form a taper. After cooling, the fiber arrangement in the taper zone is scratched and broken in such a way that approximately half a taper length is cut off and a perpendicular fracture surface is formed to the taper axis. In order to achieve a very small contact angle with favorable damping values, however, it is not scored and broken in the middle of the taper zone, but is preferably offset so that the side with the connecting fibers 10 , 11 has a longer piece of taper zone than the separated piece.

After the fracture surface has been produced in the area of the taper zone, the fiber arrangement is converted into a splicing device (not shown), fixed therein and the free ends of the connecting fibers 10 , 11 are each coupled to an optical detector. In addition, an incomplete plug with an empty capillary 7 is inserted into an axially displaceable receptacle of the splicing device in such a way that the holding part 4 of the plug is directed towards the breaking point of the taper 10 , 11 . Now a separately prepared optical fiber with a relatively long free of the plastic sheathing, bare, in the front end area possibly etched glass fiber 5 is threaded from the plug side through the capillary 7 of the connector pin 2 , behind the free end of the holding part 4 on the broken surface of the taper aligned, fixed in this position and the rear end of the optical waveguide coupled to a light source and the taper spliced with the glass fiber 5 . Corresponding measuring devices are observed with regard to the reduction of the damping and the splicing process is ended when an optimally low value is reached. The splice is then secured by encapsulating it in a plastic dispersion.

At a short distance between the splice and the back of the connector pin 2 , the glass fiber 5 , which now forms the extended base branch of the coupler 6, is given a thin adhesive wetting which, for. B. also consists of epoxy adhesive. Then the plug part is pushed so far over the glass fiber 5 wetted with adhesive until it is completely absorbed by the capillary 7 of the plug pin 2 , the splice point of the coupler 6 is close to the rear of the plug pin 2 and the beginning of the outer sheath 12 of both connecting fibers 10 , 11 lies within the holding part 4 . The coupler 6 is now fastened in the holding part 4 in the manner already described with a small portion of adhesive. This attachment and the fixing of the glass fiber S in the capillary 7 is done by applying heat and curing the adhesive, for example with hot air.

Once the adhesive has hardened, the couplings of the light source and detectors are released and the connector arrangement is removed from the splicing device. Then the holding part 4 is filled with the potting compound consisting, for example, of silicone gel, which is introduced through the longitudinal slot of the tube and protects the coupler 6 against vibration and environmental influences, among other things. Now the shrink tube is attached. Finally, the fiber protrusion is cut off on the end face of the plug pin 2 , the end face of the glass fiber 5 is ground and polished with that of the plug pin 2 .

Claims (11)

1. Plug with integrated optical coupler, characterized in that a base branch (glass fiber 5 ) of the coupler ( 6 ) is directed to the front side and at least two further fiber branches to the rear of the plug ( 1 ). 2. Plug according to claim 1, characterized by a plug pin ( 2 ) with a central capillary ( 7 ) and a glass fiber ( 5 ) fixed therein and by a flange ( 3 ) provided at the rear end of the plug pin ( 2 ) and by a behind the plug pin ( 2 ) arranged holding part ( 4 ) to which the coupler ( 6 ) having the connecting fibers ( 10 , 11 ) is attached and the base branch of which is spliced to the glass fiber ( 5 ). 3. Plug according to claim 2, characterized in that the plug pin ( 2 ) and holding part ( 4 ) are fastened to one another by means of a socket ( 8 ) having a flange ( 3 ). 4. Plug according to claim 2, characterized in that the coupler ( 6 ) at the rear end of the bare fiber branches together with the outer coverings ( 12 ) of the connecting fibers ( 10 , 11 ) is fixed with adhesive on the holding part ( 4 ). 5. Plug according to claim 2, characterized in that the holding part ( 4 ) consists of a tube having a longitudinal slot, which is filled with potting compound. 6. Plug according to claim 2, characterized in that the plug pin ( 2 ) made of ceramic and the holding part ( 4 ) are made of Kovar. 7. Plug according to claim 2, characterized in that on the holding part ( 4 ) one of the connecting fibers ( 10 , 11 ) with an enclosing shrink tube is attached. 8. Process for producing a plug with an integrated optical coupler, characterized by the use of the following process steps:

• a) making a plug ( 2 ) containing a capillary ( 7 ) with a rear holding part ( 4 );
• b) producing the optical coupler ( 6 ) by fusing at least two possibly etched connection fibers ( 10 , 11 ) and then pulling them out and, after cooling, separating about half the length of the resulting taper;
• c) threading through the capillary ( 7 ) a bare glass fiber ( 5 ) which may have been etched away in the front area until the fiber end protrudes sufficiently far beyond the end of the holding part and splicing the fiber end with the end face of the taper;
• d) encapsulating the coupler ( 6 ) and any remaining etched-off areas of the glass fibers ( 5 , 10 , 11 ) in a plastic dispersion;
• e) wetting the glass fiber ( 5 ) between the coupler ( 6 ) and connector pin ( 2 ) with a curable adhesive;
• f) moving the plug part over the wetted glass fiber ( 5 ) until it is received by the capillary ( 7 ) and the coupler ( 6 ) close to the plug end and the outer sheath ( 12 ) of the connecting fibers ( 10 , 11 ) within the holding part ( 4 ) lie;
• g) attaching the connecting fibers ( 10 , 11 ) to the end of the holding part ( 4 ) with curable adhesive and fixing the glass fiber ( 5 ) in the connector pin ( 2 ) by applying heat and curing the adhesive points;
• h) cutting off the fiber overhang on the end face of the connector pin ( 2 ) and surface grinding and polishing of the glass fiber ( 5 ).

9. The method according to claim 8, characterized in that the separation of the taper is carried out in such a way that the side with the connecting fibers ( 10 , 11 ) has a longer piece of taper zone than the separated. 10. The method according to claim 8, characterized in that the holding part ( 4 ) is filled with sealing compound after the adhesive joints of the plug ( 1 ) have hardened. 11. The method according to claim 10, characterized in that after the curing of the adhesive points on the holding part ( 4 ), the connecting fibers ( 10 , 11 ) with surrounding shrink tube is pushed on.