DE4414862A1 - Optical fibre connector with monitoring device - Google Patents

Abstract

The connector (31) contains an optical transmitter or receiver device (17,7) coupled to the receiver or transmitter (12,2). The optical component of the transmitter or receiver device (17,7) is located at the optical conductor (4). The receiver device (7) is located at the point of coupling between the transmitter (2) and the optical conductor (4). In the event of faults or an inadequate connection of the optical fibre this detects stray optical energy from the transmitter (2). An equivalent transmitter device (17) is fitted with the receiver (12).

Description

With copper-bound transmission links the flow of information between sender and receiver a closed circuit with a forward and return conductor. A faulty installation, for example a broken wire Short circuit, reverse polarity or external influences, for example electromagnetic interference fields, act directly on the current flow in the closed circuit and make therefore immediately noticeable at the transmitter and at the receiver. An installation test can therefore simply be carried out by a Checking the current flow and comparison with one Reference value at every point in the circuit, that is in particular at the sender and the receiver.

With fiber-bound transmission links, i.e. with an information transmission via optical fibers such a closed "circuit" does not exist, so that also simple monitoring as with copper-bound Transmission systems is not possible. It will be a additional transmission channel required, the for example, reports to the broadcaster that the radiated light wave energy arrives at the receiver. Because of the additional transmission channel, this is one Monitoring complex.  

A weak point in everyone Message transmission systems are plug connections in Trains and especially when connecting Lines at transmitting and receiving devices. That applies in to a high degree also for the plug connections of Optical fibers. Because, as explained above, in contrast to copper-bound transmission links for fiber optic Transmission lines no easy monitoring on the A closed circuit is possible, the invention has for its object a monitoring of fiber optic connectors to create the is easy to implement and versatile options opened. The solution to the problem is in claim 1 specified.

By coupling the transmit or Receiving elements with an optical counterpart can be easily determine whether the optical fiber is connected or not or the connector installed incorrectly or incompletely. About that further tests and evaluations are possible.

Developments of the invention are the subject of Subclaims. It can be provided that the transmission or Receiving element in the area of the coupling point of the Optical fiber with its optical counterpart, for example the coupling housing of the plug connection, is arranged. With a plug connection between one optical transmitter and an optical fiber becomes a Receiving element at the optical transmitter near the coupling point arranged with the optical fiber, such that the Receiving element in the event of missing or incomplete coupling part of the optical energy with the optical fiber of the transmitter is detected. With a plug connection between an optical receiver and an optical fiber a transmission element in the optical receiver near the  Coupling point arranged such that the receiving element at missing or incomplete coupling with the Part of the optical energy of the optical fiber Sending element records.

For the arrangement of the transmit and / or Receiving elements on the plug device exist in many ways Options. However, the element is expediently in a arranged transverse to the insertion direction of the Coupling housing arranged that the fiber optic Connector.

Exemplary embodiments of the Invention described in connection with the drawings. It demonstrate:

Figures 1 and 2 schematically an optical fiber connector between a message source or a message sink and an optical fiber according to an embodiment of the invention.

FIGS. 3 and 4 schematically shows a fiber optic connector between a message source and a light waveguide, as a further embodiment of the invention;

Fig. 5 shows schematically a cross section through a connector according to the invention.

In Fig. 1, an optical fiber connector according to the invention is shown schematically. The connector has a coupling housing 1 , which is connected to a message source 2 as a transmitter, shown schematically as a laser diode. An optical waveguide plug 3 , which contains an optical fiber 4 as an optical waveguide, can be inserted into the coupling housing 1 in the direction of arrow 5 in order to produce the plug connection. A receiving element 7 , shown schematically as a light-sensitive diode, is arranged below an opening 6 in the coupling housing 1 .

In the position shown, in which the plug 3 has not yet been (fully) inserted, the receiving element 7 can absorb part of the optical energy emitted by the laser diode of the message source 2 . An evaluation electronics (not shown) connected downstream of the receiving element 7 responds to the irradiated optical energy or information and provides an indication that the plug connection is not or not completely or not properly executed. After the plug 3 has been inserted into the coupling housing 1 , the opening 6 is covered, so that the receiving element no longer receives optical energy and consequently the correct establishment of the plug connection can be displayed.

Fig. 2 corresponds in substantial parts to the embodiment of Fig. 1. The clutch housing 1 is here, however, connected to a message sink 12 as a receiver, shown as a light-sensitive diode. A transmission element 17 is arranged below the opening 6 in the clutch housing 1 . In reverse of the situation in the embodiment of FIG. 1, the transmitting element 17 , which is for example a laser diode, can act on the message sink 12 through the opening 6 , which indicates that the plug connection has not yet been made or has not been made completely or not properly.

The exemplary embodiment according to FIGS. 3 and 4 corresponds to the exemplary embodiment according to FIG. 1. Here, however, an opening 16 is provided above the receiving element 7 , which is not covered by a corresponding recess 13 after the plug 3 has been inserted. However, if the plug 3 is inserted offset by 180 ° according to FIG. 4, the opening 16 is covered similarly to the case of the exemplary embodiment according to FIG. 1.

This is intended to show schematically that at Coding device according to the invention possible is either a recognition of the type of each Allows plug or its insertion position. This also allows different Mark distance ranges, or there can be one Adjustment of the transmission power or receiver sensitivity can be achieved when the respective connector are coded accordingly.

Fig. 5 shows schematically the structure of a connector according to the invention. A housing 20 , which contains a message source 2 or a message sink 12 with control electronics 21 connected downstream, is followed by a coupling housing 31 with a screw thread 32 . The associated optical fiber connector with the optical fiber 4 leading away, which is protected and held by sleeves 5 , can be screwed onto the thread 32 with the fiber 4 inserted. This establishes the connection with the message source 2 or the message sink 12 .

The clutch housing 31 has a transverse bore 34 , into which a transmitting element 17 or receiving element 7 with downstream evaluation electronics 22 is inserted. As shown in the exemplary embodiments according to FIGS. 1 to 4, there is an optical coupling between the message source 2 or the message sink 12 on the one hand and the receiving element 7 or the transmitting element 17 , as long as the plug 33 has not yet or not completely on the coupling housing 31 is screwed on. However, if the plug connection is made as shown in Fig. 5, the receiving or transmitting element 7 , 17 is covered by the optical fiber with its envelopes, so that the optical coupling is interrupted.

Claims (6)

1. Optical fiber connector with monitoring device, characterized in that the connector ( 1 , 31 ) is equipped with an optical transmitting and / or receiving element ( 7 , 17 ) which with the receiver and / or transmitter connected to the connector ( 2 , 12 ) is coupled and arranged so that it is optically covered when the plug connection is made. 2. Connector according to claim 1, characterized in that the transmitting or receiving element ( 7 , 17 ) is arranged in the region of the coupling point of the optical waveguide ( 4 ) with its optical counterpart. 3. Connector according to claim 1 or 2, characterized in that the cover is dependent on a coding of the optical fiber connector ( 3 ). 4. Connector according to one of claims 1 to 3, characterized in that with a plug connection between an optical transmitter ( 2 ) and an optical waveguide ( 4 ), a receiving element ( 7 ) is arranged at the optical transmitter near the coupling point with the optical waveguide, such that that the receiving element ( 7 ) detects part of the optical energy of the transmitter ( 2 ) in the absence or incomplete coupling to the optical waveguide. 5. Connector according to one of claims 1 to 4, characterized in that with a plug connection between an optical receiver ( 12 ) and an optical waveguide ( 4 ), a transmitting element ( 17 ) is arranged near the coupling point with the optical waveguide in the optical receiver, such that that the receiver ( 12 ) absorbs part of the optical energy of the transmitting element ( 17 ) in the absence or incomplete coupling to the optical fiber connector ( 3 ). 6. Connector according to one of claims 1 to 5, characterized in that the transmitting and / or receiving element ( 7 , 17 ) is arranged in a transverse to the insertion direction bore ( 34 ) of the coupling housing ( 31 ) which the fiber optic connector ( 33 ) records.