DE3823323C1 - Device for rotating an optical waveguide and application of this device - Google Patents

Abstract

When transmitting signals via optical waveguides, plug connectors are often needed. The attenuation of these plug connections is to be as low as possible. To determine the quality of the plug connections it is necessary to rotate the optical waveguides. A device is specified for rotating optical waveguides (1), whose end is accommodated in a sleeve (11), in a guide (5), the sleeve (11) being driven by a wheel (7) by means of friction. The wheel (7) is driven by the drive roller (8) by means of a traction mechanism (12), which drive roller is connected to the drive by means of a shaft. A spring (4) presses the wheel (7) against the sleeve (11). In addition, the axis of the wheel (7) is inclined against the axis of rotation of the sleeve (11) in such a manner that the sleeve (11) moves against a stop (6). Quality control of optical waveguides whose ends are accommodated in a sleeve. <IMAGE>

Description

The invention relates to a device for rotating a Optical fiber whose end in a sleeve, in particular in a connector pin or a lens cartridge, is housed around the longitudinal axis of the sleeve, which in a Guide is rotatably mounted, and an application of this Contraption.

When transmitting signals via optical fibers it is often necessary to use plug-in connections with each other or with further optical or to couple optoelectronic means. The through the Plug connections caused damping should be possible be small. It is important that as much light as possible from the first in the second optical fiber or in that optical or optoelectronic means is coupled. There the light is often not coaxial to the axis of the tube Optical fibers emerges, that means the quality of the Light transmission depends on the angle of rotation around the sleeve axis, become the optical fibers for testing around the sleeve axis turned.

EP 1 18 980 B1 describes a device for centering an optical fiber described in a pin, in which the optical fiber is rotated with the pin. The Pen is inserted into a rotatable clamping device  Machining tool used, light through the Optical fiber guided and the clamping device so long adjusted until the clamping device rotates with the pin and the optical waveguide a stationary light beam arises. Then a mating surface is machined, the is arranged concentrically to the light beam.

From US 46 73 245 is a device for Center an optical fiber in a connector pin known, in which the optical fiber is rotated with the pin becomes. The rotation takes place around the axis of an end part of the Pen instead. The rotation is done with the help of light coming in the optical fiber is coupled, observed. The emerging light describes a when rotating Circular motion. An adjustment of the optical fiber in the The pin can be made using set screws. Is the radius of the light described by the emerging light Circle zero, the adjustment is complete. The Rotation of the pin can be done manually, for example.

It is an object of the invention a device for rotating Optical fibers around a fixed axis and in a fixed one Specify position and an application for this device to show.  

This task is accomplished by a device Device with the features of claim 1 solved and regarding the application by an application according to Claim 11.

Advantageous developments of the device are in the Subclaims 2 to 10 specified.

The device according to the invention is preferably after Claim 11 for determining the transmission quality at Transition of light from or to one Optical fiber, one end of which is in a sleeve located, used.

The invention can be particularly advantageous when Alignment of the optical axes of two Apply fiber optic ends by their around their common longitudinal axis are rotated relative to each other. This is known from DE-OS 35 34 219. Furthermore it is described there that an optimal The maximum angular position Light output is used on the one free Optical fiber end is measured when free at the other Optical fiber end light coupled in and over the adjusting ends is passed.

Another application of the invention Device is that optical fiber with sleeve undergo a quality check for concentricity will. This is in the free end of the optical fiber Light coupled in, the optical fiber on the other End rotated by means of the device and in a while a measurement of a fixed distance from the end of the optical fiber only receive light that is in a circle around the axis of rotation of the Optical fiber lies with a sleeve. A recipient can Photodiode array can be used.  

In the device according to the invention, it is advantageous that Rotate the sleeve, which is at one end of the Optical fiber is located by means of a wheel that over a drive means is connected to the drive roller, perform. This creates a decoupling of the Rotational movement of movements perpendicular to the axis of rotation. A very good multi-point bearing of the axis of rotation of the wheel same effect. While rotating on the wheel and thus being transferred to the sleeve, the movements not transmitted perpendicular to the axis of rotation. This has the Advantage that the sleeve is rotated under even pressure is that of a spring that holds the wheel against the sleeve presses, is exercised. The spring also serves the purpose of Sleeve, by means of the wheel, against the walls of the guide press, which prevents the axis of rotation from moving becomes. Due to the inclination of the axis of rotation of the wheel, the one elastically deformable edge, for example a has elastic ring made of rubber, against the axis of rotation of the Sleeve has the advantage that the sleeve when turning moved against a stop regardless of the direction of rotation or is held. A particularly smooth rotation the sleeve is reached when the wheel has two rotating rings, for example made of rubber, with which the wheel on the sleeve rubs. The drive roller can be driven by means of a stepper motor or with a rotary knob. It simplifies handling when the translation is done at Drive with rotary knob is selected so that a 360 ° rotation the sleeve corresponds to a 120 ° turn of the rotary knob. Otherwise, the translation can be chosen arbitrarily. So that the optical fiber is not unnecessarily twisted is loaded, the device according to the invention has one Turn on, for example, on the drive roller is attached and which the rotation to a 360 ° rotation of the  Sleeve limited. It is also advantageous if you have the Tension the spring with which the wheel is pressed onto the sleeve or can loosen so that the correct contact pressure is always on the tail is exercised. Can be used as a guide for the sleeve serve a keyway that is particularly simple and very precise can be manufactured. The keyway must be very precise be worked so that the pivot point of the sleeve is accurate is set.

An embodiment of the device according to the invention explained. It shows

Fig. 1 plan view of a device according to the invention,

Fig. 2 front view of the device according to the invention,

Fig. 3 first side view of the device according to the invention,

Fig. 4 second side view of the device according to the invention.

In FIGS. 1 to 4 are views are shown of an inventive device. A keyway 5 is machined into a base plate 2 . The keyway 5 is worked very precisely. A sleeve 11 of an optical waveguide 1 is placed in the keyway 5 . The keyway 5 serves as a guide in which the sleeve 11 is rotatably mounted. A stop 6 is fastened to the base plate 2 with two screws 61 , 62 . The sleeve 11 of the optical fiber 1 is inserted so that it lies against the stop 6 . A rotary knob 10 is connected to a drive roller 8 via a shaft 9 . A traction device 12 transmits the rotary movement from the drive roller 8 to the wheel 7 . The wheel 7 has two rings 13 made of rubber. A spring 4 presses the wheel 7 with the rings 13 against the sleeve 11 . The spring 4 can be tightened or loosened by means of a screw 14 .

In addition, the wheel 7 can be lifted off the sleeve 11 by means of a lever 15 in order to insert or remove an optical waveguide 1 . The axis of the wheel 7 is inclined against the base plate 2 by an angle of approximately 3 ° in such a way that near the stop 6 the wheel 7 is further away from the base plate 2 than at a point further away from the stop 6 . As a result, the sleeve 11 is moved against the stop 6 during rotation regardless of the direction of rotation, that is to say that a sleeve 11 which is not inserted exactly is automatically moved against the stop 6 . The translation between the rotary knob 10 and the sleeve 11 is chosen so that a 120 ° rotation of the rotary knob 10 corresponds to a full rotation of the sleeve 11 . This makes the knob easy to use. A scale 16 simplifies the determination of the angle of rotation of the sleeve 11 for the operator

If two optical fibers 1 with sleeves 11 are to be rotated against one another, then the first can be inserted into the device described so far. For the second optical waveguide, a mounting 3 is provided on the base plate 2 , which presses the second optical waveguide into the keyway 5 by means of a spring force. This ensures that the axis of rotation of the first optical waveguide 1 coincides with the axis of the second. The attachment 3 is raised with a button 17 in order to insert an optical waveguide. So that the distance between the two optical fibers is precisely defined, the stop 6 or an additional stop is provided as a joint for the second optical fiber. The attachment 3 and the additional stop can be attached to the base plate 2 in any position along the keyway 5 , depending on the desired distance between the two optical fibers.

Claims (11)

1. Device for rotating an optical waveguide, one end of which is accommodated in a sleeve, in particular in a plug pin or a lens cartridge, around the longitudinal axis of the sleeve, which is rotatably mounted in a guide, characterized by the following features:

• - A wheel ( 7 ) with an elastically deformable tread is provided for rotating the sleeve ( 11 ) of the optical waveguide ( 1 ), the movement and force transmission being effected directly from the wheel ( 7 ) to the sleeve ( 11 ) by friction,
• - There is a pressing means for pressing the wheel ( 7 ) onto the sleeve,
• - The wheel ( 7 ) can be driven,
• - The axis of the wheel ( 7 ) and the longitudinal axis of the guide ( 5 ) lie in one plane and the axis of the wheel ( 7 ) is inclined at an angle to the longitudinal axis of the guide ( 5 ) that the sleeve ( 11 ) Rotation of the wheel ( 7 ) moves against a stop ( 6 ).

2. Device for rotating an optical fiber according to claim 1, characterized in that a stepping motor is provided as the drive for the wheel ( 7 ). 3. A device for rotating a light wave motor according to claim 1, characterized in that a rotary knob ( 10 ) is provided for driving the wheel ( 7 ). 4. Device for rotating an optical waveguide according to one of the preceding claims, characterized in that the tread is located on a ring ( 13 ) rotating around the wheel ( 7 ), with which the wheel ( 7 ) presses on the sleeve ( 11 ). 5. A device for rotating an optical waveguide according to claim 4, characterized in that the wheel ( 7 ) has a further ring ( 13 ) at a short distance from the circumferential ring ( 13 ). 6. Device for rotating an optical waveguide according to one of the preceding claims, characterized in that a spring ( 4 ) is provided as the pressing means, which can be tensioned or loosened by means of a screw ( 14 ). 7. Device for rotating an optical waveguide according to one of the preceding claims, characterized in that a keyway ( 5 ) is provided as a guide. 8. Device for rotating an optical fiber according to one of the preceding claims, characterized in that the device has a rotary stop, such that the sleeve ( 11 ) can be rotated by a maximum of 360 °. 9. Device according to one of the preceding claims, characterized in that the wheel ( 7 ) via a traction means ( 12 ) can be driven. 10. The device according to claim 3, characterized in that the translation between the rotary knob ( 19 ) and sleeve ( 11 ) is selected so that a 120 ° rotation on the rotary knob ( 10 ) corresponds to a full rotation of the sleeve ( 11 ). 11. Application of a device according to one of the previous claims for qualitative or quantitative Determination of a deposit of a light spot from a measuring point on the axis of rotation of the sleeve, the light spot from the Light is generated from the optical fiber with sleeve exit.