DE3900021A1 - Optical waveguide connector - Google Patents

Abstract

The invention relates to an optical waveguide connector which consists of a plug part and a socket part in which optical waveguide cables in monomode (single mode) or multimode with plug pins prepared on the cable ends are built in in a strain-relieved manner and form in conjunction with the coupling element in the socket part a device connection unit. The socket part (1) has a plug trough (11) and an operating trough (10) which are constructed as angularly deviating surfaces (11', 10') with respect to the front panel (3). The optical waveguide connector, constructed according to the invention as device connection unit, can be built in in or on peripheral devices or various channels (surface-mounted or flush-mounted as well as bottom). <IMAGE>

Description

The invention relates to an optical fiber plug Connection according to the preamble of claim 1.

Fiber optic connectors are so far only as Connectors with one or more light waves ladder veins have been designed and implemented for those Usual screw or bayonet locks for use come. Multiple plug connections based on elec electrical sockets / plug combinations such as devices Connection units with the on fiber optic devices requirements such as preci sion of the coupling elements and the plug-in conditions for Single or multi-mode operation, as well as the fiber optic Cable routing and strain relief elements are so far not known.

The object of the invention is therefore a light wave to create a conductor connector, especially as Optical fiber device connection unit for peripherals devices can be used. This fiber optic Device connection unit should be designed so that the necessary precision, as well as all requirements to the Housing and treatment of the supplied light waves conductor cables are taken into account.

This task is characterized by the wording of the Part of claim 1 solved.

The fact that the can part is a plug-in and operating recess has that as angularly different surfaces for  Level of the front panel are formed, the result great advantage that all technical in the can part Requirements are met and the housing unit despite which is not too big. With the plug part is in turn the direction of insertion and the inserted connector part very much Executed flat to the device and against accidental attack fende transverse forces protected so that after plugging in a intimate, flat-fitting connection is created that for the Optical fiber cable is designed with little bending.

Advantageous developments of the invention are in the characteristic parts of the subclaims.

The fact that the connector according to the invention for Plug out two or more optical fibers can be formed, results in the smallest dimensions a large area of application.

The fact that when plugging the connector part into the cans Some measures for leading positive guidance are provided are the mating conditions on the coupling element positively influenced.

The fact that the connector except optical fibers also has electrical contacting can in one Plug connection also the necessary connections from Earth and control lines can be implemented. Advantageous is still, the parts for positive control as electrical train conductive, which in turn saves space.

The fact that both for the can and for Dust protection caps are available at pulled connector the openings over which the Connection is made when plugged in, closed, with which the coupling elements and plug pins with their sensitive fiber end faces against damage and Pollution are largely protected. To plug in  the caps on the can part are pushed back and on Plug part captive in a recess below brought.

The fact that when the plug is inserted into the socket part the connector is automatically locked part after a perfect plug in the end position held. If you want to break this connection, it happens this via the release button in the operating recess.

In that the necessary resilient overstroke at least is arranged in the can part, the end faces of the Optical fibers safely and with a defined pressure pressed together.

Because the inevitably at the on-site assembly falling excess lengths of the optical fibers in the socket part with compliance with the permissible bending radii are the minimum bending radii for the light waves ladder adhered to and a supply for assembly the optical fiber is housed in the box section. The integrated channels in the connector part also provide the Minimum bending radii for the fiber optic cables safe.

Due to the arrangement of the integrated channels in the connector In part, different cable designs can be found in An dependence on the installation position of the device connection unit will be realized.

Through the training of the push-in trough and the operating trough at an angle of 45 ° to the front plate of the box part is a particularly cheap and space-saving version been realized. Plug and operating trough form one right angles to each other.

The fact that the can part as a wall, up or down cleaning part can be carried out, there are many  and installation options, especially in ducts or in Floor groups.

The fact that the bottom part on square brackets points, strain relief elements can easily be used will.

The fact that at the bottom of the can part an information note is housed, the service friendliness for assembling the connector pins and installing in the coupling element facilitates.

The fact that the can part with the front panel as waterproof design is formed, the one Possibility of the connector further expanded.

Further advantages can be found in the description will.

The invention is illustrated in the drawings presented embodiments explained in more detail. In the Shows drawings

Fig. 1 seen a connector according to the invention from the side with schematically and in phantom Pictured internal structure,

Fig. 2 is a socket part according to Fig. 1 in top view of the male and control recess,

Fig. 3 is a male part of FIG. 1 drawn partly in section, in perspective of the bottom,

Fig. 4 is a connector part of Fig. 1, drawn partly in section, in side view,

Fig. 5 is a connector part of Fig. 1, in view of the top,

Fig. 6 is a socket part according to Fig. 1, in Perspecti vischer view and view of the plug-in recess,

Fig. 7 is a socket part according to Fig. 1, in Perspecti vischer illustration and view of the control recess,

Fig. 8 shows a connector according to Fig. 1, in a perspective view and view of the upper part of the plug part in the inserted state in the socket part.

In Fig. 1, the socket part 1 of the connector according to the invention is seen from the side. The interior structure is shown schematically and in dashed lines. In the socket part 1 , the plug part 2 is inserted ge records. Only the parts with which the plug part 2 is inserted into the socket part 1 have been omitted from the schematic illustration. They are shown in FIGS. 3 to 5 and are also described in more detail there. The box part 1 consists of a front plate 3 and a housing unit 4 , which are separated by the "A construction line" 5 so that in a built-in state only the front plate 3 and the training integrated with it, such as operating trough 10 and plug-in trough 11 can be seen. The housing unit 4 below the front panel 3 is sunk in the device or the channel. At the bottom of the housing unit 4 there is an opening on the left side, through which an optical fiber cable 6 is guided and elements are secured in square brackets 15 by strain relief. In the adjacent space of the housing unit 4 after the strain relief elements, the optical fiber cables are folded in large loops to over 7 lengths, so that the minimum bending radii for the optical fibers 6 are observed. The connector pin attached to the free fiber optic fiber end is mounted in the coupling element 8 in such a way that the two fiber end faces meet without any significant losses during the plugging process. The precise alignment takes place, as will be described later, by a corresponding leading positive guidance. The overpressure 9 contained in the coupling element 8 provides the necessary pressure of the two fiber ends against one another. At the bottom of the right part of the housing unit 4 there is a brochure 25 which serves as an information note on the assembly of the connector pins 17 and the installation of the same in the coupling element 8 . The front plate 3 is a level that closes the housing unit 4 , into which the operating recess 10 and the plug recess 11 , which differ in angle from the plane of the front plate 3 , are integrated. The operating recess 10 advantageously forms an angle of approximately 45 ° with the front plate 3 . The trough 11 is also arranged at an angle of 45 ° to the front panel 3 . The operating recess 10 thus forms an insertion angle of approximately 90 ° to the insertion recess 11 . On the front plate 3 on both sides of the recess of the trough 11 from the front plate 3 ribs 16 are arranged, which protects the plug part 2 against unintentional pulling by attacking unwanted transverse forces. Further ribs are attached to the outer surface of the plug part 2 , which allow a gripping grip on the plug part 2 . The optical waveguides 6 are assigned 2 strain relief elements before being led out of the plug part. The front of the plug part 2 covers the surface 11 'of the plug trough 11 completely when plugged in. The dust cap 13 ( Fig. 2), which was in the pulled state of the plug part 2 in front of the plug opening 23 ( Fig. 2), is pushed back in the inserted state of the plug part 2 into the surface 10 'of the operating recess 10 .

In Fig. 2, the can part 1 is shown in view of the plug 11 and operating trough 10 . The parts of the housing unit 4 which are not visible are shown in dashed lines, as are the square brackets 15 which serve to accommodate the strain relief elements. Be dienmulde 10 in the front panel 3 , as already stated above, the retracted dust protection slide 13 , which actually comes to lie in the pulled state of the plug part 2 , as shown, through the openings 23 ', 18' and 19 ' . In the operating recess 10 , the elongated button 14 is also arranged, which is used for unlocking (by pressing the button) of an automatically locked plug part 2 when plugged.

On both sides of the trough 11 plate 3 ribs 16 are arranged on the front, which, as already described ben, protects the connector part 2 against unintentional pulling by attacking transverse forces. The front panel 3 is connected to the housing unit 4 by screws or by other means.

In Fig. 3, a connector part 2 is shown partially cut, shown from the bottom. The opening of the receptacle 23 for the plug pins 17 is covered with a dust protection cap 12 in the pulled state of the plug part 2 . Before the plugging process, the dust cap 12 is removed from its protective position and placed in the space 27 in the underside of the plug part 2 . By a band 26 which is fixed with its free end on the plug part 2 and at the other end to the dust cap 12, the dust cap 12 captive on the connector part 2 is held. On both sides of the receptacle 23 for the plug pins 17 there are the plug pins 18 and 19 with which the leading guidance for the plug part 2 is achieved when plugged into the socket part 1 . The connector pins 18 and 19 can also consist of a highly conductive material and at the same time be used as contact pins via the earth or control lines are switched electrically during the plugging process.

In Fig. 4 the connector part 2 is shown partially in section in side view. The dust protection cap 12 is connected to the band 26 and can be placed undetachably in the space 27 below the plug part 2 before the plugging process. The ribs 28 serve, as he already thinks, for a better grip on the plug part 2 when plugging into the socket part 1 or when pulling out of it after unlocking by pressing the button 14 within the operating recess 10 of the socket part 1 .

The automatic locking when plugged in takes place by latching a part inside the coupling element or the socket part 1 into the locking notch 24 . The se locking can be lifted up against the pressure of a spring via the release button 14 , as already mentioned. The notch 24 is located at the front end of one or both of the pins 18 and / or 19 , which are used for pre-guiding.

In Fig. 5, a connector part 2 is shown with a view of the upper side. The innards of the connector part 2 are shown in dashed lines. In the dash-dotted lines 2 channels 20, 21 and 22 are integrated in the plug part, which serve to guide the optical fiber cables 6 within the housing of the plug part 2 . The channels 20, 21 and 22 are designed so that the minimum bending radii are observed for the optical fibers. In addition, the channels 20, 21 and 22 are guided within the connector part 2 so that different cables lead out according to the respective installation position of the optical fiber connector or the device connection unit can be realized.

Fig. 6 shows the socket part 1 in a perspective view and in view of the plug-in trough 11. The dust protection slide 13 is with the plug part 2 in front of the openings 18 ' and 23' . As can be clearly seen from the illustration, there are the ribs 16 on both sides of the trough 11 , the function of which is to protect the plug part 2 when it is plugged in. The opening 19 ' , which is also within the ribs 16 in the trough 11 , is also covered by the dust cover 13 in this position, but is not seen in the Dar position.

In Fig. 7 the can part 1 is shown in perspective in view of the operating trough 10 . In the control panel 10 there is the dust protection slide 13 and the unlock button 14 . On both sides of the trough 11 , the ribs 16 rise from the plane of the front plate 3 .

In Fig. 8 is a connector according to the invention in perspective and in view of the upper part of the connector part 2 in the inserted state in the socket part 1 Darge provides. In this illustration, it can be seen particularly clearly that the ribs 16 on both sides of the trough 11 can protect the inserted plug part 2 against the unwanted attack of lateral forces. Furthermore, seen from the illustrations in FIGS. 6, 7 and 8 clearly how flat the plug builds up over the outside of a device or a channel from which the Steckver binding only with the front panel 3 and looking out the male part 2.

Claims (23)

1. Optical waveguide plug connection, consisting of a plug and a socket part, in which optical waveguide cables as single-mode or multimode versions are installed with strain relief installed at the ends of the cables and form a device connection unit in connection with the coupling element in the socket part, characterized in that that the can part ( 1 ) has a plug-in ( 11 ) and operating recess ( 10 ) which are designed as angularly different surfaces ( 11 ', 10' ) to the level of the front plate ( 3 ). 2. Optical fiber connector according to claim 1, characterized in that the connector for plugging two or more optical fibers ( 6 ) is formed. 3. Optical fiber connector according to one of claims 1 or 2, characterized in that when plugging the plug part ( 2 ) into the socket part ( 1 ) measures for leading positive guidance ( 18, 19, 18 ', 19' ) of the plug part ( 2 ) are provided. 4. Fiber optic connector according to one of claims 1 to 3, characterized in that the connector in addition to optical fiber ( 6 ) also has elec trical contacts that serve to connect earth or control lines. 5. Fiber optic connector according to one of claims 3 or 4, characterized in that the pre-lined positive guidance are designed as electrically conductive contacts ( 18, 19 ). 6. Fiber optic connector according to one of claims 1 to 5, characterized in that the socket part ( 1 ) has an integrated dust protection slide ( 13 ) for protecting the plug opening ( 23 ' ) when the connector is pulled. 7. Optical fiber connector according to one of claims 1 to 5, characterized in that the dust protection ( 12 ) for the plug part ( 2 ) with separate plug connection protects the opening in the receptacle ( 23 ) for the plug pins ( 17 ) and before the plugging process is removable within the plug part ( 2 ) in a room ( 27 ) captive deposit. 8. Optical fiber connector according to one of claims 1 to 5 and 7, characterized in that an automatic locking ( 24 ) of the plug part ( 2 ) takes place when plugged into the socket part ( 1 ). 9. Fiber optic connector according to one of claims 1 to 8, characterized in that the resilient overstroke ( 9 ) required for the secure pressing of the two fiber end faces of the light waveguide ( 6 ) is arranged at least in the socket part ( 1 ). 10. Optical fiber connector according to one of claims 1 to 9, characterized in that the excess lengths ( 7 ) of the optical fiber cable ( 6 ) in the socket part ( 1 ) are housed. 11. Optical fiber connector according to one of claims 1 to 10, characterized in that the plug part ( 2 ) and the socket part ( 1 ) integrated channels ( 20, 21, 22 ) for cable routing and to ensure minimum bending radii for the optical fibers ( 6 ) contain. 12. Fiber optic connector according to one of claims 1 to 11, characterized in that the integrated channels ( 20, 21, 22 ) in the plug part ( 2 ) are arranged so that different cable designs can be realized according to the respective installation position of the device closure. 13. Optical fiber connector according to one of claims 1 to 12, characterized in that the surface ( 11 ' ), which forms the plug-in level in the trough ( 11 ), is arranged approximately at an angle of 45 ° to the plane of the front plate ( 3 ) is. 14. Fiber optic connector according to one of claims 1 to 13, characterized in that the surface ( 10 ' ), which forms the operating level in the operating recess ( 10 ), arranged approximately at an angle of 45 ° to the plane of the front plate ( 3 ) is. 15. Fiber optic connector according to one of claims 1 to 14, characterized in that the surface ( 10 ' ) of the operating recess ( 10 ) and the surface ( 11' ) of the insertion recess ( 11 ) form approximately a right angle to each other. 16. Optical fiber plug connection according to one of claims 1 to 15, characterized in that in the operating recess ( 10 ) the unlocking button ( 14 ) and parts of the dust protection slide ( 13 ) are arranged when the plug connection is inserted. 17. Optical waveguide plug connection according to one of claims 1 to 16, characterized in that at least the socket part ( 1 ) in the design of a seated on a device part or a recessed in a device part housing unit ( 4 ) is formed. 18. Optical fiber connector according to one of claims 1 to 17, characterized in that on the socket part ( 1 ) the front plate ( 3 ) in the plug-in area is provided with ribs ( 16 ) which the plug part ( 2 ) in the inserted state against unintentional pulling of the Protects connector part ( 2 ) by attacking unwanted transverse forces. 19. Fiber optic connector according to one of claims 1 to 18, characterized in that at the bottom or at the bottom of the socket part ( 1 ) square holding stanchions ( 15 ) are provided which serve to accommodate strain relief elements. 20. Optical fiber connector according to one of claims 1 to 19, characterized in that the coupling element ( 8 ) in the front plate ( 3 ) of the socket part ( 1 ) is integrated. 21. Optical fiber connector according to one of claims 1 to 20, characterized in that an information note (brochure) for the assembly of the plug pins ( 17 ) and installation in the coupling element ( 8 ) is stored on the bottom of the socket part ( 1 ). 22. Fiber optic connector according to one of claims 1 to 21, characterized in that the socket part ( 1 ) with front plate ( 3 ) is suitable for channels (such as according to DIN 49 073), which as wall, on- or flush-mounted ducts, and can be installed in floor groups. 23. Optical fiber connector according to one of the preceding claims, characterized in that the socket part ( 1 ) with the front plate ( 3 ) is designed as a watertight guide.