DE3637746A1 - OPTO-ELECTRONIC CONVERTER WITH A CONNECTOR FOR A LIGHT-WAVE GUIDE - Google Patents

Abstract

An opto-electronic converter (30) has a connecting element (5) for a beam waveguide (12). Each transformer (1) is mounted in a transformer housing (32) in such a manner that the free terminal section (10) of a beam waveguide (12) is perpendicularly arranged to the corresponding optical measurement-vale receiving surface (4). Each beam waveguide (12) passes through a capillary through-hole (6) of an adapter (35) removably secured to a recess (33) of the transformer housing (35). Each beam waveguide (12) is secured by means of a clamp (34) to the terminal section (20) of the transformer housing (32) facing away from the transformer (1).

Description

The invention relates to an opto-electronic converter with a connector for an optical fiber.

In known connectors for detachable light waves conductor connections require the plug and connection bindings the adjustment and optical processing in or on Connector. Furthermore, there are plug-in and connection Connections of several parts, so that the whole Execution must be highly precise to add tolerances to avoid. In most cases, it is necessary to these plug and socket connections are the optical fibers glue in so that reuse is impossible is. A local adjustment and fixation comes regularly on great difficulty since these connections various conditions such as dusty reverse air or weather-related flaws Need to become.

The object of the invention is an opto-elek tronic converter with a connector for light waves create ladder with the easy way even under difficult conditions an optical fiber with a Converter can be brought into contact, with Mög possibility of reusing the optical waveguide ver binding their accuracy compared to known light waves conductor connections should be increased.

According to the invention, the object is achieved in that each transducer is stored in a transducer housing in this way, that perpendicular to the optical measurement surface of the free End portion of an optical fiber is arranged, the through a capillary-like opening in one Recess of the converter housing releasable but stationary ge stored adapter and tension-free on the End section of the converter housing facing away from the converter a clamp connection is attached.

Further refinements of the invention are in dependent Described claims and below using the example of in the drawings schematically illustrated opto-electronics tronic converter explained in more detail. It shows

Fig. 1 is an opto-electronic converter in a schematic plan view in section,

Fig. 2 shows the opto-electronic converter according to Fig. 1 in a schematic cross-sectional view,

Fig. 3 shows an adapter block for the opto-electronic converter of FIG. 1 in a plan view in partial section.

The opto-electronic converter 30 consists of a wall lergehäuse 32 , in which the transducers 1 are used so that when connected to the associated optical fibers 12, the electrical contacts 2 in the region of the end portion 19 of the optical fiber 30 are accessible for further electrical connections ( Fig. 1). The converter housing 32 consists of a lower housing part 36 and a housing cover 39 which is detachably connected to the lower housing part 36 by means of a screw connection 40 ( FIG. 2). In the lower housing part 36 , a recess 17 is formed for each transducer 1 , each of which is assigned an adapter 35 in a further recess 37 . The optical waveguide 12 is guided through the adapter 35 . In the area of the end portion 20 to the transducers 1 remote from the converter housing 32 is provided in this one clamping member 38, through which the light can be fiber cable is clamped 13 so that the optical fiber cable is guided free of stress in the adpater 35 and in the converter housing 32nd

The adapter 35 is formed as a one-piece fitting so that it rests in the recess 33 of the lower housing part 36 releasably but stationary. A capillary-like opening 6 is formed in the adapter 35 , through which the optical waveguide 12 is guided. Where the light wave conductor 41 facing away from end portion 9 of the adapter 35, the capillary aperture 6 may be in a conical He furtherance pass. 11 This facilitates the insertion of the optical waveguide 12 into the capillary-like opening 6 . It is also possible to replace a section of the capillary-like opening 6 with an enlarged opening 31 instead of the conical extension 11 , which also facilitates the insertion of the optical waveguide 12 . Both variants are shown schematically in FIG. 3.

If the optoelectronic transducer 30 is to accommodate a plurality of transducers 1 , it is possible to provide a corresponding number of recesses 17 in the transducer housing 32 for receiving the transducers 1 . In this case, the adapters 35 are also expediently connected to an adapter block 45 by means of a connecting web 44 , the recess 33 being adapted accordingly. The adapter block 45 can be manufactured as an injection molded part or the like, consisting of a larger number of adapters 35 . In this case, a material weakening 43 such as groove or the like is to be formed on the connecting webs 44 , which serves as a predetermined breaking point. As a result, the number of adapters 35 required in each case can be released from the adapter block 45 by a separating cut or by breaking off.

The section 42 of the adapter 35 which faces the optical waveguide outlet 41 is designed as a conical guide piece 46 which bears in a conical section 47 of the recess 33 . The conical section 47 is connected to the recess 17 via an opening 50 . The end faces 48 of each guide piece 46 are ground perpendicular to the longitudinal axis 49 of the respective capillary-like opening 6 flat. This ensures an optimal light transition between the optical waveguide outlet 41 and the optical measurement surface 4 of the respective transducer 1 .

Each transducer 1 is mounted in its recess 17 such that the optical measurement area 4 is assigned to the free end portion 10 of the optical waveguide 12 over the entire surface. Each transducer 1 can be fixed in position in the recess 17 by means of a connecting means 8 . As a connecting means 8 z. B. an adhesive layer or the like. Serve. By the attachment of the light wave conductor cable 13 by means of the clip member 38 is sicherge provides that the Meßwertaufnahmefläche 4 associated end portion of the optical waveguide 12 permanently applied to the optical Meßwertaufnahmefläche 4, so that a disturbance-free signal transmission is ensured. Ursäch Lich this is the curvature of the portion of the optical waveguide 12 and the optical fiber cable 13 located between the terminal member constructed as a adapter 35 5 and the clamping member 38, due to the specific elasticity of the optical waveguide 12 or light waves conductor cable 13 the free end portion 10 on the optical Meßwertaufnahmefläche 4 brings to the plant. In addition, the curvature of the optical waveguide 12 or optical waveguide cable 13 serves as a tension reserve for possible mechanical loads acting on the optical waveguide cable 13 outside the clamping member 38 .

Claims (9)

1. Opto-electronic transducer connected to a terminal member for an optical waveguide, characterized in that each transducer (1) is so mounted in a transducer housing (32), that perpendicular to the optical Meßwertaufnahmefläche (4) the free end portion (10) of the optical waveguide (12 ) is arranged, which is guided through a capillary-like opening ( 6 ) of an adapter ( 35 ) which is detachably but fixedly mounted in a recess ( 33 ) in the converter housing ( 32 ) and is tension-free on the end section ( 20 ) of the converter housing () which faces away from the converter ( 1 ). 32 ) is fastened with a clamp connection ( 34 ). 2. Opto-electronic converter according to claim 1, characterized in that the converter housing ( 32 ) from a lower housing part ( 36 ) with recesses ( 17 , 33 ) for receiving at least one converter ( 1 ) and at least one adapter ( 35 ) and with one at the end section ( 20 ) of the converter housing ( 32 ) arranged clamping member ( 38 ) which can be covered by means of a housing cover ( 39 ) which is detachably connected to the lower housing part ( 36 ) by means of screw connections ( 40 ). 3. Opto-electronic converter according to claim 1 and 2, characterized in that the optical waveguide ( 41 ) facing end portion ( 9 ) of the kapillararti gene opening ( 6 ) is designed as a conical extension ( 11 ). 4. Opto-electronic converter according to claim 1 to 3, characterized in that at least two adapters ( 35 ) are connected to form an adapter block ( 45 ), on the connecting webs ( 44 ) of which at least one material weakening ( 43 ) is designed as a predetermined breaking point. 5. Optoelectronic converter according to claim 1 to 4, characterized in that the optical fiber exit ( 41 ) facing section ( 42 ) of each adapter ( 35 ) is designed as a conical guide piece ( 46 ) which in a conical section ( 47 ) of the recess ( 33 ). 6. Optoelectronic converter according to claim 1, characterized in that the converter ( 1 ) in the recess ( 17 ) is mounted such that the optical measurement surface ( 4 ) is assigned to the free end section ( 10 ) of the optical waveguide ( 12 ) . 7. Opto-electronic converter according to claim 6, characterized in that the converter ( 1 ) in the recess ( 17 ) by means of a connecting means ( 8 ) is fixed in position. 8. An optoelectronic converter according to claim 7, characterized in that the connecting means ( 8 ) is formed as an adhesive layer or the like. 9. Opto-electronic converter according to claim 1, characterized in that the end face ( 48 ) of the guide piece ( 46 ) perpendicular to the longitudinal axis ( 49 ) of the capillary-like opening ( 6 ) is ground flat.