WO2008058505A1 - Optical waveguide coupling with a magnetic coupling - Google Patents

Abstract

The invention relates to an optical fiber coupling, comprising a first and a second connector housing (12, 18) for receiving and affixing at least a first and at least a second optical fiber (14, 20), wherein the optical fibers (14, 20) each have fiber ends (16, 22) that can be connected to each other in a light-conducting manner. According to the invention, the connector housings (12, 18) are connected to each other by means of a magnetic coupling (72) such that the fiber ends (16, 22) of the optical fibers (14, 20) to be connected come to rest flush on top of each other. The magnetic coupling (42) comprises a first magnetic element (32) arranged in a recess (64) of a first housing element (28). The first housing element (28) is connected to the first connector housing (12) by means of a fixing device (60).

Description

 FIBER OPTIC CONNECTOR WITH MAGNETIC COUPLING

The invention relates to an optical waveguide coupling consisting of a first and a second connector housing for receiving and fixing at least a first and at least one second optical waveguide, wherein the optical waveguides each have fiber ends, which are to be connected in a light-conducting manner.

Such optical fiber clutches are known. So, for example, so-called SMA couplings are used, but where it is not yet possible to reproducibly connect two optical fibers, since the signal of the light source is attenuated to different degrees. The reason for this lies in the different strength of the respective screw the optical waveguide with the corresponding connector housings and at the respective different angles of rotation. In addition, the screwing and unscrewing the known fine thread is complex and there is also the risk of contamination or heat in the delay of the screw the risk of damage to the optical waveguide. In addition, it is possible to weld optical fibers. However, this principle of safe and low-loss connection method is also complex and therefore costly.

Object of the present invention is therefore to provide an optical fiber coupling of the type mentioned, which allows a non-complex, fast and secure connection of two optical fibers.

This object is achieved by an optical waveguide coupling according to the features of claim 1.

Advantageous embodiments of the invention are described in the respective subclaims. An optical waveguide coupling according to the invention consists of a first and a second connector housing for receiving and fixing at least one first and at least one second optical waveguide, the optical waveguides each having fiber ends, which are to be connected in a light-conducting manner. According to the invention, the plug housings are connected to one another by means of a magnetic coupling, such that the fiber ends of the optical waveguides to be connected come to rest on one another in a reproducibly flush manner. In the reproducible flush connection, the fiber ends are always in high accuracy in all three spatial directions (axial, radial and azimuthal) equal to each other.

By means of the optical waveguide coupling according to the invention, on the one hand, a non-complicated type of connection of two optical waveguides is ensured, in which unwanted twisting or shifting of the fiber ends is avoided. In addition, the connection can be made quickly and safely.

In an advantageous embodiment of the invention, the magnetic coupling comprises at least one arranged in or on the first connector housing first magnetic element and at least one corresponding, arranged in or on the second connector housing second magnetic element, wherein the magnetic elements have a different magnetic polarity and are aligned with each other. In addition, it is possible that, according to a further embodiment, the magnetic elements are arranged in recesses of a first and second receiving element, wherein the first receiving element is arranged on the first connector housing and the second receiving element on the second connector housing, such that the magnetic elements aligned with each other are. By the aforementioned embodiments of the invention, in turn, a non-complex connection of the optical waveguides is ensured with each other.

In a further advantageous embodiment of the optical waveguide coupling according to the invention at least two dowel pins are arranged on or in the first connector housing, wherein the dowel pins are insertable and positionable in a corresponding recess in or on the second connector housing. In another embodiment, it is also possible that at least two dowel pins are arranged in the first receiving element, wherein the dowel pins are then einfuhrbar and positionable in a corresponding recess in the second receiving element. Through the formation of dowel pins which can be inserted and positioned in corresponding recesses, an exact and reproducible positioning of the fiber ends of the optical waveguides to be connected to the optical waveguide is ensured. In addition, the connection can be carried out quickly and safely.

In a further advantageous embodiment of the invention, the magnetic elements are formed as permanent magnets. As a result, a simple and inexpensive production of the magnetic coupling is possible. According to one embodiment, the magnetic elements are designed as ring elements. This configuration makes possible a very secure connection of the two plug housings to one another or the two receptacle elements of the plug housings.

According to a further advantageous embodiment of the invention, the magnetic ele- ments are designed as electromagnets. This results in a switchability of the magnetic coupling, which allows an active connection and disconnection of the optical fiber coupling.

In a further advantageous embodiment of the optical waveguide coupling according to the invention, the first connector housing or the first receiving element at the second plug housing or the second receiving element facing plug end at least one recess for receiving at least one formed in the plug end of the second plug housing or the second receiving element projection. According to a possible embodiment of the invention, the recess are formed as a circumferential shoulder and the projection as a circumferential collar. By this design options further secure positioning of the two connector housing is guaranteed each other.

In a further advantageous embodiment of the invention, a ferrule of the first optical waveguide protrudes from the first connector housing or the first receiving element. from, wherein the fiber end of the first optical fiber terminates flush or non-flush with the end face of the ferrule. The formation of a ferrule significantly reduces the risk of damaging the fiber ends of the optical waveguide.

Further advantages, features and details of the invention will become apparent from the following description of a diagrammatically illustrated exemplary embodiment. It shows

Figure 1 is a sectional view of the optical waveguide coupling according to the invention; and

FIG. 2 shows a schematic representation of the optical waveguide coupling according to FIG. 1.

1 shows a sectional view of an optical waveguide coupling 10 consisting of a first and a second connector housing 12, 18 for receiving and fixing each of a first and a second optical waveguide 14, 20. It can be seen that the optical waveguides 14, 20 by means of fasteners designed as screws 24, 26 are connected to the respective connector housing 12, 18. The first optical waveguide 14 is arranged in an opening 78 of the plug housing 12. The second optical waveguide 20 is arranged in a through opening 80 of the second connector housing 18. The optical waveguides 14, 20 each have a fiber end 16, 22, which are to be connected in a photoconductive manner by means of the optical waveguide coupling 72. The fiber ends 16, 22 are in each case surrounded by a plug head 40, 42, wherein the plug heads 40, 42 are used for further attachment of the optical waveguide 14,20 in the first and the second connector housing 12, 18. The plug heads 40, 42 are each screwed in an internal thread 48 of the connector housing 12, 18.

It can be seen that the plug housings 12, 18 are connected to one another by means of a magnetic coupling 72, such that the fiber ends 16, 22 of the optical waveguides 14, 20 to be connected ultimately end up flush with one another. The magnetic coupling 42 comprises a first magnetic element 32, which is arranged in a recess 64 of a first receiving element 28. The first receiving element 28 is connected to the first connector housing 12 by means of a fastening device 60. Of the way The magnetic coupling 72 includes a second magnetic element 34, which is arranged in the illustrated embodiment in a recess 66 of a second receiving element 30. The second receiving element 30 is connected to the second connector housing 18 via a fastening device 62. The magnetic ele- ments 32, 34 are formed in the embodiment as ring magnets with different magnetic polarity. In addition, it can be seen that the magnetic elements 32, 34 are aligned with each other. The magnetic elements 32, 34 may be glued in the recesses 64, 66. Other mounting options are conceivable.

In addition, it is possible that the magnetic elements 32, 34 can be aligned by means of adjusting screws 50, 52, which engage on an inner side of the magnetic elements 32, 34.

In the illustrated embodiment, the optical fiber coupling 10 also has three dowel pins 44 (see also FIG. 2), which are arranged in the first receiving element 28. The dowel pins 44 can be inserted and positioned in corresponding recesses 46 in the second receiving element 30. The dowel pins 44 can be firmly connected to the first receiving element 28. But it is also possible to store the dowel pins 44 resiliently. In addition, it is advantageous to bend or chamfer the dowel pins 44 at least peripherally on their end faces facing the second plug housing 18 so that they can be inserted into the recesses 46 relatively easily.

For secure and exact positioning of the first connector housing 12 with the second connector housing 18, the first receiving element on the second connector housing 18 and the second receiving member 30 facing the plug end 74 has a circumferential shoulder 54 for receiving one in the plug end 76 of the second connector housing 18 and of the second receiving element 30 formed circumferential collar. It can be seen that thereby an end face 68 of the first receiving element 28 facing the second plug housing 18 comes to rest on an inner surface 70 of the second receiving element 30 formed by the circumferential collar 56. FIG. 1 also shows that the fiber end 16 of the first optical waveguide 14 is arranged within a ferrule 36 and protrudes from the first connector housing 12 or the first retaining element 28. In the exemplary embodiment illustrated, the fiber end of the optical waveguide 14 terminates non-flush with the end face 58 of the ferrule 36. But it is also possible that the fiber end 16 is flush with the first optical waveguide 14 flush with said end face 58 of the ferrule 36. The end face 58 of the ferrule 36 is also laterally rounded, so that the positioning and the insertion of the ferrule 36 in an end piece 38 of the second optical waveguide 20 is facilitated. In the illustrated embodiment, the fiber end 22 of the second optical waveguide 20 engages in a corresponding opening of the ferrule 36 of the first optical waveguide 14, so that the two fiber ends 16, 22 come to lie flush with each other.

Figure 2 shows a schematic representation of the optical fiber coupling 10 according to Figure 1. It can be seen how the two connector housings 12, 18 are positioned to each other, wherein the first connector housing 12, the first receiving element 28 for the first magnetic element 32 includes. One clearly recognizes the annular configuration of the first magnetic element 32. The same applies to the second magnetic element 34 (not shown). The plug housings 12, 18 are formed overall annular, other embodiments are also conceivable.

Furthermore, it becomes clear from FIG. 2 that the first optical waveguide 14 is connected to the plug housing 12 by means of a first fastening device 24. The second optical waveguide 20 is connected to the second connector housing 18 by means of a second fastening device 26. In addition, the connection of the second receiving element 30 with the second connector housing 18 is shown by way of example via a fastening device 62. Finally, the formation of the circumferential shoulder 54, which serves to insert the first plug housing 12 or the first receiving element 28 into the second plug housing 18 or the second receiving element 30, can also be seen. The three locating pins 44 and the ferrule 36 having the fiber end 16 of the first optical waveguide 14 project beyond the first connector housing 12 and the first receiving element 28, respectively.

Claims

claims

1. optical waveguide coupling consisting of a first and a second connector housing (12, 18) for receiving and fixing at least one first and at least one second optical waveguide (14, 20), wherein the optical waveguides (14, 20) each fiber ends (16, 22 ), which are to be connected in a light-conducting manner, characterized in that the plug housings (12, 18) are interconnected by means of a magnetic coupling (72) such that the fiber ends (16, 22) of the optical waveguides (14, 20) to be connected reproducibly flush with each other.

2. optical fiber coupling according to claim 1, characterized in that the magnetic coupling (72) at least one in or on the first connector housing (12) arranged first magnetic element (32) and at least one corresponding, in or on the second connector housing (18) arranged second magnetic element (34), wherein the magnetic elements (32, 34) have a different magnetic polarity and are aligned with each other.

3. optical fiber coupling according to claim 1 or 2, characterized in that the magnetic elements (32, 34) in recesses 64, 66) of a first and second receiving element (28, 30) are arranged, wherein the first receiving element (28) on the first Plug housing (12) and the second receiving element (30) on the second connector housing (18) is arranged, such that the magnetic elements (32, 34) are aligned with each other.

4. optical waveguide coupling according to one of the preceding claims, characterized in that on or in the first connector housing (12) at least two dowel pins (44) are arranged, wherein the dowel pins (44) in corresponding recesses (46) in or on the second connector housing (18) are insertable and positionable.

5. optical waveguide coupling according to claim 3, characterized in that at least two dowel pins (44) in the first receiving element (28) are arranged, wherein the dowel pins (44) in corresponding recesses (46) in the second receiving element (30) can be inserted and positioned.

6. optical fiber coupling according to one of the preceding claims, characterized in that the magnetic elements (32, 34) are permanent magnets.

7. optical fiber coupling according to one of claims 1 to 5, characterized in that the magnetic elements (32, 34) are ring magnets.

8. optical fiber coupling according to one of claims 1 to 5, characterized in that the magnetic elements (32, 34) are designed as electromagnets.

9. optical waveguide coupling according to one of the preceding claims, characterized in that the first connector housing (12) or the first receiving element (28) on the said second connector housing (18) and the second receiving element (30) facing the plug end (74) at least one recess (54) for receiving at least one in a plug end (76) of the second plug housing (18) or the second receiving element (30) formed projection (56) summarized.

10. optical waveguide coupling according to claim 9, characterized in that the recess (54) as a circumferential shoulder and the projection (56) are formed as a circumferential collar.

11. Optical waveguide coupling according to one of the preceding claims, characterized in that a ferrule (36) of the first optical waveguide (14) protrudes from the first connector housing (12) or the first receiving element (28), wherein the fiber end (16) of the first optical waveguide (14) is flush or non-flush with the end face of the ferrule (36).