SU1714553A1 - Optical connector - Google Patents

Abstract

The invention relates to elements of fiber optic technology and can be used to connect an optical cable with an optoelectric node, both learning and receiving. The purpose of the invention is to simplify the construction and reduce the size while maintaining the existing level of attenuation of the light signal. The housing 1 contains sleeves 2 with an optoelectric assembly 4 and a sleeve 3 with a light guide 5. Sleeve 2 is made with a flange 6 for rotation and the axis of its inner cylindrical surface is offset relative to the axis of the outer cylindrical surface by a distance equal to the difference of the radius of the outer cylindrical surface of the sleeve 3 and the radius of the active region of the optoelectric unit 4. 2 ml.

Description

The invention relates to elements of fiber optic technology and can be used to connect an optical cable with an optoelectric NODE, both radiating and receiving.

The aim of the invention is to simplify the design and reduce ra6apitTOB while maintaining the existing attenuation level of the light signal.

FIG. 1 shows the proposed construction of an optical connector; in fig. 2 shows section A-A in FIG. one.

The optical connector contains a cylindrical body 1 with an external thread at the ends. Inside the case is located (9 | bushings 2 and 3; inside the sleeve 2 there is an optoelectric use 4 installed, and inside the sleeve 3 a light guide 5 is fixed.

The sleeve 2 has a flange 6 for its rotation when combining the active region of the optoelectric node 4 and the light guide

cores 5, while the longitudinal axes of the inner and outer cylindrical surfaces of this sleeve are spaced by a distance equal to the difference between the radius of the hole for the light guide bush and the radius of the active region of the optic node.

The sleeve 3 has a centering bead 7 with a protrusion 8 under the fixing groove in the cylindrical groove of the inner surface of the housing 1. The covers 9 and 10 are screwed onto the body from two sides.

The housing 1 has a flange with holes for fasteners.

The combination of the active region of the optoelectric node and the light guide core is performed as follows.

A sleeve 3 with a light guide 5 mounted into it is mounted in the housing 1 so that the protrusion 8 fits into the fixing groove of the cylindrical groove of the inner surface of the housing. The cover 10 is put on the case and screwed to the stop. Then, a sleeve 2 with an optoelectric unit 4 is installed in the case. An electrical setup consisting of a DC power supply connected in series, an optical coupler with an emitting optoelectric coupler, an optical cable, an optical coupler with a receiving optoelectric node, and an oscilloscope are assembled. Rotation of the sleeve 2 with the radiating optoelectric node for the flange 6 on the oscilloscope screen yields the maximum indication, which corresponds to the maximum combination of the active region of the optoelectric node and the light guide core. Disassemble the electrical circuit, slide the cover 9 onto the housing 1 and screw it in until it stops. Then, all the adjustment operations performed for the optical connector with the receiving optoelectric node are repeated.

Claims (1)

AND APPLICATION OF THE INVENTION An optical connector comprising a housing with a threaded surface, on the ends of which there are two covers, and inside the housing — two cylindrical bushings, the optoelectric assembly with the active region being mounted in the first sleeve, and a fiber optic socket, which differs in that, in order to simplify the design and reduce the size while maintaining the attenuation level of the light signal, the first sleeve is made with a flange on the end, placed between the housing and the cover, and its axis the inner cylindrical surface is offset relative to the axis of the outer cylindrical surface by a distance Si satisfying the condition, where R is the radius of the outer cylindrical surface of the second sleeve; r is the radius of the active region of the optoelectric node. AK 2