DE102017115689A1 - Optical transmission device - Google Patents

Abstract

The present invention relates to an optical transmission apparatus for splitting a WDM optical signal into a plurality of individual signals and for bundling a plurality of individual signals into a WDM optical signal, comprising a multiplexer housing having a WDM signal terminal for connecting at least one of an optical WDM Signal carrying signal carrier, such as a glass fiber, and a plurality of input and / or output terminals for receiving or output of individual signals. In order to provide an optical transmission device of the type mentioned above, which can be easily connected to further processing elements and is designed to save space, the invention proposes that the plurality of input and / or output terminals are designed as a plug, which from a wall of the Multiplexergehäuses be kept.

Description

The present invention relates to an optical transmission apparatus for splitting a WDM optical signal into a plurality of individual signals and for bundling a plurality of individual signals into a WDM optical signal, comprising a multiplexer housing having a WDM signal terminal for connecting at least one of an optical WDM Signal carrying signal carrier, such as a glass fiber, and a plurality of input and / or output terminals for receiving or outputting individual signals.

Such an optical transmission device is known and is also referred to as a multiplexer or demultiplexer. The abbreviation WDM stands for the English term "wavelength division multiplex" and is an optical frequency division multiplexing method which is used in the transmission of signals via optical fibers. Basically, a plurality of light signals with different wavelengths can be transmitted via a glass fiber. By means of the aforementioned optical transmission device, such optical WDM signals consisting of a plurality of individual signals with different wavelengths can be split into the individual signals.

Such optical transmission devices are usually arranged in a multiplexer housing, wherein the multiplexer housing is a WDM signal terminal for connecting a glass fiber, which is intended to carry the combined multiplexed signal. Furthermore, the optical transmission device has a plurality of input and / or output terminals for receiving or outputting the individual signals. Usually, corresponding plug sockets are provided for this purpose, it being possible for a single signal of a particular wavelength to be switched on or off via each plug socket. The corresponding transmission devices are often mounted in control cabinets or so-called racks.

The individual signals must then be further processed or redistributed in other elements. These further elements likewise have corresponding plug sockets, so that the plug sockets of the optical transmission device can be connected to the corresponding sockets of the further processing elements by means of so-called patch cables.

Through the use of patch cables, the sockets can be connected individually. However, the patch cables have the disadvantage that they are expensive to assemble and also a separate slot in the control cabinet must be provided both for the optical transmission device as well as for the corresponding further processing device. In addition, it must be checked during a troubleshooting, if the patch cables connect the correct sockets together.

Based on the described prior art, it is therefore an object of the present invention to provide an optical transmission device of the type mentioned above, which can be easily connected to further processing elements and is designed to save space.

According to the invention this object is achieved in that the plurality of input and / or output terminals is designed as a plug, which are held by a wall of the multiplexer or are mounted in or on this.

According to the invention, therefore, plugs are now used instead of the usual sockets, so that the transmission device can be plugged as a whole with their plugs into corresponding sockets of signal processing elements. It is understood that the arrangement of the connector of the transmission device must be adapted to the arrangement of the sockets in the processing device.

For most applications, it is advantageous if at least two input terminals are provided for receiving individual signals and at least two output terminals for outputting individual signals.

In this case, an input connection and an output connection are preferably arranged side by side in pairs. For example, each pair of input and output ports may be formed as a duplex LC connector. The LC connector, which dates back to Lucent Technologies, is a small-form-factor connector that has become the standard for LAN cabling. The plug is defined in the standard EN 50173.

In a further preferred embodiment, the plugs of the plurality of input and / or output terminals are arranged side by side in a row. Since most signal processing elements have sockets arranged in a row, this embodiment is advantageous.

In a particularly preferred embodiment of the Distance between adjacent plugs within a pair smaller than between adjacent pairs. Preferably, the distance between adjacent plugs within a pair is from 1% to 25% and most preferably from 2% to 22% less than the distance between plugs of adjacent pairs. Although usually the sockets in the signal processing elements are arranged side by side, these are often arranged in female housings, which can each accommodate a pair of sockets. This may result in the spacing between adjacent pairs of receptacles being slightly greater than the spacing of the boxes within a pair.

In a further preferred embodiment, each plug is reciprocable in a direction perpendicular to the wall of the multiplexer housing, the so-called Z-direction, relative to that wall between first and second Z-positions, wherein in the first Z-position the plug continues to protrude beyond the wall of the multiplexer housing than in the second Z position. The mobility of the individual plugs relative to the wall of the multiplexer housing simplifies the assembly of the optical transmission device to the sockets of signal processing devices. It may happen that the corresponding sockets are not aligned exactly flush with each other. The mobility of each individual connector in the Z-direction can compensate for such deviations.

In order to further simplify the assembly, the plug is preferably resiliently biased in the first Z-position. When mounting the optical transmission device thus the plug are pressed into the corresponding sockets. Due to the elastic bias of each plug exerts a force in the direction of the socket. The elastic bias can be done for example by appropriate spring elements.

In a further preferred embodiment, each plug is in at least one direction, preferably in at least two directions (X-direction and Y-direction) parallel to the wall of the multiplexer housing relative to the wall between a first and a second X-position and / or between a first and second Y-position back and forth movable. Basically, the plugs are floating, so that corresponding tolerances in the plane of the housing wall between adjacent sockets Signalweiterverarbeitender elements can be compensated.

In a preferred embodiment, each plug is designed as a self-locking connector and has an unlocking lever. Such connectors are known in principle and the already cited LC connector is formed. The plug can be plugged into the corresponding corresponding socket and snaps into it. Using the release lever, the catch can be removed and the plug pulled out of the socket.

Therefore, in order to decouple the optical transmission device having a plurality of connectors stuck in respective sockets of signal processing elements at the same time, it is necessary to simultaneously press all the unlocking levers, which may be difficult.

It is therefore provided in a particularly preferred embodiment that an unlocking device is provided on the multiplexer housing, with which simultaneously a plurality of unlocking levers can be operated.

For example, the plugs may be arranged such that the unlatching levers are all aligned in the same direction perpendicular to the direction in which the plugs are arranged in rows side by side.

Then, a release lever movable relative to the multiplexer housing may be provided which can be moved relative to the housing so as to actuate in one position all of the unlocking levers of the plugs.

Furthermore, the present invention relates to a media converter module having an optical transmission device as just described.

The media converter module is there to convert the individual signals with different wavelengths. For example, the media converter module could convert the individual signals of different wavelengths into electrical signals. These could then be further processed with a corresponding device.

It is also possible to convert the electrical signals into individual signals of the same wavelength. For example, some RAN (Radio Access Networks) installations require the use of signals of the same wavelength.

Therefore, the media converter module has a converter for converting a plurality of signals of different wavelength into a plurality of electrical signals. The use of the optical transmission device according to the invention in a media converter module has the advantage that in this application it is clear which plugs are to be connected to which socket and there is no subsequent need to replace the connections.

Such a media converter module can be used for example for connecting a baseband signal processing unit to a mobile radio base station by means of WDM transmission.

In a preferred embodiment, the converter has a converter housing with a plurality of converter input and converter output terminals, which are designed as sockets, wherein the sockets are formed corresponding to the plugs of the optical transmission device and the plug are arranged in the sockets. Basically, a commercially available converter can be used here. The plugs of the optical transmission device must then be adapted to the position of the sockets in the converter.

In addition, a transceiver module may be provided with a transceiver housing having a plurality of sockets. In this case, the sockets can be housed either individually or in pairs in corresponding transceiver housings or all sockets are arranged in a common transceiver housing. The transceiver module is designed to convert the electrical signals into optical signals of the same wavelength.

In this case, a wall of the multiplexer housing of the optical transmission device may be connected to a wall of the transceiver housing. Alternatively, a support plate may be provided with one wall of the multiplexer housing secured to one side of the support plate and one wall of the transceiver housing to the opposite side of the support plate. In this case, the output signals of the converter can be provided via the sockets of the transceiver module. The carrier plate may be, for example, a printed circuit board. This has the advantage that the components for processing the electrical signals and the necessary power supply can be arranged on the circuit board.

In a particularly preferred embodiment, WDM signal connection of the transmission process and sockets of Tranceiver module are arranged so that the corresponding connector to be connected to have the same direction of insertion. Thus, both the WDM signal connector and the sockets of the transceiver module can be populated from the same side.

• 1: eine Draufsicht auf eine erste Ausführungsform der Erfindung,
• 2: eine perspektivische Ansicht einer zweiten Ausführungsform der Erfindung,
• 3: eine perspektivische Ansicht einer dritten Ausführungsform der Erfindung,
• 4: eine Explosionsansicht der Ausführungsform von 1.
• 5-7: drei perspektivische Ansichten eines erfindungsgemäßen Medienkonvertermoduls.

Further advantages, features and applications of the following invention will become apparent from the following description of preferred embodiments and the accompanying drawings. Show it:

• 1 FIG. 2 is a plan view of a first embodiment of the invention. FIG.
• 2 FIG. 3: a perspective view of a second embodiment of the invention, FIG.
• 3 FIG. 3: a perspective view of a third embodiment of the invention, FIG.
• 4 FIG. 4: an exploded view of the embodiment of FIG 1 ,
• 5-7 Three perspective views of a media converter module according to the invention.

In 1 is a plan view of a first embodiment of an optical transmission device according to the invention 1 shown. The transmission device 1 has a multiplexer housing 2 on. At the multiplexer housing 2 is a WDM signal connection 3 provided, which is designed here as a socket. Here, a fiber optic cable can be coupled, via which a multiplex signal of the transmission device 1 is supplied.

On the the WDM signal port 3 opposite side of the multiplexer housing 2 twelve input and / or output terminals are provided, which are designed according to the invention as a plug, namely here as an LC plug. The optical transmission device 1 works as a multiplexer or demultiplexer, which means that via the port 3 coupled multiplex signal divided into its individual wavelength components and the single component via the connector 4 is issued. Basically, the signal transmission path also works in the opposite direction, that is, the plurality of individual signals of different wavelengths can via the corresponding inputs, which act as a plug 4 are formed, the transmission device 1 and are merged by it and via the WDM signal port 3 transferred to the connected fiber there.

One recognizes that the plugs 4 are arranged in pairs, wherein each pair consists of an input terminal and an output terminal, wherein the distance between the plugs of a pair is slightly smaller than the distance between plugs of adjacent pairs.

The transmission device according to the invention has the advantage that it can be plugged directly into corresponding terminals of a transceiver bank processing equipment without the use of patch cables. Although this is the advantage of the individual connection of individual outputs of the transmission device with individual inputs of the subsequent signal processing device is lost, such an individual However, interchangeability is not desired at all in many cases.

The arrangement of the WDM signal terminal 3 is in principle arbitrary. So show the 2 and 3 a second embodiment of the optical transmission device 1' and a third embodiment of the optical transmission device 1" in which the corresponding connection is alternatively arranged. In the in 2 illustrated embodiment, the WDM signal terminal extends 3 perpendicular to the orientation of the plug 4 while still not projecting laterally beyond the housing.

The in 3 shown embodiment are even two WDM signal terminals 3 provided, which also do not protrude laterally beyond the housing, but with respect to the plane through the arranged in rows next to each other plugs 4 is formed, angled.

Especially in the 2 and 3 you realize that every plug 4 a release lever 6 having.

If the LC plug is inserted into the corresponding socket, then the release lever is first pressed down and then locked in the socket. The plug can only be removed from the socket when the lever 6 down, that is pressed towards the plug.

Since the optical transmission device according to the invention has a plurality of plugs, all levers 6 pressed simultaneously to the transmission device 1 separate from the corresponding transceiver bank of a signal-processing element. To enable this is a Entriegelungsaktuator 5 provided, relative to the housing 2 can be moved and then at the same time with all levers 6 comes in contact and pushes down to unlock the connector.

Alternatively, could be on the front, that is, the plugs 4 opposite side, a handle can be arranged, with which the entire transmission device can be pulled out of the receiving transceiver bank. With this handle, a mechanism could be connected, the unlocking actuator 5 activates, so that by manual operation of the handle arranged on the front side an automatic unlocking of all plugs 4 he follows.

To easily assemble and disassemble the plug 4 in a corresponding transceiver bank of a signal processing element, the individual plugs are 4 inside the case 2 the transmission device 1 floating, that is, they can individually relative to the housing 2 be moved to some extent. This becomes clear from the exploded view of 4 , One recognizes that the plugs 4 have a cuboid housing. The multiplexer housing 2 points to its back 7 several recesses 8th on, so that a total of a comb-like structure results. In the individual recesses 8th can then be used in each case a plug with its cuboid housing.

One recognizes furthermore that the plug 4 at its the multiplexer housing 2 facing side a stepped plate 10 through which a corresponding glass fiber 9 is guided. Between the holding plate 10 and the plug housing, a cylindrical connection is provided, which in the 4 can not be seen. As a result, the plug points 4 a circumferential groove between the connector housing 4 and holding plate 10 runs.

Furthermore, two holding elements are provided 11 . 12 , each having semicircular recesses. These are assembled so that the retaining elements 11 . 12 together form a plurality of circular recesses into which the corresponding cylindrical connections between the retaining plate 10 and the cuboid housing 4 The plug 4 to come to rest. The holding elements 11 . 12 be from the inside at the back 7 of the multiplexer housing 2 screwed. The gap between the retaining plate 10 and the cuboid housing of the plug 4 is slightly larger than the thickness of the retaining elements 11 . 12 such that each plug is in the Z direction, that is the direction perpendicular to the back wall 7 of the multiplexer housing 2 are movable to some extent.

In addition, the distance between adjacent teeth of the comb-like structure, that is, the width of the recesses 8th , slightly larger than the width of the cuboid housing of the plug 4 so the plugs 4 within the recesses 8th in two mutually perpendicular directions, the X direction and the Y direction, have a certain play. By this floating storage is a simple installation of the optical transmission system according to the invention 1 possible in a corresponding transceiver bank.

In the 5 to 7 Three perspective views of a media converter module are shown. The media converter module according to the invention has an optical transmission device 1 on, as has been described in connection with the previous figures. Furthermore, there is a converter 13 for converting a plurality of signals of different wavelength into a plurality of electrical signals. Both the optical transmission device 1 as well as the converter 13 are on a backing plate 15 mounted so that the plug 4 the optical transmission device 1 in the corresponding sockets of the converter 13 intervention. The from the converter 13 converted electrical signals are then received by a transceiver module 16 converted into optical signals with the same wavelength and on corresponding sockets 17 output, the transceiver module 16 on the opposite side of the carrier plate 15 is attached.

The carrier plate 15 can be accommodated in a commercial rack or a corresponding cabinet and be designed as a printed circuit board. The media converter module is very compact. It is only necessary to have the appropriate WDM signal through the connector 3 to provide. Without the need for further patch cords, they are connected via the corresponding sockets of the transceiver module 16 Outputs signals of the same wavelength, which can be connected to the corresponding modules of a mobile device.

LIST OF REFERENCE NUMBERS

1, 1 ', 1 "

Optical transmission device

2

Multiplexergehäuse

3

signal connection

4

plug

5

unlocking actuator

6

release lever

7

back

8th

recesses

10

Retaining plate

11, 12

retaining elements

13

converter

14

sockets

15

support plate

16

transceiver module

17

Decker jacks

Claims (12)

An optical transmission apparatus for splitting a WDM optical signal into a plurality of individual signals and for bundling a plurality of individual signals into a WDM optical signal, comprising a multiplexer housing having a WDM signal terminal for connecting at least one signal carrier carrying a WDM optical signal, such as a glass fiber, and a plurality of input and / or output terminals for receiving or outputting individual signals, characterized in that the plurality of input and / or output terminals are formed as a plug, which are held by a wall of the multiplexer , Optical transmission device according to Claim 1 , characterized in that at least two input terminals are provided for receiving individual signals and at least two output terminals for outputting individual signals. Optical transmission device according to Claim 2 , characterized in that in pairs one input terminal and one output terminal are arranged side by side, wherein preferably each pair of input and output terminal is designed as a LC plug in duplex design. Optical transmission device according to Claim 2 or 3 , characterized in that the plugs of the plurality of input and / or output terminals are arranged in a row, wherein preferably the distance between adjacent plugs within a pair is smaller than between adjacent pairs. Optical transmission device according to one of Claims 1 - 4 characterized in that each plug is reciprocable in a direction (Z direction) perpendicular to the wall of the multiplexer housing relative to the wall between a first and a second Z position, wherein in the first Z position the plug continues protruding beyond the wall of the multiplexer housing than in the second Z-position, wherein preferably the plug is resiliently biased in the first Z-position. Optical transmission device according to one of the preceding claims, characterized in that each plug in at least one direction, preferably in at least 2 directions (X-direction and Y-direction) parallel to the wall of the multiplexer housing relative to the wall between a first and a second X. Position and / or between a first and a second Y-position back and forth is movable. Optical transmission device according to one of the preceding claims, characterized in that each plug is designed as a self-locking connector with an unlocking lever, wherein preferably on the multiplexer housing an unlocking device is provided, with which a plurality of unlocking lever can be operated simultaneously. Media converter module with an optical transmission device according to one of Claims 1 - 7 and a converter for converting a plurality of signals of different wavelength into a plurality of electrical signals. Media converter module after Claim 8 , characterized in that the converter has a converter housing with a plurality of converter input and converter output terminals, which are designed as sockets, wherein the sockets are formed corresponding to the plugs of the optical transmission device and the plugs are arranged in the sockets. Media converter module after Claim 9 , characterized in that a transceiver module is provided with a transceiver housing having a plurality of sockets, wherein preferably the transceiver module converts the plurality of electrical signals into optical signals having the same wavelength. Media converter module after Claim 10 characterized in that a wall of the multiplexer housing of the optical transmission device is connected to a wall of the transceiver housing or a support plate is provided and a wall of the multiplexer housing and a wall of the transceiver housing are secured to opposite sides of the support plate. Media converter module after Claim 10 or 11 , characterized in that the WDM signal port and sockets of the transceiver module are aligned parallel to each other so that they can be accessed from the same side of the media converter module.

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