DE10041438A1 - Arrangement for coupling a plurality of first optical waveguide fibers to a plurality of second optical waveguide fibers - Google Patents

Abstract

An arrangement for the coupling of a number of first light waveguide fibres with a number of second light waveguide fibres, comprises a number of first light waveguide connectors for optically coupling the first light waveguide fibres and a number of second light waveguide connectors for optically coupling the second light waveguide fibres. Each of the first light waveguide connectors may be optically coupled to one of the second light waveguide connectors by means of a coupling light waveguide fibre. Furthermore, a coupling recognition unit is provided, which is arranged such that it can be detected if an optical coupling of a first light waveguide connector to a second light waveguide connector, by means of a coupling light waveguide fibre exists, by means of an additional channel to the optical channel produced from one of the light waveguides, by means of the coupling light waveguide fibre.

Description

The invention relates to an arrangement for coupling a A plurality of first optical waveguide fibers with a plurality second fiber optic fibers.

With a large number of optically coupled to each other a clutch assembly arriving first Optical fibers with the coupling arrangement outgoing second optical fiber often occurs Problem on, a clear and relatively robust Possibility of coupling the individual fiber optic Creating fibers. Furthermore, it is often desirable automates the information to determine whether a clutch actually switched between two optical fibers is.

In this context, it is known to be a Coupling arrangement to be used with a plurality of first Optical fiber connections for optically coupling the first optical fiber and with a plurality second fiber optic connections for optical coupling the second optical fiber. One of each first fiber optic connections are made with one of the second fiber optic connections via one Coupling optical fiber coupled.

The coupling arrangement is also used as a patch panel or patch panel.

The coupling optical fiber is also referred to below Patch connection or patch cord called.  

According to the known arrangement, the coupling Fiber optic cables controlled remotely via robot arms with the incoming first fiber optic fibers and the outgoing second fiber optic fibers connected.

Furthermore, there is a coupling arrangement with optical switches known.

Furthermore, a clutch arrangement is known in which the over the optical fibers in an optical channel transmitted information is used to determine whether a transmission channel switched, d. H. whether two Fiber optic fibers mechanically coupled and are optically coupled with each other. In this Coupling arrangement is an optical signal immediately the optical channel for the transmission of user information decoupled. This leads to an undesirable relatively high Attenuation of the optical signal to be transmitted via the optical channel. Furthermore, the decoupling of a signal from the optical channel by the optical fiber is provided, very complex and expensive.

The coupling arrangements known in glass fiber technology have the particular disadvantage that they are very expensive are. In this context, it should also be pointed out that only rarely, especially with optical fibers Change in the coupling between the individual Optical fiber is required. Under Taking this aspect into account are therefore the known ones Arrangements for use in fiber optics oversized.

There is therefore a considerable need for one Coupling arrangement, which a fitter of the coupling arrangement, which the respective fiber optic fibers manually couples together, support for quick and safe Detection and for fast and safe switching or  Provides coupling of the individual connections. In particular, it is desirable to have errors when disconnecting or Connecting the transmission links, d. H. of clutches between two optical fibers.

The invention is therefore based on the problem of a Arrangement for coupling a plurality of the first Optical fiber with a plurality of second Specify fiber optic fibers that is inexpensive and nevertheless the coupling of fiber optic fibers quickly and error-proof enabled.

The problem is solved by an arrangement for coupling one A plurality of first optical waveguide fibers with a plurality second fiber optic fibers with the features according to independent claim solved.

An arrangement for coupling a plurality of the first Optical fiber with a plurality of second Optical waveguide fibers have a plurality of the first Optical fiber connections for optically coupling the first optical fiber and a plurality of second Optical fiber connections for optically coupling the second fiber optic fibers. One each Optical fiber connection of the first optical fiber Connections using a coupling optical fiber is the second with one fiber optic connection Optical fiber connections can be optically coupled. Farther the arrangement has a coupling detection unit. The Coupling detection unit is set up in such a way that by means of one to one of the optical fibers provided optical channel additional channel that is provided by the coupling optical fiber, can be detected whether an optical coupling of a first Optical fiber connection via a coupling Optical fiber with a second optical fiber Connection exists.  

The invention can clearly be seen in that by means of the arrangement according to the invention without decoupling a signal from the optical signal, d. H. the optical Channel, which optical signal from the respective incoming or outgoing fiber optic fibers is carried out Providing another channel, preferably another optical channel or an electrical channel is whether there are two fiber optic connections with each other via a coupling optical fiber are coupled or not.

For example, another can be provided optical signal in a frequency range in the Optical fiber of the coupling optical fiber to couple in or out, which is different from that Frequency range differs in which the optical signal from the incoming or outgoing fiber optic fibers becomes. In this case, the coupling optical waveguide as well as the incoming or outgoing fiber optic Fibers one or more optical fibers.

Alternatively, one can in the coupling optical waveguide additional optical fiber can be provided. About the additional fiber optic fiber will be another optical signal fed by means of an optical transmitter, each preferably a first optical waveguide Connection is assigned. Preferably one of each assigned to a second optical fiber connection optical receiver is one of an optical transmitter optical signal sent when the two respective fiber optic connections via the coupling Optical fibers are interconnected. In this case is thus over another optical fiber in the Coupling fiber optic coupling information transmitted, by means of the indirect, d. H. without in the optical Signal circuit between the incoming and outgoing  Intervene fiber optic fibers, it can be determined whether a connection between two fiber optic connections is switched.

According to a further embodiment of the invention Coupling optical fiber an additional electrical Cable, preferably made of copper, is provided.

Via the additional electrical line in the coupling An electrical signal is fed into the optical fiber by means of a voltage or current source, each preferably a first optical fiber connection is assigned and with this via a in the Optical fiber connection provided electrical contact is coupled. About one each preferably in one second optical fiber connector arranged another electrical contact is made by the voltage source or Receive electrical signal provided by the power source, if the two respective fiber optic connections over the coupling optical fibers are interconnected. In this case, an additional electrical Line in the coupling optical fiber Coupling information transmitted by means of the can be indirectly determined whether between two Fiber optic connections a connection is switched.

In this context, indirect determination is too understand that from this additional information further Channel (optical or electrical) is inferred that too the corresponding optical coupling is present or not.

The invention makes it possible for the first time in a simple manner and inexpensive way to determine whether fiber optic Fibers with a patch panel and one over the other Patchcord are coupled without being in the actual optical signal circuit must be intervened.  

Thus, in the solution according to the invention, this is also achieved via incoming or outgoing fiber optic fibers transmitting optical signal not attenuated.

According to an embodiment of the invention, a plurality of Coupling detection units are provided, one each Coupling detection unit a first optical fiber Connection and / or a second fiber optic connection assigned.

Through this training is a simple and therefore inexpensive assignment of the recorded couplings to the respective fiber optic connections.

According to a further embodiment of the invention, a optical coupler on at least part of the first Fiber optic connections for coupling another optical signal in the optical channel of the Optical fiber fibers are provided. Furthermore, an optical Decouplers on at least part of the second Optical fiber connections for decoupling the optical Signals from the optical channel of the optical fiber intended.

This configuration makes it simple and therefore cost-effective implementation of an additional optical signal circuit to recognize the corresponding specified optical couplings, not even one additional electrical wire or an additional Optical fiber in the coupling optical fiber is required.

Furthermore, for at least part of the first Optical fiber connections and for at least part of the second optical fiber connections each an electrical Connection should be provided to which one in the coupling Optical fiber fiber additionally provided electrical  Can electrically couple line if the coupling Optical fiber with the corresponding Fiber optic connection is coupled,

According to a further embodiment of the invention central processing unit provided, preferably a Microprocessor, with which processing unit all Couplings between a first fiber optic connection and a second fiber optic connection via each a coupling optical fiber is detected and can be saved.

The central processing unit can also which optical fiber connections are specified to each other via a coupling optical fiber are pairing.

This way, even with complex Coupling structures of a large number coupled together Fiber optic fibers a reliable automated Acquisition, processing and storage of the optical Realize couplings. It can also be central in this way an overview of the respective already switched Optical fiber connections are provided.

Furthermore, an optical display unit for at least part of the first fiber optic connections and for at least part of the second optical fiber connections be provided which optical display unit with the central processing unit are coupled such that an optical display unit is activated when the respective fiber optic connection with a Optical fiber is coupled.

The optical display units can, for example by means of different colors, from the central Processing unit can be controlled to give the fitter a  Assistance with the interconnection of the coupling To give fiber optic by the optical Display units of those to be interconnected Optical fiber connections for lighting can be controlled.

This way it can be inexpensive and very clear for a fitter will be shown which clutches already have been switched and so which clutches still are actually to be switched by the fitter.

According to a further embodiment of the invention, the optical display units or other optical Display units may also be provided to the fitter indicate which first fiber optic connections with which second fiber optic connections to couple are.

In this way, the assembly is even for the fitter clearer and thus easier and more robust designed.

Furthermore, it can alternatively be provided that the first Fiber optic connections each have a button as a switch and the second fiber optic connections one each optical display unit is assigned so that when pressed a button in case the corresponding first Optical fiber connection via a coupling Optical fiber with a second optical fiber Connection is coupled, the corresponding, the respective second optical fiber connector associated optical Display unit is activated, so that a user on Pressing a button receives the light information about it with which second fiber optic connection each first optical fiber connector is coupled.  

The switch can be implemented as a button or as a open contact, where by touching a finger the electrical contact is formed and thus the switch is closed conductively. The key can also be used as One-contact button be designed.

Embodiments of the invention are in the figures are shown and are explained in more detail below.

Show it

FIG. 1 is a cross-sectional view of a coupling assembly having a coupling optical waveguide according to a first embodiment of the invention;

Figure 2 is a cross-sectional view of a coupling assembly having a coupling optical waveguide according to a second embodiment of the invention. and

Fig. 3 is a plan view of a clutch arrangement according to the first embodiment of the invention.

First embodiment

FIG. 3 shows an incoming optical waveguide cable 300 , via which a large number of optical signals with a large number of different center wavelengths λ ₁ , λ ₂ ,. , . Λ, _n as the total signal 301 an input coupled to the optical fiber cable 300 Wellenlängenmultiplexer- / wavelength demultiplexer 302, an AWG Wellenlängenmultiplexer- / wavelength demultiplexer (Arrayed Waveguide Grating- wavelength demultiplexer) may be fed 302 according to this embodiment.

In the AWG wavelength multiplexer / wavelength demultiplexer 302 , the total signal 301 is converted into the plurality of optical signals 303 with the center wavelengths λ ₁ , λ ₂ ,. , ., λ _n divided. Each optical signal 303 is fed to a first optical fiber 304 via a transponder 305 .

Each first optical waveguide fiber 304 is coupled to a first optical waveguide connection 306 of a coupling arrangement 313 , which will be explained in more detail below.

The coupling arrangement 313 also has a number of second optical waveguide connections 307 which corresponds to the number of first optical waveguide connections 306 .

A second optical fiber 308 can be coupled to a second optical fiber connector 307 .

A first optical fiber 306 coupled to a first optical fiber connector 304 can, as shown in FIG. 3, by means of a coupling optical fiber via a correspondingly selected second optical fiber connector 307 with a second optical fiber coupled to the respective second optical fiber connector 307 -Fiber 308 coupled and thus optically coupled.

The second optical waveguide fibers 308 are fed via a further transponder 309 to a further AWG wavelength multiplexer / wavelength demultiplexer 310 , in which the optical signals 303 are multiplexed correspondingly to form a further overall signal 311 . The overall signal 311 is fed to a further, outgoing optical fiber cable 312 .

Of course, the arrangement can also be reversed Signal flow direction are operated, in which case the Functionality of the AWG wavelength division multiplexer / Wavelength demultiplexer reversed accordingly is designed.

Fig. 1 shows a cross section through the coupling assembly 100. The coupling arrangement 100 has a front plate 101 with a first optical waveguide connection 102 accommodated in a bore, which is formed by an MT-RJ plug connector, generally a two-fiber plug for connecting a plurality of optical waveguide fibers 103 , 104 .

A first optical fiber 103 , which is coupled to the first optical connector 102 at a first connection part 105 , is an optical fiber arriving at the coupling arrangement 100 . An optical useful signal for the actual useful data transmission is transmitted via the first optical waveguide fiber 103 .

An additional optical signal is transmitted from an optical transmitter 107 , which is assigned to the first optical waveguide connection 102 , to the first optical waveguide via a second optical waveguide fiber 104 , which is coupled to the first optical waveguide connection 102 at a second connection part 106. Connection 102 led.

As shown in FIG. 1, the first optical waveguide connection 102 is further coupled on its other connection side to a coupling optical waveguide 108 .

The coupling optical waveguide 108 has a first coupling optical waveguide fiber 109 and a second coupling optical waveguide fiber 110 .

The first coupling optical fiber fiber 109 is optically coupled to the first optical fiber 103 , so that the optical useful signal from the first optical fiber 103 is fed to the first coupling optical fiber 109 .

The second coupling optical waveguide fiber 110 is optically coupled to the second optical waveguide fiber 104 , so that the further optical signal generated by an optical transmitter 107 is fed from the second optical waveguide fiber 104 to the second coupling optical waveguide fiber 110 . The optical transmitter 107 is a light emitting diode or a laser.

The other end of the coupling optical fiber 108 is coupled to a second optical fiber connector 111 , which is arranged in a further bore of the coupling arrangement 100 , which second optical fiber connector 111 is also formed by an MT-RJ two-fiber connector.

Via a first connection part 112 of the second optical waveguide connection 111 , the first coupling optical waveguide fiber 109 is optically coupled to a third optical waveguide fiber 113 originating from the coupling arrangement 100 , so that optical signal transmission from the first optical waveguide fiber 103 is thereby the first coupling optical fiber 109 of the coupling optical fiber 108 to the third optical fiber 113 is enabled.

The second coupling optical fiber 110 is coupled to a fourth optical fiber 115 via a second connecting part 114 of the second optical waveguide connection 111 . The fourth optical waveguide fiber 114 is in turn coupled to an optical receiver 116 .

An additional signal circuit, which is optical in accordance with this first exemplary embodiment, is thus created from the optical transmitter 107 via the second optical waveguide fiber 104 , the second coupling optical waveguide fiber 110 and the fourth optical waveguide fiber 115 to the optical receiver 116 .

This additional signal circuit can now be used to signal whether the first optical waveguide connection 102 is coupled to the corresponding second optical waveguide connection 111 .

According to this exemplary embodiment, the optical receiver 116 is coupled to an electrical contact 117 and above it to a first light-emitting diode 118 and a second light-emitting diode 119 as optical display units.

If the optical receiver 116 receives an optical signal, an electrical signal is generated and the two light-emitting diodes 118 , 119 are activated by means of the electrical signal. Furthermore, the electrical contact 117 is connected to a computer 120 as a central processing unit via an electrical line 121 as a control and detection line.

By means of the computer 120 , which according to this exemplary embodiment is coupled to all electrical contacts of the second optical waveguide connections of the coupling arrangement 100 , all existing optical couplings between a respective first optical waveguide connection 102 and a second optical waveguide connection 111 can be queried and on the one hand Others, the light-emitting diodes 118 , 119 can be controlled and activated in this way, even if the corresponding optical waveguide connections have not yet been coupled to one another to indicate to a user which optical waveguide connections are to be coupled to one another and / or are coupled to one another.

According to an alternative embodiment, it is provided that electrical contact 117 is connected to a computer 120 as a central processing unit via an electrical line 121 as a control and detection line and not directly to the light-emitting diodes 118 , 119 . In this case, the light-emitting diodes 118 , 119 are only controlled centrally by the computer 120 , ie activated or deactivated.

In other words, the light emitting diodes 118 , 119 of the first and second optical waveguide connections to be coupled are activated by the computer 120 in order to optically indicate to the installer which optical waveguide connections are to be coupled. If the optical waveguide connections are coupled to one another, this is recorded by the computer 120 and the corresponding light-emitting diodes 118 , 119 are deactivated again, so that the fitter is optically informed that the coupling is switched correctly.

According to this embodiment, two separate signal circuits are thus clearly formed, one for acquiring the coupling information and one for driving the light-emitting diodes 118 , 119 .

Computer 120 is also coupled to a data display device 122 for displaying desired information to a user.

In this context it should be noted that instead of one MT-RJ connector alternatively an SCDC connector or other multi-fiber connectors can be used.  

Second embodiment

Fig. 2 shows a cross section through the coupling assembly 200 according to a second embodiment of the invention.

The coupling arrangement 200 has a front plate 201 with a first optical waveguide connection 202 accommodated in a bore, which is formed by a first plug connector, which first optical waveguide connection 202 is provided with an electrical contact 203 .

A first optical fiber 204 , which is coupled to the first optical fiber connector 202 , is an optical fiber arriving at the coupling arrangement 200 . An optical useful signal for the actual useful data transmission is transmitted via the first optical waveguide fiber 204 .

Via the electrical contact 203 , an additional electrical signal from a battery 205 or another power supply source as the current source is led to the first optical fiber connection 202 via a first electrical line 209 from a computer 215 to the first optical fiber connection 202 .

According to this exemplary embodiment, the electrical contact 203 of the first optical waveguide connection 202 is formed by a conductor path of a printed circuit board.

According to this exemplary embodiment, the first optical waveguide connection 202 is designed to be electrically conductive.

As shown in FIG. 2, the first optical waveguide connection 202 is further coupled on its other connection side to a coupling optical waveguide 206 .

The coupling optical waveguide 206 has a coupling optical waveguide fiber 207 and an electrical line 208 made of a copper strand, which is laid together with Kevlar around the coupling optical waveguide fiber 207 .

The coupling optical waveguide fiber 207 is optically coupled to the first optical waveguide fiber 204 , so that the optical useful signal from the first optical waveguide fiber 204 is fed to the coupling optical waveguide fiber 207 .

The electrical line 208 of the coupling waveguide 206 is electrically coupled to the electrical contact 203 of the first optical fiber connector 202 so that the current provided by the battery 205 electrical power from the battery 205 via the electrical line 209 of the electrical cable 208 of the coupling Optical fiber 206 is supplied.

The other end of the coupling optical waveguide 206 is coupled to a second optical waveguide connection 210 , which is likewise formed by an electrically conductive plug connector.

Via the second optical waveguide connection 210 , the coupling optical waveguide fiber 207 is optically coupled to a second optical waveguide fiber 211 extending from the coupling arrangement 200 , so that optical signal transmission from the first optical waveguide fiber 204 via the coupling optical waveguide Fiber 207 of the coupling optical fiber 206 to the second optical fiber 211 is enabled.

The second optical fiber connector 210 is also provided with an electrical contact 212 . According to this exemplary embodiment, the electrical contact 212 of the second optical waveguide connection 210 is likewise formed by a conductor path of a printed circuit board.

In this context, it should be noted that between the front plate 201 and the respective electrically conductive components of each first optical waveguide connection 202 and each second optical waveguide connection 210 , an insulating body 213 is provided as an electrically insulating element, so that a short-circuit current between the electrically conductive components of FIG Optical fiber connections 210 via the front panel 201 is avoided.

In general, electrical insulation of the electrically conductive components of the optical waveguide connections 202 , 204 and the coupling points from the optical waveguide components and the front plate 201 is provided in order to avoid a short-circuit current.

The electrical contact 212 of the second optical waveguide connection 210 is connected to the computer 215 via a second electrical line 214 such that a closed electrical circuit is formed when the first optical waveguide connection 202 is connected to the second optical waveguide via the coupling optical waveguide 206. Port 210 is coupled.

An additional signal circuit, which is electrical according to this second exemplary embodiment, is thus created from the battery 205 via the first electrical line 209 , the electrical line 208 of the coupling optical waveguide 206 and the second electrical line 214 to the computer 215 . This additional signal circuit can now be used to signal whether the first optical waveguide connection 202 is coupled to the corresponding second optical waveguide connection 212 .

According to this exemplary embodiment, the computer 215 is coupled via a third electrical line 216 as a control and detection line to a further electrical contact 217 and, above that, to a first light-emitting diode 218 and a second light-emitting diode 219 .

If the computer 215 receives an electrical signal via the second electrical line 214 , an electrical control signal is generated by the computer 215 and the two light-emitting diodes 218 , 219 are activated or deactivated by means of the electrical control signal.

By means of the computer 215 , which, according to this exemplary embodiment, is coupled to all electrical contacts of the first optical waveguide connections 202 and the second optical waveguide connections 210 of the coupling arrangement 200 , on the one hand, all existing optical couplings between a respective first optical waveguide connection 202 and a second one Optical fiber connector 210 are queried and on the other hand, the light emitting diodes 218 , 219 can be activated and activated in this way, even if the corresponding optical fiber connectors are not yet coupled to one another, in order to indicate to a user which optical fiber connectors should be coupled to one another.

Computer 215 is also coupled to a visual display device 220 for displaying desired information to a user.

Below are some alternatives to the above shown embodiments shown.  

In alternative configurations of the invention, different types of wiring are provided for electrical contacting in the optical waveguide connections 202 , 210 .

So the electrical connection, especially the electrical contacts in the fiber optic connections designed as a matrix using multilayer printed circuit boards his. This way it becomes possible even at high Packing density a simple connection topology to reach.

Furthermore, in alternative configurations of the invention other types of wiring, such as B. Form cable Single wires or metal rails that hold the fiber optic Record connections, provided.

Furthermore, the electrical line 208 of the coupling optical waveguide 206 can be formed from a braid of electrically conductive elements in analogy to a coaxial cable.

Furthermore, the electrical line 208 of the coupling optical waveguide 206 can be formed from an aluminum jacket or a strip-shaped electrical line from aluminum.

In this context it should be noted that the Coupling arrangement can be modular. In this Case becomes a usual connector module with the above described elements provided. Each module contains one predetermined number of first optical fiber connections and second optical fiber connections, preferably 12 first fiber optic connections and 12 second Fiber optic connections.  

The modules are taken up by a rack, The individual fiber optic cables are Connected to the central processing unit.

Because of the modularity of the clutch assembly, it is possible a distributor of a few Optical fibers up to a very high number of To create fiber optic fibers flexibly expandable.

Claims (9)

1. Arrangement for coupling a plurality of first optical waveguide fibers to a plurality of second optical waveguide fibers,
with a plurality of first optical waveguide connections for optically coupling the first optical waveguide fibers,
with a plurality of second optical waveguide connections for optically coupling the second optical waveguide fibers,
one of the first optical waveguide connections can be optically coupled to one of the second optical waveguide connections by means of a coupling optical waveguide fiber,
with at least one coupling detection unit,
wherein the coupling detection unit is set up in such a way that by means of an additional channel to an optical channel provided by the optical waveguides, which is provided by the coupling optical waveguide fiber, it can be detected whether an optical coupling of a first optical waveguide connection is via there is a coupling optical fiber with a second optical fiber connection. 2. Arrangement according to claim 1,
with a plurality of coupling detection units,
wherein in each case a coupling detection unit is assigned to a first optical fiber connection and / or a second optical fiber connection. 3. Arrangement according to claim 1 or 2, in which the coupling detection unit is set up in this way is that an optical signal in the additional channel can be evaluated.   4. Arrangement according to claim 3,
with an optical coupler on at least part of the first optical fiber connections for coupling a further optical signal into the optical channel of the optical fiber fibers, and
with an optical decoupler on at least part of the second optical waveguide connections for decoupling the optical signal from the optical channel of the optical waveguide fibers. 5. Arrangement according to claim 1 or 2, in which the coupling detection unit is set up in this way is that an electrical signal in the additional channel can be evaluated. 6. Arrangement according to claim 5, for at least part of the first Optical fiber connections and for at least part of the second optical fiber connections each an electrical Connection is provided to which one in the coupling Optical fiber fiber additionally provided electrical Can electrically couple line if the coupling Optical fiber with the corresponding Fiber optic connection is coupled, 7. Arrangement according to one of claims 1 to 6, with a central processing unit with which all Couplings between a first fiber optic connection and a second fiber optic connection via each a coupling optical fiber is detected and get saved. 8. Arrangement according to one of claims 1 to 7, with an optical display unit for every first Optical fiber connection and / or every second Optical fiber connection, which optical Display units with the central processing unit  are coupled such that an optical display unit is activated when the respective first optical waveguide Connection with a second fiber optic connection pair is. 9. Arrangement according to one of claims 1 to 8,
each with a switch for at least some of the first optical fiber connections,
each with an optical display unit for at least some of the second optical fiber connections,
wherein when a switch of a first fiber optic connector is activated, an optical display unit of a second fiber optic connector is activated when the first fiber optic connector, the switch of which has been actuated, is coupled to the second fiber optic connector.