EP4211503A1 - Optoelectronic module, optoelectronic plug connector and optoelectronic subdistribution unit - Google Patents

Abstract

In order to simplify mounting and cabling of optoelectronic plug connectors (3, 3') and – equipped therewith – subdistribution units (6) and subdistribution systems, the use of special module housings (100) is proposed. The latter can accommodate a plurality of, in particular eight, identical and/or different optoelectronic transducers (2, 2') and are installed in the plug connectors (3, 3') between the electrical plug contacts (311) and the multi-core optical cables (58), i.e. the cores (51) thereof. Susceptibility to errors is considerably improved as a result and mounting is significantly simplified as a result of the improved clarity.

Description

Optoelectronic module optoelectronic connector and optoelectronic sub-distribution unit

description

The invention is based on an optoelectronic module according to the preamble of independent claim 1 .

Furthermore, the invention is based on an optoelectronic connector with at least two optoelectronic modules according to claim 1.

In addition, the invention is based on an optoelectronic sub-distribution with a central optoelectronic connector of the aforementioned type, and several decentralized connectors, each having at least one optoelectronic module.

Such modules, connectors and sub-distributions are required in order to install and operate complex signal distributions without errors or interference.

State of the art

Optoelectronic converters, namely what are known as “transceivers” (Tx) and “receivers” (Rx), and connectors in combination with such optoelectronic converters are known from the prior art.

EP 1 180 704 A2 relates to a connector and a system for the electrical connection of subracks in the field of switching technology. At least one optical transmission cable can be connected to the connector. An optoelectronic converter is accommodated in the housing of the plug itself. In addition, in contact with the printed circuit board, there is an optoelectronic converter with plug-in contacts that are either plugged onto the printed circuit board or are soldered. On the plug-in side there are also plug-in contacts to which the optical signal cables are connected. At least one of the plug contacts is used to supply power to active components in the plug. In particular, the optoelectronic converter is supplied with electrical energy through the plug contact.

The document DE 20 2017 100 608 U1 criticizes the aforementioned design for the contacting taking place outside of the connector housing on the one hand, the small number of optical fibers that can be connected to one unit and the undesirably high space requirement on the other. Based on this, the document proposes a connector which has a printed circuit board and at least one optoelectronic converter. The converter is accommodated in a converter housing and arranged on the printed circuit board and is connected to it in an electrically conductive manner. The optical fiber is receivable in the converter housing.

A disadvantage of this prior art is that optoelectronic plug connectors and in particular optoelectronic sub-distribution boards with such plug connectors often require undesired production and/or installation outlay. The assembly, assignment and cabling of the electro-optical modules on a connector-internal printed circuit board is complex. It has also been found that there is a great need on the customer side to be able to use optoelectronic converters from different manufacturers, which naturally vary in the geometric dimensions of their converter housing. Furthermore, there is a high demand for flexibly adaptable optoelectronic cabling, especially for central sub-distributions, especially in the railway sector.

The German Patent and Trademark Office has researched the following prior art in the priority application for the present application: DE 20 2017 100 608 U1, EP 1 180 704 A2 and US 2002/0141706 A1.

task

The object of the invention is therefore to specify an optoelectronic module, an optoelectronic connector and an optoelectronic sub-distribution, the manufacturing, assembly, configuration and / or installation effort is as low as possible and at the same time can be adapted as flexibly as possible to individual customer requirements.

The object is solved by the subject matter of the independent claims.

An optoelectronic module has a module housing and several, in particular eight, optoelectronic converters. These converters have the following: a converter housing with internal converter electronics arranged therein and a number of electrical connections which are electrically conductively connected to the converter electronics and which protrude from the converter housing and an optical connection which is arranged in the converter housing and which receives light through a window in a housing wall of the converter housing and/or or can emit.

The module housing serves on the one hand to accommodate the optoelectronic converters and to fasten them together on a printed circuit board. On the other hand, the module housing is used to connect and relieve strain on optical wires, ie single wires of multi-wire optical cables, in particular fiber optic cables (LWL) to the optical connections of the converter. In particular, a multi-wire optical cable can have eight optical wires (ie optical individual wires). The module housing is designed in at least two parts and has a housing bottom part and a housing top part that can be connected to it and fixed thereto, in particular that can be latched.

A converter chamber is arranged in the lower housing part for each optoelectronic converter to be accommodated in the module housing, in order to accommodate the respective optoelectronic converter therein in a form-fitting manner.

In particular, a converter recess can be arranged in the upper part of the housing for each optoelectronic converter. By joining the upper part of the housing with the lower part of the housing, the converter recess comes to lie above the converter chamber. As a result, the converters can then be held in a form-fitting manner in each direction in their respective converter chambers. In particular, the module housing can have eight converter chambers and converter recesses.

The converter chamber of the lower housing part is designed to be open at its end intended for attachment to the printed circuit board or has one or more contact feedthrough openings at this end for passing through and for electrical contacting of the electrical connections of the optoelectronic converter with the printed circuit board.

Both the lower part of the housing and the upper part of the housing each have a contact surface. These two contact surfaces abut against each other when they are joined, in particular come to lie on top of one another and are accordingly referred to as common contact surfaces. On these common contact surfaces, both the upper part of the housing and the lower part of the housing have a part of a cable duct leading to the converter chamber for each converter chamber, ie an upper part of the cable duct and a lower part Part of the cable duct, whereby the complete cable duct is formed after the upper and lower parts of the housing have been assembled. The cable duct is thus set up to feed the optical wires to the converter chambers and thus to the optoelectronic converters respectively arranged therein.

Advantageous configurations of the invention are specified in the dependent claims and the following description.

In a preferred embodiment, the upper part of the housing has a cable fixing recess for each cable duct, which is connected to the respective cable duct, more precisely to the upper part of the respective cable duct, and into which a fixing element can be inserted in order to fix the respective optical wire with strain relief on the module housing.

The lower housing part and the upper housing part of the module housing can preferably be fastened to one another by latching, screwing, gluing, pressing, casting, hot pressing, riveting, spraying and/or positive insertion. The latching, screwing and pushing in have the advantage that they are reversible, i.e. the connection can be separated non-destructively, for example to replace a converter. The latching is less labor-intensive and enables the upper and lower parts to be brought together in the axial direction of the optoelectronic converters, as a result of which they can be fixed particularly easily in their converter chambers and is therefore particularly advantageous.

In a preferred embodiment, both the lower housing part and the upper housing part each have a step. The lower housing part has an inner step and the upper housing part has an outer step. This advantageously serves to increase the packing density and to simplify the insertion of the optical wires.

Then a first group of cable ducts can be arranged in a first level and a second part of the cable ducts can be arranged in a second level. The first level can be offset from the second level by the gradation by at least the thickness of the cable duct.

This has the advantage that a group of optical wires can be introduced into the module housing in the first level and that a second group of optical wires can be introduced into the module housing in the second level, whereby the packing density is increased. This also makes it easier to manually insert the wires into the respective cable duct.

As already mentioned, the optoelectronic converters each have a converter housing with internal converter electronics arranged therein, as well as the electrical connections already mentioned, which protrude from the housing. B. can be designed as pins. Furthermore, they have the said optical connection arranged in the converter housing, which can receive and/or emit light through the window in a housing wall. The optical cores of the optical cable are now to be fed to this optical connection by means of the cable duct of the module housing. On the other hand, as already mentioned, the electrical connections of the converters can be electrically conductively connected, in particular soldered, to conductor tracks on the printed circuit board

According to their internal converter electronics, some of the optoelectronic converters can be transceivers (Tx), ie they receive electrical signals and convert them, e.g. B. by an LED ("Light Emission Diode"), in an optical signal.

Another part of the optoelectronic converters can be receivers (Rx) according to their internal converter electronics, i. That is, they receive an optical signal and convert this optical signal into an electrical signal.

In a preferred embodiment, all of the optoelectronic converters have the same housing dimensions.

In another embodiment, at least two of the optoelectronic converters have different housing dimensions, i. H. their converter housings differ in shape, e.g. B. because they come from different manufacturers.

In a preferred embodiment, the module housing is able to accommodate the optoelectronic converters with the aforementioned different housing dimensions in a form-fitting manner in its converter chambers. As already mentioned, these different optoelectronic converters can come from different manufacturers and can be used by the customer based on decision criteria such as price and/or quality and/or other specific properties, which offers the user a so-called “second source”. and thus makes purchasing more flexible and secures deliveries.

Despite the different housing dimensions, both types of transducers can be positively accommodated in the same transducer chambers in the module housing, in that the transducer chamber has a suitable contour which is specially adapted to these two housing dimensions in order to make this possible. This can - Depending on the type of converter housing involved - for example by a funnel shape and/or corresponding webs or other special geometric adjustments to the shape of the converter chambers, which the expert designs in detail on the basis of the various converter housings.

An optoelectronic connector has a connector housing. An internal printed circuit board is arranged therein and at least two optoelectronic modules of the aforementioned type are arranged on the printed circuit board. This printed circuit board has conductor tracks which are electrically conductively connected on the connection side to at least one of the electrical connections of the optoelectronic converters and which are electrically conductively connected to electrical plug contacts of a plug-in area of the connector on the plug-in side.

In particular, the connector housing can have a separate cable outlet for each of the optoelectronic modules.

An optoelectronic sub-distribution has a central optoelectronic connector of the aforementioned type and a plurality of decentralized optoelectronic connectors, the decentralized connectors each having at least one and in particular exactly one optoelectronic module.

This also reveals sub-distributions in which the decentralized connectors have exactly one optical module. This is particularly advantageous due to the clarity and the simple and inexpensive manufacturability.

This also sub-distributions are still disclosed, in which the decentralized connector can have multiple optical modules, although the aforementioned variant, in which the decentralized Connectors having exactly one optoelectronic module is particularly favored because of their simplicity and easily manageable structure. In individual cases, however, more complex sub-distributions, possibly even in a tree structure, may be required. This variant can be particularly advantageous because these distributions can be cascaded, ie a central connector of a further sub-distribution of the aforementioned type could advantageously be plugged into such a decentralized connector again in order to create a sub-distribution system with a complex, correspondingly sub-branched tree structure.

In a preferred embodiment of the sub-distribution, the number of optoelectronic modules in the central optoelectronic connector matches the number of all optoelectronic modules of all decentralized optoelectronic connectors that belong to this sub-distribution. Put simply, the central connector then has just as many modules as the decentralized connectors of this sub-distribution together.

Otherwise, the decentralized connectors can be constructed in a manner comparable to the central optoelectronic connector.

Furthermore, the optoelectronic sub-distribution has several optical cables, each with several, in particular eight, optical wires, the optical wires of a cable being connected on the one hand to one of the optoelectronic modules of the central optoelectronic connector and on the other hand to the optoelectronic module of one of the decentralized connectors - or possibly to one the optoelectronic modules of one of the decentralized connectors - are connected. In particular, each of the optoelectronic modules of the at least one central optoelectronic connector can be connected via an optical cable to exactly one optoelectronic module of one of the associated decentralized optoelectronic connectors.

Put simply, this means that in an advantageous embodiment, one optical module of the central connector can always be connected to exactly one optical module of a decentralized connector via exactly one optical cable. For example, the central connector can have three modules, each of which is connected via an optical cable to a respective decentralized connector, which has only one module. This sub-distribution then has a central connector and three decentralized connectors. This enables a resolution/sub-distribution that is easy to understand, easy to construct, easy to assemble and ergonomic to produce. It is easy to see that this structure is very clear and very error-free in the construction.

As already indicated, an optoelectronic sub-distribution system is also disclosed here. The sub-distribution system has several sub-distributions of the aforementioned type.

In a first embodiment, these can be connected to one another in the aforementioned tree structure.

Alternatively or additionally, several sub-distributions can also be operated in parallel in a sub-distribution system. In an expedient configuration, several sub-distributions, e.g. B. with cable ties, be connected to a common wiring harness. Then there are several central optoelectronic connectors operated in parallel in the sub-distribution system. Furthermore, there are several decentralized connectors for each of these central connectors, which are each connected to this central connector via an optical cable or at least via optical wires.

In a further advantageous embodiment, such an optoelectronic module can also be arranged on a conventional printed circuit board, for example a printed circuit board of an electronic device, in order to conveniently connect the optical wires to the printed circuit board electronics. As a result, the electronic device can also be fitted with an optical interface that is particularly advantageous.

example

An embodiment of the invention is shown in the drawings and is explained in more detail below. Show it:

1a, b an optoelectronic module in an exploded view from two different viewing angles;

2a, b shows the assembled optoelectronic module from the two different viewing angles;

3a-d a connector with housing and two optoelectronic modules;

3e, f the connector without housing;

Fig. 4a, b two different optoelectronic sub-distributions.

The figures contain partially simplified, schematic representations.

In part, for the same, but possibly not identical Elements used identical reference numerals. Different views of the same elements could be scaled differently.

1a and 1b show an optoelectronic module 1 from two different perspectives, each in an exploded view.

The optoelectronic module 1 has a plurality of optoelectronic converters 2, 2', which are designated in detail in FIG. 1a and which can differ in their design.

The optoelectronic converters 2, 2' each have a converter housing 20, 20' with internal converter electronics arranged therein, as well as electrical connections 21, 21', which are electrically conductively connected to the converter electronics and protrude from the converter housing 20, 20'. Furthermore, the optoelectronic converters 2, 2' each have an optical connection 22, 22' which is arranged in the converter housing 20, 20' and which can receive and/or emit light through a window in a housing wall of the converter housing.

The optoelectronic module 1 has a module housing 100 which is designed in two parts and consists of an upper housing part 11 and a lower housing part 12 .

Transducer chambers 120 are arranged in the lower housing part 12, into which the optoelectronic transducers 2, 2' can be inserted in a form-fitting manner. It is irrelevant that the converter housings 20, 20' of different converters 2, 2' can have different housing shapes, since the converter chambers 120 of the lower housing part 12 are adapted to several converter housings 20, 20' and are thus suitable for receiving the various converter housings 20, 20' in a form-fitting manner are. At a lower end, which is provided for contact on the printed circuit board 4, the converter chambers 120 each have a contact feedthrough opening 125, shown and labeled in FIG a printed circuit board 4.

The upper housing part 11 can be latched to the lower housing part 12 by means of latching hooks 117 on a latching edge 127 of the lower part 12 . Furthermore, the housing upper part 11 has guide pins 116 and the lower part has guide recesses 126, which makes it easier to bring the two housing parts 11, 12 together. The upper housing part 11 and the lower housing part 12 each have a common contact surface 114, 124 with which they connect to one another in the assembled state.

A part of a cable duct is formed in each case in this common contact surface, namely an upper part 118 of the cable duct 18 in the upper housing part 11 and a lower part 128 of the cable duct in the lower housing part 12 .

The upper housing part 11 also has a cable fixing recess 19 for each cable duct 18, which connects its upper side 15 to the upper part of the cable duct 118. For this purpose, the optoelectronic module 1 has a cable fixing element 10 in each case, which can be inserted into this cable fixing recess 119 in a positive and non-positive manner in order to fix an inserted optical wire 58 in the cable duct 18 with strain relief.

Furthermore, the upper housing part 11 has an outer step 113 and the lower housing part has an inner step 123.

The importance of these steps 113, 123 can be seen from Figures 2a and 2b. These show the composite optoelectronic Module 1 from the two different perspectives. The two housing parts 11 , 12 together form the module housing 100 . A total of eight optoelectronic converters 2 , 2 ′ are installed in the module housing 100 .

Both the converters 2, 2' and the cable ducts 18, 18' are distributed over two different levels, which are offset from one another by at least one cable duct diameter due to the stepped structure. It is easy to see that this achieves a higher packing density. The manual insertion of the optical wires 51 and their fixation by the cable fixing elements 10 during assembly is also made easier.

2b shows particularly well how the electrical connections 21, 21' of the optoelectronic converters 2, 2' are passed through the contact feedthrough openings 125 of the lower housing part 12 and protrude for connection to a printed circuit board 4.

This printed circuit board 4 can first be seen in FIG. 3a with a restricted view of its mounting surface (not explicitly designated for reasons of clarity), namely as a component of an optoelectronic connector 3 in whose housing 30 it is arranged. Two optoelectronic modules 1 are arranged on said mounting surface of the printed circuit board 4 and electrically conductively connected to the electrical connections 21, 21' of their optoelectronic converters 2, 2'.

The connector 3 has a plug-in area 31 with

Plug contacts 311, which are also electrically connected to the printed circuit board 4, ie connected to it. However, this connection/connection is not shown in the drawing for reasons of clarity. Furthermore, the connector 3 has a cable connection area 32. Two cable outlets 320 are arranged in it. An optical cable 58 is routed through each cable outlet 320 . Each cable has eight optical cores 51, four cores 51 being combined into a bundle. One of them is labeled Tx. Its optical cores are each intended for connection to those optoelectronic converters 2, 2' which are designed as transceivers (Tx). These transceivers (Tx) convert electrical signals from the plug contacts 311 into optical signals, which they transmit via their optical connection 22, 22' to the optical wire 52 connected thereto. The other bundle is labeled Rx and is intended for connection to those optoelectronic converters 2, 2' that are designed as receivers (Rx). The receivers (Rx) convert optical signals of the respective connected optical wire 51 into electrical signals, which they transmit via their electrical connections 21, 21' via the printed circuit board 4 to the respective plug contacts 311. Thus there are four forward and four return lines per cable 58 . In addition, the housing 30 has a display window 330 that is still open in this representation.

Fig. 3b shows the connector 3 with the housing 30, which was closed by a housing cover unspecified. The arrangement shown here also differs from that shown in the previous illustration in that the cable outlets 32 are closed with cable glands 321, each cable gland 321 providing strain relief for a bundle of wires that is passed through. In addition, the display window 330 is closed with a blind plate 33 .

This arrangement is in Fig. 3c for the connector 3 in the open and in Fig. 3d in the closed state modified in that in which Display window 330 instead of the aforementioned dummy plate 33, a status display 34 with one LED (“Light Emitting Diode”) for each optical wire 51/each electro-optical converter 2, 2' is arranged. As soon as signals are transmitted via the respective optical wire 51 or the optoelectronic converter 2, 2' connected to it, the corresponding LED lights up to indicate this signal flow. For this purpose, the status display 34 is connected to the printed circuit board 4, from which it 34 receives the corresponding electrical signals.

3e and 3f show an arrangement similar to that of FIG. 3a, but without the connector housing 30, from two different views.

The printed circuit board 4 can be seen particularly well in this representation. In particular, FIG. 3f allows a view of an underside of the printed circuit board 4 (likewise unspecified for reasons of clarity), which shows its above-mentioned mounting surface opposite. Separation openings 40 are arranged in the printed circuit board 4 . Through this separation openings 40, the overlying fixing elements 10 are with a tool such. B. a pointed object such. B. an electric screwdriver o. Ä., From the Kabelfixierausnehmung 119 of the module housing 100 removable.

4a shows a first embodiment of an optoelectronic sub-distribution 6 in a schematic representation.

This first sub-distribution 6 has a very simple form and is formed from a central connector 3 of the aforementioned type and two decentralized connectors 3 ′, which differ from the central connector 3 in that they each have only one optoelectronic module 1 . The central connector 3 thus has just as many optoelectronic modules 1 as the decentralized connectors together. The modules 1 of the decentralized Connectors are each arranged on a printed circuit board 4', which in this embodiment has only eight conductor tracks (although any other number is of course also possible). Accordingly, each of the decentralized connectors in this example also has only eight plug contacts 311. On the cable connection side, the central connector 3 is connected to one of its optoelectronic modules 1 via a corresponding eight-wire optical cable 58 to an optoelectronic module 1 of one of the decentralized connectors 3'.

This design has the advantage that it is constructed in a particularly clear and error-free manner and thus allows very simple assembly.

Fig. 4b shows a second sub-distribution 6 'with a central 3 and three decentralized connectors 3'.

It can be seen from this illustration that the number of optoelectronic modules 1 of the decentralized plug connector s' does not necessarily have to match the number of optoelectronic modules 1 of the central plug connector 3. Instead, the optoelectronic converters 2, 2' of these modules 1 can also be freely connected to one another via individual optical wires 51 if required.

This embodiment offers the advantage that maximum flexibility is made possible for the assignment of the plug contacts 311, 311' and at the same time offers a simplification of assembly compared to the prior art.

The optoelectronic modules 1 of the central 3 and the decentralized 3' connector can be identical in both versions. Even if different aspects or features of the invention are shown in combination in the figures, it is obvious to the person skilled in the art--unless stated otherwise--that the combinations shown and discussed are not the only possible ones. In particular, mutually corresponding units or complexes of features from different exemplary embodiments can be exchanged with one another.

Optoelectronic module optoelectronic connector and optoelectronic sub-distribution unit

Reference List

I optoelectronic module

10 fixing element

18,18' cable channels

100 module housing

I I upper part of the housing

110 transducer recess

113 outer stage

114 common contact area (of the upper part of the housing)

115 top

116 guide pins

117 snap hooks

118 upper part of the cable duct

119 cable fixing recess

12 lower housing part

120 converter chamber

123 inner stage

124 common contact area (of the lower part of the housing)

125 via hole

126 guide recesses

127 locking edge

128 lower part of the cable duct

2, 2' optoelectronic converters

20, 20' converter housing

21, 21' electrical connections

22, 22' optical connectors 3 (central) connector

3' decentralized connector

30, 30' connector housing

31 mating area

311, 31r plug contacts

32 cable connection area

320 cable outlet

321 cable gland

33 blind plate

330 display window

34 status display

4, 4' (connector internal) circuit board

40 separation port

51 optical wire

58 optical cable

Rx transceiver (supply line)

Tx receiver (supply line)

6 optoelectronic sub-distribution

Claims

Optoelectronic module optoelectronic connector and optoelectronic sub-distribution unit

Claims ptoelectronic module (1), having the following: a plurality of optoelectronic converters (2, 2'), which have the following: o a converter housing (20) with internal converter electronics arranged therein and o electrical connections electrically conductively connected to the converter electronics which protrude from the converter housing (20) and o an optical connection (22) arranged in the converter housing (20) which can receive and/or emit light through a window in a housing wall of the converter housing (20), a module housing (100) for receiving and joint attachment of the optoelectronic converters (2) on a printed circuit board (4) on the one hand and for the connection and strain relief of optical wires (51) to the optical connections (22) of the converters (2) on the other hand, the module housing (100) being designed at least in two parts is and has a housing upper part (1 1) as well as a housing lower part (12) which can be connected thereto and fixed thereto, wherein

■ a converter chamber (120) is arranged in the lower housing part (12) to positively accommodate each optoelectronic converter (2) to be accommodated, the converter chamber (120) being open at its end provided for attachment to the printed circuit board (4). is executed or at this end has one or more contact feedthrough openings (125) for passing through and for making electrical contact with the electrical connections (21, 21') of the optoelectronic converter (2) with the printed circuit board (4), and wherein

■ Both the upper housing part (11) and the lower housing part (12) have part of a cable duct (118, 128) on their common contact surfaces (114), whereby o after the upper housing part (11) and lower housing part (12) have been assembled, a complete Cable duct (18) for feeding the optical wires (58) to the converter chambers (120) and thus to the optoelectronic converters (2) arranged therein. Optoelectronic module (1) according to claim 1, wherein the upper housing part (11) has a cable fixing recess (119) for each cable duct (18), which is connected to the upper part of the respective cable duct (118) and into which a fixing element (10 ) can be inserted in order to ensure that the respective optical wire (58) is fixed to the module housing (100) with strain relief. Optoelectronic module (1) according to any one of the preceding claims, wherein the housing upper part (11) and the housing lower part (12) of the module housing (100) by latching, screwing, gluing, pressing, casting, hot pressing, riveting, spraying and / or positively pushing together are attachable.

4. Optoelectronic module (1) according to one of the preceding claims, wherein both the upper housing part (11) and the lower housing part (12) each have a step (113, 123) to increase the packing density and simplify the introduction of the optical wires (58). .

5. Optoelectronic module (1) according to claim 4, wherein a first part of the cable ducts (18) is arranged in a first level and wherein a second part of the cable ducts (18 ') is arranged in a second level and wherein the first level to the second Level through the gradation (113, 123) by at least the thickness of the cable duct (18, 18 ') is arranged offset.

6. Optoelectronic module (1) according to one of the preceding claims, wherein at least some of the optoelectronic converters (2,2') are transceivers ("Tx") according to their internal converter electronics, and that their optical connection (22) configured to emit light.

7. Optoelectronic module (1) according to one of the preceding claims, wherein at least some of the optoelectronic converters (2, 2′) are receivers (“Rx”) according to their internal converter electronics, and that their optical connection (22, 22') is set up to receive light.

8. Optoelectronic module (1) according to one of claims 5 to 7, wherein the converter housing (20) of all the module housing (100) arranged optoelectronic converter (2, 2 ') have the same housing dimensions.

9. optoelectronic module (1) according to any one of claims 1 to 7, at least two of the optoelectronic converters (2, 2') arranged in the module housing (20) having different converter housings (20, 20') with different housing dimensions. Optoelectronic connector (3), having a connector housing (30) and a circuit board (4) arranged in the connector housing (30) and at least two optoelectronic modules (1) arranged on the circuit board according to one of the preceding claims, wherein the circuit board (4) has electrical Has conductor tracks which are electrically conductively connected on the connection side to at least one of the electrical connections (21, 21') of the optoelectronic converters (2, 2') and which are connected to electrical plug contacts (311) of a plug-in area (31) of the plug connector (3) on the plug-in side are electrically connected. Optoelectronic connector (3) according to claim 10, wherein the connector housing (30) for each of the optoelectronic modules (1) provides a separate cable outlet (320). Optoelectronic sub-distribution with a central connector (30) according to one of Claims 10 to 11 and a plurality of decentralized connectors (3'), each of which has at least one optoelectronic module (1) according to one of Claims 1 to 9, and with a plurality of optical cables (58 ) each having a plurality of optical cores (51), the optical cores (51) of each of the optical cables (58) being connected on the one hand to the optical connection (22, 22') of an optoelectronic converter (2, 2') of one of the optoelectronic modules (1 ) of the central optoelectronic connector (3) and on the other hand to the optical connection (22, 22 ') of the optoelectronic converter (2, 2') of an optoelectronic module (1) of the decentralized optoelectronic connector (3') are connected. Optoelectronic sub-distribution according to claim 12, wherein the number of optoelectronic modules (1) in the central connector (3) corresponds to the number of all optoelectronic modules (1) of all decentralized connectors (3') belonging to this sub-distribution. Optoelectronic sub-distribution according to one of claims 12 to 13, wherein each of the optoelectronic modules (1) of the central connector (3) is connected via an optical cable (58) to exactly one optoelectronic module (1) of a decentralized optoelectronic connector. Optoelectronic sub-distribution according to one of claims 12 to 14, wherein each of the decentralized connectors has exactly one optoelectronic module (1). Optoelectronic sub-distribution system comprising a plurality of optoelectronic sub-distributions according to one of Claims 12 to 15.