DD235341B1 - ARRANGEMENT FOR COUPLING AN OPTOELECTRONIC TRANSMISSION ELEMENT TO A LIGHT WAVEGUIDE - Google Patents

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to a coupling arrangement for the connection of an optoelectronic transmission component, for example a semiconductor injection laser, to an optical waveguide, for example a glass fiber. Such coupling arrangements can be used as a structural unit in transmission modules of the optical fiber communication and as light sources for the optical fiber sensor technology.

Characteristic of the known state of the art

All known solutions have in common that transmission component and optical waveguides are adjusted to optimal coupling with each other and permanently fixed in this position.

The coupling arrangement is housed to protect against environmental influences in a closed housing and connected via a light guide bushing and various electrical connections to the external environment.

In all cases, the stability of the coupling over the life of the device under all operating conditions is required, which includes a corresponding strain relief for the optical waveguide.

The known coupling arrangements and manufacturing methods can be divided into two groups.

Thus, arrangements and methods are known in which the optoelectronic transmission component is mounted on a holder in the housing and the coupling-side end of the optical waveguide is adjusted and fixed directly to optimal coupling (DE-OS 3046415, G 02 B, 7/26).

Such solutions have the disadvantage that the process step of the coupling of transmission component and optical fiber must be realized within the component housing. This determines and considerably restricts the assembly process and for further processing steps to be used, such as hermetization, contacting. But also a rating

(eg load tests) of the optically-mechanically coupled system transmission component optical waveguide as the most essential subsystem of the transmission module is not possible independently of other subsystems.

The second group, the solutions can be assigned, in which the mutual adjustment of optoelectronic transmission component and optical fiber is realized by means of fiber guides or fiber mounts.

Arrangements are known in which highly precisely etched or milled grooves, which are aligned to the transmission component, are applied (DE-PS 2620158, G 02 B, 7/26).

It is also known to use very precisely manufactured housing parts, for which tolerances are required by 0.01 mm, for the reception of transmission component and optical waveguide (for example USP 4386821, G 02 B, 5/14). In this arrangement, the transmission component is mounted on the housing base and the optical waveguide secured in a central portion of the housing with a defined distance of its light entry surface to the annular end face of the housing, which determines the z-distance to the component. The housing bottom is in contact with the end face of the housing. The system is fixed by means of a cap.

The disadvantage of the latter solutions lies above all in the high production costs for the guide elements or their accuracy of fit to each other, which limits the achievable adjustment accuracy.

Also known is another device for connecting an optical fiber with an optoelectronic component arranged on a base (DE-PS 2930317, G02B, 7/26). It consists essentially of a surrounding the optoelectronic device, mounted on a base annular body and a fixable on this, which can be fixed in a pin, from this end outstanding fiber receiving ring.

This solution is also part of the type of arrangements in which additional holding and guiding parts are used for coupling the optical fiber with the optoelectronic component and the fixing of the two functional parts by fixed connection of a guide part of the fiber holder with a housing receiving the housing part. The coupling arrangement is here bound to a specific component housing, which itself is part of the coupling arrangement. With the coupling at the same time the hermetization of the component housing against environmental influences.

In arrangements designed in this way, high tolerance demands are made on the dimensions of the holding and guiding parts and the housing parts used for the coupling, derived from the required adjustment accuracy.

Object of the invention

The aim of the invention is to have a universally applicable arrangement for coupling an optoelectronic transmission component, preferably semiconductor injection laser, with an optical waveguide, preferably glass fiber, which ensures the most accurate and permanent alignment of the optical waveguide to the transmission component using simple means. In particular, the radiation emitted by laser diodes should be coupled as defined as possible into the optical waveguide and permit reproducible adjustment down to the sub-jum range.

Explanation of the essence of the invention

The invention has the object of providing a coupling arrangement in such a way that it is largely independent of the geometric dimensions, the type of construction and the type of transmission component and the type of light guide and the design of the coupling element. It should be mountable without fundamental change in different component housings, in particular in the specified by the IEC standard (No.47 / 850, July 83) hermetic DIL housing and largely adapted to different user needs in the housing design.

The object is achieved by a coupling arrangement which consists essentially of an intermediate carrier, on which the optoelectronic component is mounted, and a fiber holder, in which the optical waveguide is embedded.

According to the fiber holder frontally fixed to the intermediate carrier at its parallel to the light exit surface of the device extending surface directly connected, such that this coupling arrangement forms a fixed self-contained unit and as such in a component housing of the desired type can be mounted. The fiber holder is composed of a coupling outer tube and an inner tube of smaller diameter emerging from its rear end face, wherein the optical waveguide is hermetically and strain-relieved with its stripped end portion embedded in the outer tube and received with its subsequent sheathed portion in the inner tube.

The z-distance between the light exit surface of the component and the optical waveguide is predetermined by the position of the transmitting component on the intermediate carrier and the defined defined distance of the optical waveguide end to the contact surface of the fiber holder with the intermediate carrier.

So that the two-dimensional x, y-distance can be made sufficiently accurate by adjustment of intermediate carrier and fiber holder against each other, the principle to be complied with the requirement of the shape of the two holding parts, that the roughness or unevenness of the contact surfaces is less than the minimum z-distance (10 / im), d. H. they should just be polished or polished. It has proven to be advantageous to perform the case of optimal coupling effectiveness of transmission component and optical fiber fixed connection of the fiber holder to the intermediate carrier by laser pulse welding, whereby thermal stress on the functional parts is avoided.

In a further embodiment of the coupling arrangement, the outer tube of the fiber holder coupling side of its lateral surface is cut obliquely to the contact surface with the intermediate carrier to form a window.

As the main body of the fiber holder can be advantageously use a commercial tubular condenser bushing with extended inner tube.

The intermediate carrier is preferably a surface-finished copper block, which is adapted in size to the needs of handling and assembly in a given housing structure.

An inventively designed coupling arrangement has significant advantages over known solutions.

Without the use of additional holding and guiding parts and without the inclusion of parts of a component housing, the fiber holder is connected directly to the optoelectronic Sen'debauelement carrying intermediate carrier. The design of the coupling arrangement forming two functional parts allows adjustment and fixation in the tolerance range by 1 μΐη. The self-assembly performing coupling assembly can be tested as a whole on functionality and then installed in any device. The attachment within the housing via the intermediate carrier and is technologically completely uncritical, since the adjustment and fixation of optical fiber and component has already been completed with optimal coupling efficiency outside the case.

The assembly requires no complicated adjustment. Production-related deviations can be easily compensated by the mounting position of the coupling arrangement in the component housing. Another technological advantage is the fact that any number as described constructed and prepared intermediate carrier and hermetic fiber holders can be prepared, tested and pre-selected for a coupling arrangement. From this supply then pairings for optimal z-spacing between the component and the optical fiber can be formed.

embodiment

The invention will be explained in more detail using an exemplary embodiment. This is a coupling arrangement in which the optoelectronic component is a semiconductor injection laser and the optical waveguide is a 50 μm gradient fiber. The arrangement is intended for installation in a standard DIL housing according to IEC standard 47/850. In the accompanying drawings show:

1: an intermediate carrier with mounted component,

2 shows the longitudinal section of a fiber holder,

3 shows a completed coupling arrangement according to the invention,

4 shows the side view of a completed coupling arrangement with a sectional view of the fiber holder.

On the cuboid intermediate carrier 1 shown in FIG. 1, the semiconductor laser 2 is soldered at a distance of 5-10> m and with its optical axis approximately perpendicular to the contact surface 3 of the intermediate carrier 1 with the fiber holder 4.

Between the semiconductor laser 2 and the intermediate carrier 1 is a pad 5, z. B. Si or BeO. The structure of the semiconductor laser 2 can be done with either top or bottom p-n junction. The contact surface 3 is lapped and is characterized by low surface roughness and unevenness. The intermediate carrier 1 is made of copper and is provided with a surface coating, preferably galv. Ni.

The example shown in Fig. 2 of a fiber holder 4 is advantageously realized in this case with a standard commercial component. This is the tubular condenser _feedthrough KH 3.5 Α _Ί with extended inner tube 6. The use of this condenser _feedthrough offers several advantages. Since the part is manufactured with a standard technology and no find existing application case separate manufacturing tolerances are required, it is extremely inexpensive. Only the contact surface 7 with the intermediate carrier 1 is to be reworked by grinding or polishing and cut the coupling side expediently a "window" 8.

The glass body 9 between inner tube 6 and outer tube 10 serves as a thermal resistance to ambient temperature and reduces the thermal load that must be dissipated by a cooler in temperature-controlled operation of the laser 2 via the intermediate carrier 1. At the same time a potential separation of subcarrier 1 and the component housing, both of which must be in contact with the fiber holder in the installed state, given.

The outer tube 10 provides sufficient space to gluing the glass fiber 11 in this hermetically and to be soldered and its diameter, in view of expected shear forces and torques, the required stability of a spot weld fillet adapted.

The diameter of the inner tube 6 corresponds approximately to the outer diameter of the core, d. H. the protective jacket 12 of the fiber 11. The inner tube 6 can accommodate this and be squeezed to the strain relief of the fiber 10. The fiber end is preferably connected to a coupling element, e.g. Taper 13 provided and soldered to the z-distance significantly determining amount relative to the contact surface 7 with the intermediate carrier 1 reset in the outer tube 10 or glued.

For thermal and electrical insulation can be between the fiber hermetizing and fixing Lot 14 and the inner tube 6 is a layer of insulating material.

In Figure 3, an inventively assembled from complete intermediate carrier 1 and fiber holder 4 and adjusted for optimum coupling efficiency coupling arrangement is shown schematically. Here the position of the laser welding points 15 generated for the connection of intermediate carrier 1 and fiber holder 4 is indicated. Furthermore, a section of the wall 16 of a component housing is shown, through which the completed coupling arrangement is inserted for the purpose of mounting in the housing. On the after mounting from the housing projecting inner tube 6 of the fiber holder 4, a commercially available capacitor bushing 17 is pushed and soldered to said housing wall 16. It serves to seal the fiber holder 4 and allows the compensation of production-related bearing tolerances of the coupling arrangement in a component housing.

Claims (4)

1. Arrangement for coupling an optoelectronic transmission component with an optical waveguide, consisting of a component receiving the intermediate carrier and a fiber holder, in which the optical waveguide is firmly embedded with a distance of its coupling-side end of the end face of the fiber holder, which z the distance between the light exit surface of the Component and light entry surface of the optical waveguide, characterized in that the fiber holder is connected to the front side fixed to the intermediate carrier at its parallel to the light exit surface of the device surface directly so that this coupling arrangement forms an independent unit, wherein the fiber holder from a coupling side outer tube and one whose rear end side emerging inner tube of smaller diameter is composed and the optical waveguide hermetically and zugentlastet is embedded in this fiber holder. 2. Arrangement according to claim 1, characterized in that the outer tube of the fiber holder coupling side of its lateral surface to the contact surface with the intermediate carrier to form a window is cut obliquely. 3. Arrangement according to claim 1 and 2, characterized in that a commercially available tubular condenser bushing is used with extended inner tube as the main body of the fiber holder. 4. Arrangement according to claim 1 to 3, characterized in that the intermediate carrier is a surface-finished copper block.