DE10023463A1 - Optical fiber connector, has electro-optic module comprising flexible base body which is compressed to produce spring force - Google Patents

Abstract

The connector has two connector parts (12,14) provided with a ferrule (16) and electro-optic module (20) respectively. When the two parts are connected, the ferrule lies opposite the input or output of the electro-optic module. The electro-optic module has a flexible base body (28) which is compressed and/or deformed to produce a spring force so that its end comprising the input/output is loaded in an end position in which the input/output of the ferrule lies opposite.

Description

The invention relates to a connector for light guides with two pluggable connector parts with at least one optical Ferrule or at least one electro-optical module are provided, the on the one hand at least one optical input and / or output and others on the other hand in particular has electrical connection contacts, with assembled connector parts the ferrule the optical out or The input of the electro-optical module is opposite. Under an electro optical module is to be understood as any module in which optical signals in electrical signals and / or electrical signals in optical signals are converted. The electrical connection contacts of a respective electro-optical module can, for example, with a PCB are soldered.

The functionality of fiber optic connectors of the beginning named type is from the mutual alignment of the optical compo dependent. An incorrect alignment of these components can lead to greater light losses and consequently the functionality of the entire light guide system.

The aim of the invention is to provide a connector of the type mentioned to create, in which the resulting with respect to the optical function Tolerance range kept as small as possible in a simple and reliable manner  is. In particular, the resultant in the axial direction Tolerance range should be kept as small as possible.

This object is achieved according to the invention in that the electro optical module be a flexible base body at least in some areas sits, so compressible and / or generating a spring force it is deformable that its optical input and output Is resiliently loaded into an end position in which the optical input or output of the ferrule is opposite.

Due to this training, the optical functi on resulting tolerance range reduced to a minimum, so that after a respective plugging together of the connector parts always an optimal Function is guaranteed. In particular, regarding the optical Tolerance range resulting in function in the axial direction is significantly reduced device. Given the flexible body of the electro-optical Module formed spring is an opti with minimal construction Male connection guaranteed. To the usual elaborate Aus straightening concepts can therefore be dispensed with. After the spring is on the side of the electro-optical module is not provided more the risk that the light guide provided with the respective ferrule with a tensile load acting on it from the electro-optical module Will get removed. The optical ferrule can now in the relevant Ver Binder part to be fixed. The invention is particularly in the case of hybrid compounds other (hybrid connectors) applicable. Strike in the axial or mating direction alignment tolerances of the respective electro-optical systems optimized in a simple and reliable way.  

According to a preferred embodiment of the invention The connector is the electro-optical module based on a dreidi dimensional injection molded circuit carrier, d. H. based on a so-called MID (molded interconnected device) formed. Such a MID can have a printed circuit on its surface his.

The electro-optical module can be integrated in the MID or on include attached electro-optical one-chip component.

The electro-optical module can in particular also be based on a MID is formed, which is designed as an SMD component (SMD = surface mounted device).

In or on the MID can further the electro-optical component assigned circuits may be provided.

The electro-optical module can in particular be an optical or electro include optical transceiver module or vorese as a transceiver module hen.

At its end, which has the optical input and output electro-optical module preferably provided with a plug receptacle, in the ferrule is insertable. This connector forms a kind of optical Chamber, which may be formed by the MID itself. By the MID can thus also serve as an optical connection at the same time de chamber can be created.  

The end of the electro-optic having the optical input or output cal module is in its end position expediently at one of the associated connector part, transverse to the axial direction start the stop surface.

It is also an advantage if in the mated condition with the Ferrule provided connector part on a cross to the axial direction abuts the stop surface assigned to the other connector part.

In a preferred embodiment of the plugver according to the invention The ferrule is fixed in the connector part in question. Even with one The tensile load of the light guide in question is thus ruled out that the ferrule is removed from the electro-optical module.

The connector part provided with the electro-optical module can in particular be designed especially as a header or chip holder.

The connector can be used in particular as a hybrid connector (hybrid con nector).

With the connector according to the invention, in particular also with regard to the positioning of chips (e.g. LED and PD) Comply with tolerances. Values can be less than 20 µm, for example be enough. The particular transceiver circuit design becomes essential more flexible. There is more space available than with versions with Holding frame (leadframe). A respective one that is adjacent to the recipient Post amplifier can be integrated more easily. There can be more final contacts may be provided. The conductor tracks and the gaps  can be very small and e.g. B. in a range of about 50 microns lie. The integration of capacitors or capacitors is ver simple. SMD caps are cheaper than bond types. The MID can be designed as an SMD component. The MID can do the same an optical chamber can be realized in good time. It can be simple in a wide range of hybrid connection systems chen. The overall manufacturing costs are significantly reduced. So different components, component holders, Ab integrate shielding and / or the like. Examples of MIDs are at to be found for example in the field of infrared sensors.

Further advantageous embodiments are set forth in the dependent claims given.

The invention is un based on exemplary embodiments ter explained in more detail with reference to the drawing; in this show:

Fig. 1 is a schematic, partially sectioned illustration of an optical fiber connector and

Fig. 2 is a schematic, partially sectioned illustration of a further embodiment of an optoelectronic chip or component comprising electro-optical module of the optical fiber connector.

Fig. 1 shows a schematic, partially sectioned representation of an optical fiber connector 10 with two pluggable connector parts 12 , 14th

The connector part 12 is hen with at least one optical ferrule 16 , which is arranged at the end of a light guide 18 in question and serves to receive and center the fiber. The fiber is attached in the Fer rule 16 and the ferrule is snapped into the connector.

The other connector part 14 is provided with at least one electro-optical module 20 . An electro-optical module is to be understood here as any module in which optical signals are converted into electrical signals and / or electrical signals into optical signals.

The ferrule 16 female fastener part 12 may be, for example, The portion 14 is provided as a receiving part for example, as plug-in part and the electro-optical module 20 receiving Verbin. The connec derteil 14 can thus be designed in particular as a so-called header or chip holder. In particular, the connector can be designed as a hybrid connector.

The electro-optical module 20 has on the one hand at least one optical input and / or output 22 and on the other hand electrical contact 24 . The optical input or output 22 opens into a plug-in receptacle 26 forming an optical chamber, into which the ferrule 16 projects when the connector parts are plugged together. When connector parts 12 , 14 are plugged together, the ferrule 16 or the light guide in question is thus opposite the optical output or input 22 of the electro-optical module 20 .

As can be seen from FIG. 1, the electro-optical module 20 has a base body 28 which is bent in a zigzag shape in an area between its end having the optical input or output and its end having the electrical contacts 24 and is accordingly flexible is executed. The base body 28 of the electro-optical module 20 is thus compressible and / or deformable with the generation of a spring force such that its end having the optical chamber or plug receptacle 26 and the optical input or output 22 is resiliently loaded toward the ferrule 16 . Due to this inherent in the electro-optical module 20 spring 46 , the relevant module is thus held resiliently in a respective end position in which the optical input and output 22 of the ferrule 16 is opposite.

The electro-optical module 20 can in particular be formed on the basis of a three-dimensional injection-molded circuit carrier (MID, molded inter-connected device), the surface of which is advantageously provided with a printed circuit.

The electro-optical module 20 can comprise, for example, an electro-optic one-chip component 30 integrated in or attached to the MID. In principle, it is also conceivable that the electro-optical module 20 is formed on the basis of a MID, which is designed as an SMD component (SMD = surface mounted device). Further circuits 32 assigned to the electro-optical component 30 can also be integrated in or attached to the MID. For example, the electro-optical component 30 may have a subsequent amplifier and / or the like connected downstream. In Fig. 1 further conductor tracks 34 can be seen, serve to produce the electrical connections REQUIRED chen.

The electro-optical module 20 can in particular be designed as a transceiver module.

In the present exemplary embodiment, the end of the electro-optical module 20 which has the plug-in receptacle 26 and the optical input or output 22 is in its end position on a stop surface 36 assigned to the connector part 14 in question, transverse to the axial or plug-in direction z ver. The provided with the ferrule 16 Ver connector part 12 is after plugging together the two connector parts 12 , 14 on a transverse to the axial direction z stop surface 38 of the connector part 14 .

The two stop surfaces 36 , 38 are provided on two opposite sides of a transverse wall 40 of the connector part 14 . This transverse wall 40 is provided with an opening 42 through which the ferrule 16 extends into the plug receptacle 26 of the electro-optical module 20 which forms the optical chamber.

As can be seen from FIG. 1, there is a relatively large amount of space available for the electro-optical module provided with an integrated spring function. In addition, an optimal optical interface with very small tolerances results in the area of the optical chamber 26 .

The electrical connection contacts 24 of the electro-optical module 20 , which are provided, for example, as SMD contacts, can in particular be soldered to a printed circuit board.

Fig. 2 shows a schematic, partially sectioned representation of a further embodiment of the electro-optical module 20 of the fastex binder. In this case, the base body 28 of the electro-optic module 20 is bent generally S-shaped in order to create the flexibility required to produce the spring 46 . Corresponding flexible zones 44 result in particular in the bending areas.

In the front region of the base body 28, which is bent downward in FIG. 2, a corresponding electro-optical component 30, in particular an optoelectronic chip or the like, is provided again. In this area, the optical input or output 22 to be aligned with the ferrule 16 (cf. FIG. 1) is also provided.

In the upper region 48 of the generally S-shaped base body 28 of the electro-optical module 20 there is space for further circuits 32 associated with the electro-optical component 30 , which can be bonded chips and / or the like, for example.

In the lower region of the generally S-shaped base body 28 of the electro-optical module 20 , for example, electrical connection contacts 24 are again provided. In particular, SMD connections are again conceivable.

Otherwise, this electro-optical module 20 shown in FIG. 2 can be constructed again in the manner described with reference to the embodiment according to FIG. 1.

The illustrated embodiment of the base body in FIG. 1 is intended here only as an example to clarify the resilient area. The illustration in FIG. 2 is primarily intended to illustrate the functionality again.

It is particularly important that the optics sits in the front area and is located opposite the ferrule. The flexible part of the basic body is also crucial. To implement practical embodiments, the following is possible, for example:

• 1. a flexible MID as described
• 2. a connection of two rigid bodies with a flexible Lei terplatte (FCB, flexible circuit board)
• 3. a connection with an anisotropically conductive rubber, wherein the conductivity is only given in one direction, e.g. B. as in an LCD display

Of importance is u. a. the possibility of an electronic chip directly to bond to the component. This can ver the function of the component be changed, while maintaining all mechanical dimensions sions.

The claims in the claims are of particular advantage Chen specified optoelectrics, flex range and PCB connection.  

Reference list

10th

Connectors

12th

Connector part

14

Connector part

16

Ferrule

18th

Light guide

20th

electro-optical module

22

optical input or output

24th

electrical connection contacts

26

optical chamber, receptacle

28

Basic body

30th

electro-optical component, optoelectronic chip

32

Circuits

34

Conductor tracks

36

Stop surface

38

Stop surface

40

Transverse wall

42

opening

44

flexible zones

46

feather

48

Circuit area
z axial or mating direction

Claims (14)

1. Plug connector ( 10 ) for light guide ( 18 ) with two compound connector parts ( 12 , 14 ) which are provided with at least one optical Fer rule ( 16 ) or at least one electro-optical module ( 20 ), which on the one hand has at least one optical one Input and / or output ( 22 ) and on the other hand in particular electrical connection contacts ( 24 ), wherein when the connector is plugged together ( 12 , 14 ) the ferrule ( 16 ) the optical output or input ( 22 ) of the electro-optical module ( 20 ) opposite, characterized in that the electro-optical module ( 20 ) has an at least partially flexible base body ( 28 ) which is so compressible and / or deformable to produce a spring force that its optical input or output ( 22 ) has End is resiliently loaded in an end position in which the optical input and output ( 22 ) of the ferrule ( 16 ) is opposite. 2. Connector according to claim 1, characterized in that the electro-optical module ( 20 ) is formed on the basis of a three-dimensional injection molded circuit carrier (MID). 3. Connector according to claim 1 or 2, characterized in that the electro-optical module ( 20 ) comprises a device carrier in the injection-molded scarf (MID) integrated or mounted on this electro-optical one-chip component ( 30 ). 4. Connector according to one of the preceding claims, characterized in that the electro-optical module ( 20 ) is formed on the basis of an injection-molded circuit carrier (MID), which is designed as an SMD component. 5. Connector according to claim 3 or 4, characterized in that further the electro-optical component ( 30 ) associated circuits ( 32 ) in the injection molded circuit carrier (MID) are integrated or attached to this. 6. Connector according to one of the preceding claims, characterized in that the electro-optical module ( 20 ) is vorgese hen as a transceiver module. 7. Connector according to one of the preceding claims, characterized in that the base body ( 28 ) of the electro-optical module ( 20 ) is bent at least in regions generally zigzag shape. 8. Connector according to one of the preceding claims, characterized in that the base body ( 28 ) of the electro-optical module ( 20 ) is bent at least in regions generally S-shaped. 9. Connector according to one of the preceding claims, characterized in that the electro-optical module ( 20 ) at its end having the optical input or output ( 22 ) is provided with a plug-in receptacle ( 26 ) into which the ferrule ( 16 ) can be inserted is. 10. Connector according to one of the preceding claims, characterized in that the optical input or output ( 22 ) having the end of the electro-optical module ( 20 ) in its end position on one of the connector part ( 14 ) associated, transverse to the axial direction (z ) abutting stop surface ( 36 ). 11. Connector according to one of the preceding claims, characterized in that in the mated condition with the ferrule ( 16 ) ver seen connector part ( 12 ) on a transverse to the axial direction (z) end, the other connector part ( 14 ) assigned to the stop surface ( 38 ) is present. 12. Connector according to one of the preceding claims, characterized in that the ferrule ( 16 ) is fixed in the relevant connector part ( 12 ). 13. Connector according to one of the preceding claims, characterized in that the provided with the electro-optical module ( 20 ) connector part ( 14 ) is designed as a header. 14. Connector according to one of the preceding claims, characterized, that it is designed as a hybrid connector.