DE8804518U1 - Fiber optic coupler - Google Patents

Description

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The invention relates to a fiber optic coupler which splits and couples the light from one or more fiber optics (fiber optic inputs) into one or more fiber optics (fiber optic outputs), whereby the surfaces of the fiber optics which are joined together are adjusted and fixed to one another.

Optical fiber couplers are used to split or couple the light from one optical fiber into two or more output optical fibers. In optical communications and optical fiber sensor technology, so-called 3 dB couplers are of particular importance. These have two fiber inputs and two fiber outputs and split an input light output evenly between both output optical fibers. For coupling, the successive components on the output or input surfaces to be coupled are provided with fiber disks or surfaces instead of glass end windows or similar, the outer surfaces of which are brought into as close contact as possible. In this way, for example, any image shell can be created by grinding the surface to a specific shape.

The so-called grinding process and the shifting process are known to date for the manufacture of optical fiber couplers. In the melting process, two optical fibers are melted together so that the light can pass into the other optical fiber. The disadvantage is that the refractive index structure of the optical fiber is changed by the melting process, which can lead to increased light losses. In addition, the light distribution in the two output optical fibers is not uniform in principle, i.e. they have a different mode structure, which is disruptive in many applications. So-called grinding couplers

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In contrast, they have laterally ground fibers that are aligned with each other and fixed with an adhesive. The disadvantage of such a fiber optic coupler is that there is an optically transparent adhesive or an immersion liquid between the grinding surfaces in order to fill the smallest air gaps on the coupling surface. This also leads to a non-uniform refractive index.

It is therefore the object of the present invention to improve the optical fiber coupler in such a way that the interlocking optical fiber surfaces are in as close contact with one another as possible without having to accept a non-uniform refractive index at the contact surface.

This task is carried out in the above-mentioned Optical fiber coupler solved by the fact that the

lying optical fiber surfaces are cracked*

The term "bonding" refers to the rigid connection of two or more optical parts to one another by molecular adhesion forces which become effective between two polished and extremely clean surfaces when their mutual distance has become zero due to the air gap being squeezed out. This requires, as is well known, that in addition to the extreme cleanliness of both surfaces, conditions such as the radii of curvature of both surfaces are exactly the same, i.e. the fit of both surfaces matches to within fractions of a strip width.

According to a further development of the invention, the light guides are embedded in a quartz block, preferably glued in, e.g. using epoxy resin. The

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According to a further embodiment of the invention, the quarry block has a cuboid shape and preferably has a size of 20 mm x 5 mm x 5 mm or 10 mm x 3 mm x 3 mm.

If the coupler is to be used for Mohöde light transmission, it is sufficient that the two fiber cores are located close to each other in the coupling area, which can be achieved by grinding the optical fibers in a radial direction close to the fiber core.

In a coupler for multimode optical fibers, however, the grinding area must be designed so that the fiber cores touch each other. In a 3 dB coupler, the fibers in the coupler waist are each ground to half their diameter or cross-section.

According to a further embodiment, the optical fiber coupler consists of two quartz block halves, in each of which one of the optical fibers is inserted in a groove with _a non-linear, preferably partially circular groove base.

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. ground light guide with the flat quartz block

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The thickness of the conductor or the groove base is preferably 30 to 50 mm, the groove width is between 100 to 300 pm and preferably corresponds to the thickness of the light conductor.

»The groove described is so deep that the fiber is completely accommodated in it and the fiber surface is flush with the quartz block surface. This can be achieved in practice by

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surface of the quartz block, which initially completely covers the light guide, is ground down until the light guide is ground to the required length on the side. It is important to ensure that the surface quality is so good that the principle of wringing is possible, as is known from the state of the art. Wringing is already used, for example, in the manufacture of gas lasers, where the optical windows are wringed to close the laser tube. The connection between two surfaces, for example made of quartz or glass, is extremely strong without adhesive, since the electrostatic attraction forces of the atoms from the opposite surfaces are effective themselves. The wringing connection has proven to be extremely stable mechanically and temperature-resistant. Furthermore, this connection is less sensitive to temperature than the adhesive connections discussed at the beginning.

Embodiments of the invention are shown in the drawings. Hs show

Fig. 1 the basic coupling of two light guides, Fig. 2 a light guide with side grinding,

Fig. 3 a fiber optic coupler in which the fiber optics are embedded in quartz block halves,

Fig. 4 a quartz block half with inserted light guide in perspective view and

Fig. 5 three different sectional views of the light-to-conductor coupler according to Fig. 4.

The light guides 11/12 shown in Fig. 1 each have öVäle produced by lateral grinding

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Interfaces 11c and 12c, which are bound together by adhesive forces. The light guide shown in Fig. 1, for example, has an input 11a, whereby the light incident there is divided into the outputs 11b and 12b.

In order to create such a connection, one must start with a light guide as shown in Fig. 2. The flexible light guide is slightly curved and ground at the sides to form surface 11c. If a second light guide is ground in a similar way, the ground surfaces in question can be pressed together.

However, problems arise because the two optical fibers to be coupled must be aligned (adjusted) in a position in which the cut surfaces 11c and 12c are positioned exactly. This problem is solved in a simple manner using the optical fiber coupler shown in Fig. 3 to 4 or its halves. The finished optical fiber coupler is shown in Fig. 5 and consists of two cuboid halves 13 and 14, each of which accommodates an optical fiber 11 and 12, in such a way that the optical fiber cut surfaces 11c and 12c are held together by wringing.

The manufacture of such an optical fiber coupler is best understood from Fig. 4 to 7. If one starts with a quartz block 13 or a quartz block half, a groove with a width d is first milled into it, which corresponds to the diameter of the optical fiber 11. The groove has a partially circular course and can initially be so deep that even the area above the groove apex

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The lying light guide body 11 does not protrude from the quartz block surface 13a. If the quartz block surface 13a is now ground flat, the light guide boundary surface is finally reached. Grinding is now continued until at least the light guide fiber core is reached, preferably the light guide is ground down to half its diameter. After grinding, the quartz block half surface 13a and the surface 11c of the light guide 11 are inevitably in one plane. The light guide also emerges from the quartz block on the side surfaces 13b and 13c. A second quartz block with an inserted light guide is manufactured in a similar manner. The two quartz blocks must now be wrought together in the manner shown in Fig. 3. It goes without saying that the coupler halves have the required surface quality and are precisely adjusted to each other. The important thing here is to set the desired degree of coupling and a minimum attenuation without the surfaces touching each other beforehand. Once the adjustment is complete, the surfaces are blasted together; the achievable coupler attenuation and the coupling/to-to-pressure ratio are practically independent of temperature, which is extremely important for many tasks, for example in optical sensors. It is also advisable to coat the edge of the adhesive surface with a protective varnish to prevent water or oil from penetrating the adhesive surface between the two blasted parts.

The optical fiber coupler is a coupler for so-called single-mode optical fibers or polarization-maintaining single-mode optical fibers or a coupler for multi-mode fibers.

Claims (1)

HAMBURG, THE 5.4.1988 1. Optical fiber coupler that combines the light from one or more optical fibers (optical fiber inputs) splits or couples into one or more light guides (light guide outputs), whereby the adjacent light guide fiber surfaces are adjusted and fixed against each other, characterized in that the adjacent light guide fiber surfaces (11c, 12c) are snapped together. 2. Optical fiber coupler according to claim 1, characterized in that the optical fibers (11, 12) are embedded in a quartz block or quartz block halves (13, 14). 3. Optical fiber coupler according to claim 2, characterized in that the optical fibers (11, 12) are glued into the quartz block or the quartz block sleeves (13, 14), preferably by means of epoxy resin. 4. Optical fiber coupler according to claim 2 or 3, characterized by a cuboid-shaped quartz block (13,14) preferably of 20 mm x 5 mm x 5 mm up to 10mm X 3mm x 3mm. 5. Optical fiber coupler according to one of the claims 1 to 4, characterized in that the adjacent optical fibers (11, 12) are ground in the radial direction, at least up to the vicinity of the fiber core. 6. Optical fiber coupler according to claim 5, characterized in that the adjacent optical fibers (11, 12) in the coupler waist (15) are each ground to half their diameter (d). 7. Optical fiber coupler according to one of the claims 1 to 6, characterized in that each light guide (11, 12) is inserted or rests in a groove (16) with a groove base (16a) of non-straight cross-section in a quartz block half (13) in such a way that the fiber surfaces (11c, 12c) of the laterally ground light guides are flush with or aligned with the flat quartz block half surface (13a) and the corresponding quartz block halves (13, 14) lie on top of one another. 8. Optical fiber coupler according to claim 7, characterized in that the groove base (16a) is partially circular in cross section. 9. Optical fiber coupler according to claim 8, characterized in that the bending radius of the optical fiber (11) or the groove base (16a) is 30 to 50 mm. 10. Optical fiber coupler according to one of claims 7 to 9, characterized in that the groove width (b) is between 100 and 300 µm, preferably corresponds to the thickness (d) of the optical fiber (11, 12). &iacgr;&iacgr; «* ·· S it fi > # ·»* &diams; tat «< ti 17, Optical fiber coupler according to one of claims 7 to 10/ characterized in that it is a coupler for so-called monomode optical fibers or polarization-maintaining monomode optical fibers* 12. Optical conductor coupler according to one of claims 7 to 11/ characterized in that it is a coupler for multimode fibers»