DE4013630A1 - Opto electric modulator for manufacture - has groove for receiving fibre connecting components - Google Patents

Abstract

A modul has a cover (2) and silicon base (1). Optoelectronic, electronic and optical components (8, 10, 11, 12) are arranged on the surface of base (1). A groove (3) is provided in thee base (1) to receive a light wave conducting fibre (9). The groove (3) extends from an edge of the base (1) to at least one optoelectronic component (10, 11). Groove (3) has a widened region (5) between the edge of base (1) and optoelectronic components (10, 11). A corresponding groove (13) is provided on the underside of the cover (2). In cover (2) is an opening (6) in the region of the widened part (5) of grooves (3, 13) and an opening (7) where the optoelectronic components are set in the base (1). USE/ADVANTAGE - For optical data transmission system. Has improved hermetic sealing and more efficient assembly.

Description

The invention relates to an optoelectronic converter module according to the preamble of claim 1 and a method its manufacture.

In the optical transmission of messages via lightwave ter (LWL) fibers become electro-optical transmission and reception modules, d. H. optoelectronic converter modules required.

With the current micromechanical construction, the individual subunits, such as B. laser diode, lens (s), light conductive fiber, on their intermediate supports in a metal housing combined individually into a module with high adjustment effort set. The finished module is then soldered or laser welding hermetically sealed.

More advantageous because of less adjustment effort and a so-called is more suitable for mass production hybrid integrated construction on silicon. Such an op table transmission and reception module is in the older Deut described patent application, official act P 38 09 396.0. This optoelectronic converter module has an Si carrier part on the surface of which the electro-optical and / or optoelectric and optical components are arranged. There is in the surface of the Si carrier part a groove is provided to accommodate an optical fiber connection fiber, starting from an edge of the Si carrier part a recess for receiving a focusing component up to at least one electro-optical and / or optoelek tric component extends.  

The invention has for its object in an op toelectronic converter module of the type mentioned at the beginning the adjustment and fixing effort for the individual optical and to reduce optoelectronic components whose improve hermetic encapsulation and rational To enable production of the modules.

This object is achieved by an optoelectro African converter module with the features of claim 1 or by a method having the features of claim 9 solved.

Advantageous refinements or developments of the Erfin are subject to additional claims.

The advantages achieved with the invention are in particular the fact that the optoelectronic converter module in addition to its technical suitability due to low adjustment wall, hermetic encapsulation against the ambient atmosphere and distinguishes rational production.

The hermetic encapsulation is achieved by using a sili ziumsubstrat or on the Si carrier part with the optical and optoelectronic components netes cover part, preferably also made of silicon, useful by means of a glass solder. For example The cover part has wise laser light in and out a suitable implementation or a window. This through guidance becomes self-adjusting and without an intermediate bracket FO connection fiber (pigtail) melted or glued.

Due to the high precision of the anisotropic etching (preferred etching) is achieved in that the optical components on the Silicon substrate (Si carrier part) to each other correctly positio are nated and no longer need to be adjusted.  

Using an off shown in the figures of the drawing the invention is explained in more detail. Show it

Fig. 1 shows the schematic configuration of a transmission module in hybrid intregrierter construction,

Fig. 2 is a plan view of the Si carrier part of the transmitter module and

Fig. 3 is a plan view of the cover part of the transmitter module.

The illustrated in FIGS. Opto-electronic transducer module is a transmitter module and consists essentially of a Si support part 1, on the surface as an electro-optical Kom component a laser diode 10, as an opto-electrical component, a monitor diode 11, as well as optical components, a ball lens 8, a fiber optic Fiber section 9 and the fiber optic connection fiber 15 are arranged. In the surface of the carrier part 1 is to receive the exposed end of the fiber optic connection fiber 15 and the fiber section 9, a groove 3 is seen, which is preferably V-shaped. The fiber section 9 is used in the finished module as a bushing for the laser light. The groove 3 has a slight expansion or extension 5 in the middle so that the fiber section 9 can be sealed all around. The groove 3 continues in the narrowed shape up to the rectangular recess 4 in this example, which serves to receive the ball lens 8 . This recess 4 is followed by a narrow continuation of the groove 3 , via which the laser diode 10 is expediently dissolved. Above the reflecting end edge of this groove 3 , the monitor diode 11 is soldered with the optically active surface facing downwards. The electrical connections of the two diodes 10 , 11 are made via the contacts 12 and the connecting wires 18th

The Si carrier part 1 is metallized on both sides in order to make electrical connections 12 and to be able to solder the carrier part 1 onto a lead frame 17 , or metalized on one side if it is glued to the lead frame 17 .

The cover part 2 shown in FIG. 3 fulfills two functions. First, it is intended to fix the ball lens 8 and the fiber optic section 9 . For this purpose, on the underside of the lid part 2, a rectangular recess 4 and a groove 13 with he extension 5 as in the carrier part 1 is etched. That is, the groove 3 in the carrier part 1 is at least symmetrical with the groove 13 in the cover part 2 , the symmetry of which may, however, differ from one another. Second, the cover part 2 is to seal the module hermetically. For this purpose, a suitable glass solder is thinly applied over the entire surface of the underside of the cover part 2 in order to glaze the cover part 2 and the carrier part 1 with one another. In order to seal the fiber section 9 tightly, a hole or a first opening 6 is etched through from the upper side of the Dec part 2 and filled with glass solder. After the optical parts and the cover part have been glazed in, the module housing is soldered or glued to the leadframe 17 .

The second opening 7 in the cover part 2 serves to be able to solder the laser diode 10 and the monitor diode 11 . In the end, this opening is preferably closed tightly by soldering on a metal cover 16 .

The fiber optic connection fiber (pigtail) 15 is butt-coupled to the fiber section 9 , fixed with a cover 14 and glued.

The joint can also be spliced optionally by melting. To relieve the strain, the coating of the fiber optic fiber 15 is glued onto the leadframe 17 and / or crimped with two tabs of the leadframe 17 .

The finished module is covered with plastic for further protection splashes or pours.  

The module structure according to the invention has the essential purpose part that many of the manufacturing steps, such as etching, metallization the whole wafer and adjust it are free.

The further manufacturing or process steps, such as soldering on the leadframe, soldering the monitor diodes and the lasers, Laser positioning, fixing the connecting fiber, closing the modules, artificial aging (burn-in) and qualifications, take place in the bar association or in the association of a film tape. The modules are only separated for the final examination. This enables cost-effective production.

Claims (9)

1. Optoelectronic converter module for the optical Nachrich transmission in optical fibers, with a closed part of the cover and a Si-covered part covered with it, on the surface of which the optoelectric, electrical and optical components are arranged, and in which to receive an optical fiber connecting fiber Groove is provided, which extends from an edge of the Si carrier part to at least one optoelectric component, characterized in that the groove ( 3 ) between the edge of the Si carrier part ( 1 ) and an optoelectric component ( 10 , 11th ) has an expansion point ( 5 ) that the Si carrier part ( 1 ) facing the underside of the cover part ( 2 ) has a groove ( 3 ) in the carrier part ( 1 ) at least in its course symmetrical groove ( 13 ), and that in the cover part ( 2 ) from the upper side of a first opening ( 6 ) in the region of the extension ( 5 ) of the grooves ( 3 , 13th ) and a second opening ( 7 ) in the area of the support part ( 1 ) to be installed electro-optic components ( 10 , 11 ) is introduced. 2. Optoelectronic converter module according to claim 1, characterized in that in the grooves ( 3 , 13 ) in front of the electro-optical component ( 10 ) a recess ( 4 ) for receiving a focusing component ( 8 ) is provided. 3. Optoelectronic converter module according to claim 1 or 2, characterized in that for closing the cover part ( 2 ) Ver see a metal disc ( 16 ) is easily seen. 4. Optoelectronic converter module according to one of Ansprü che 1 to 3, characterized in that the cover part ( 2 ) consists of silicon. 5. Optoelectronic converter module according to one of claims 1 to 4, characterized in that the grooves ( 3 , 13 ) formed symmetrically to one another in the Si carrier part ( 1 ) and in the cover part made of silicon ( 2 ) are introduced by anisotropic etching and the two Openings ( 6, 7 ) in the cover part ( 2 ) are etched through. 6. Optoelectronic converter module according to one of claims 1 to 5, characterized in that the cover part ( 2 ) with a glass solder layer applied to its entire surface on the underside of the Si carrier part ( 1 ) is glassed. 7. Optoelectronic converter module according to one of claims 1 to 6, characterized in that the extension point ( 5 ) of the grooves ( 3 , 13 ) and the first opening ( 6 ) located in this area in the cover part ( 2 ) are filled with glass solder, so that in the area of the extension ( 5 ) extending fiber section ( 9 ) of the fiber optic connection fiber ( 15 ) is embedded in glass solder. 8. Optoelectronic converter module according to one of Ansprü che 1 to 7, characterized in that the fiber optic connection fiber ( 15 ) to the fiber section ( 9 ) butt-coupled and fixed with a cover ( 14 ), and that for strain relief, the envelope of the fiber optic Connection fiber ( 15 ) on the lead frame ( 17 ) is attached. 9. A method for producing an optoelectronic wall module according to one of claims 1 to 8, characterized in that the grooves ( 3 , 13 ) with their on a Si wafer in the wafer assembly in a plurality of carrier parts ( 1 ) and cover parts ( 2 ) Wells ( 4 ) and extensions ( 5 ) and the openings ( 6 , 7 ) in the Dec kelteile ( 2 ) are simultaneously anisotropically etched in or through that the carrier parts ( 1 ) to form the electrical connections ( 12 ) and for attachment are metallized on a leadframe ( 17 ) at the same time, that the carrier parts ( 1 ) with the cover parts ( 2 ) and the optical components ( 8 , 9 ) are glazed in at the same time, and that the further steps of soldering onto the leadframe ( 17 ), the soldering and positioning of the optoelectric components ( 10 , 11 ), the fixing of the fiber optic connection fibers ( 9 , 15 ), the closing of the modules, the artificial aging and the qualification in the bar be made in association or in association with a film tape.