RU2504807C9 - Fibre-optic socket - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: fibre-optic socket has a housing with a centraliser, the centraliser being in form of a floating coupler, having an annular groove in the central part of the outer cylindrical surface, and opposite ends of the floating coupler have conical outer surfaces. The housing of the fibre-optic socket has an inner annular groove in which an additional fixing element is inserted, said element being located in the annular groove of the floating coupler. The floating coupler can be in form of a resilient collet element and has one or more elements; the fixing element of the floating coupler can be in form of an resilent split ring. Opposite ends of the resilient collet element have conical outer surfaces. The resilient collet element can have in the central part of the outer cylindrical surface a protrusion for fixation thereof in the annular groove of the housing of the fibre-optic socket.

EFFECT: high impact and vibration resistance of the fibre-optic socket while maintaining accuracy of accuracy of coupling ferules of convectors and simple design.

6 cl, 8 dwg

Description

The invention relates to devices for fiber optic information transmission lines and can be used as a socket for fiber optic connectors.

Known fiber optic SC-type socket, designed for detachable connection of fiber optic cords, containing a plastic housing made with a transitional sleeve fixed to it with a centralizer installed in it, made in the form of a floating split ceramic sleeve [1].

Also known is a fiber-optic ST-type socket containing a metal housing with a centralizer made in the form of a floating split bronze sleeve [2]. The disadvantages of these fiber optic outlets are insufficient shock and vibration stability, due to the design features of their execution.

Closest to the technical nature of the present invention is the FC-type fiber optic socket we have taken as a prototype, designed for detachable connection of fiber-optic cords, containing a metal housing, inside of which the adapter sleeve is coaxially mounted with the centralizer installed in it, made in the form of a floating split ceramic sleeve [3].

This fiber optic outlet has a high accuracy of articulation of ferrules of convectors in it, but does not provide shock and vibration stability when docking single-mode optical fibers, due to the design features of its floating split ceramic sleeve.

Therefore, the use of this fiber-optic outlet on moving objects, for example, in fiber-optic transmission lines installed on rocket and space technology products, leads to disruption of the onboard fiber-optic lines due to mutual resonant vibrations of the tips (ferrules), due to the presence of a gap between the housing of the outlet and the ceramic centralizer installed in it, which limits the scope of this fiber optic outlet.

The aim of the invention is to increase the shock and vibration resistance of a fiber optic outlet while maintaining the accuracy of articulation of ferrules connectors and simplifying the design.

This goal is achieved by the fact that in a fiber optic outlet containing a housing with a centralizer, the centralizer is made in the form of a floating coupling having an annular groove in the central part of the outer cylindrical surface, and the opposite ends of the floating coupling are made with external conical surfaces, the fiber housing the optical outlet contains an inner annular groove into which an additionally inserted locking element is inserted, located in the annular groove of the floating joint body coupling.

While the floating coupling may contain one or more elements made in the form of sectors with an external annular groove, the locking element of the floating coupling can be made in the form of an elastic split ring or in the form of turns of an annular spring, the floating coupling can be made in the form of an elastic collet element having an annular groove in the central part of the outer cylindrical surface, opposite ends of the elastic collet element are made with external conic kimi surfaces and the resilient member may comprise a collet in a central portion of the outer cylindrical surface of the protrusion for fixing it in an annular groove housing optical fiber outlet.

Increasing the shock and vibration resistance of the fiber optic outlet while maintaining the accuracy of the articulation of the ferrules of the connectors is ensured by replacing the centralizer made in the form of a floating split ceramic sleeve of the prototype optical fiber socket, with a centralizer in the form of a floating coupling, the opposite ends of which are made with external conical surfaces, and the elastic collet element may contain a protrusion in the central part of the outer cylindrical surface for its fixation in the ring EVA groove of the fiber optic housing.

Improving the shock and vibration resistance of a fiber optic outlet while maintaining the accuracy of the articulation of convector ferrules is ensured by replacing a centralizer made in the form of a floating split ceramic sleeve of a prototype fiber optical socket, with a centralizer in the form of a floating coupling, the opposite ends of which are made with external conical surfaces, allowing to center the ferrules of the convector due to the radial compressive force of the floating coupling.

Also, the advantage of the proposed fiber optic outlet is the simplicity of design, a small number of parts included in the design of the outlet, and, therefore, the speed and ease of assembly of the fiber optic outlet.

The invention is illustrated by drawings:

Figure 1 shows a longitudinal section of a fiber optic outlet, taken as a prototype.

Figure 2 shows a longitudinal section of the proposed fiber optic outlet.

Figure 3 shows the appearance of a floating coupling containing one sector with an external annular groove into which the locking element is inserted.

Figure 4 shows the appearance of a floating coupling containing three sectors with an outer annular groove into which a locking element is inserted in the form of an elastic split ring.

Figure 5 shows the appearance of a floating coupling, with a locking element in the form of coils of an annular spring.

Figure 6 shows the appearance of the centralizer in the form of an elastic collet element with four slots.

Figure 7 shows a longitudinal section of the proposed fiber optic outlet with elements docked to it convectors.

On Fig shows the appearance of the proposed fiber optic outlet.

Figure 1 shows a longitudinal section of a fiber optic outlet, taken as a prototype, comprising a housing 1, into which bushings 3 and 4 are pressed in through a hole 2, holding a centralizer made in the form of a floating split ceramic sleeve 5. The housing has threads 6 and 7 for tightening the cap nuts of the joined convectors and the grooves 8 and 9 for the keys of the elements of the optical convectors to enter into them, necessary to prevent the ferrules of the convectors from turning, as well as the flange 10 for attaching the fiber-optic outlet.

Figure 2 shows a longitudinal section of the proposed fiber optic outlet containing the housing 11, inside of which is inserted a floating coupling 12, held by the locking element 13.

Figure 3 shows the appearance of the floating coupling 12, containing one sector 14 with an external annular groove 15, into which the locking element 13 is inserted. The floating coupling is a cylinder 16, the opposite ends 17 and 18 of which are made with external conical surfaces 19 and 20. Along the axis coaxial to the cylinder 16 of the floating coupling 12, a through hole 21 is made having chamfers 22 and 23, necessary for the ends of the ferrules of convectors to enter the floating coupling 12, as well as the incision 24, necessary for deformation of the coupling 12.

Figure 4 shows the appearance of a floating coupling 12 containing several sectors 25, 26 and 27 with external annular grooves 28, 29 and 30 into which the locking element 13 is inserted, in the form of an elastic split ring. The floating coupling is a cylinder 31, the opposite ends 32 and 33 of which are made with external conical surfaces 34 and 35. Along the axis coaxial to the cylinder 31 of the floating coupling 12, a through hole 36 is made having chamfers 37 and 38 necessary for the ends of the ferrules of convectors to enter floating coupling 12. Sections 39, 40 and 41 are necessary to move sectors 25, 26 and 27 relative to each other. The locking element 13 in the form of an elastic split ring is inserted from the side of one of the ends 32 or 33, while being squeezed along the outer conical surfaces 34 or 35 when approaching the annular groove, reaching which, the elastic split ring snaps into the annular groove under the action of elastic forces and fixes sectors 25, 26 and 27 relative to each other. An advantage of a coupler containing several sectors is the high accuracy of centering the ferrules of convectors.

Figure 5 shows the appearance of the floating coupling 12, with the locking element 13, made in the form of coils of an annular spring. The spring 42 is inserted from the side of one of the ends 43 or 44, while being unclenched by external conical surfaces 45 or 46 when approaching the annular groove 47, having reached which, the spring is compressed by the action of elastic forces in the annular groove 47 and fixes sectors 48 and 49 relative to each other .

Figure 6 shows the appearance of the centralizer in the form of an elastic collet element with four slots. The collet element 50 is made of a cylindrical sleeve, and the opposite ends 51 and 52 of the cylindrical sleeve are made in the form of external conical surfaces 53 and 54. Along the axis coaxially with the conical surfaces 53 and 54 of the collet element, a through hole 55 is made having chamfers 56 and 57 necessary for approaching the ends of the ferrules of the convectors into the collet element 50, moreover, cuts 58, 59, 60, 61 are made from each end of the cylindrical sleeve, overlapping each other in the central part 62 of the cylindrical sleeve, but not reaching the opposite end, and offset relative to each other at a certain angle. A protrusion 64 is made on the outer cylindrical surface 63 for fixing the collet element in the housing 11 of the fiber optic outlet.

The advantage of a centralizer in the form of an elastic collet element is the absence of separate fixing elements and sectors in its design.

Figure 7 shows a longitudinal section of the proposed fiber optic outlet with elements docked to it convectors. Improving the accuracy of the articulation of ferrules of convectors and simultaneously increasing the vibration resistance of the fiber optic outlet is ensured by the fact that, when docked, the ferrules 65 and 66 enter the centralizer 12 of the proposed fiber optic outlet until they touch, providing optical contact of the ends of the fibers 67 and 68, and thanks to tightening the flare nuts 69 and 70 of the convectors on the threaded surfaces 71 and 72 of the socket; at the same time, the springs 73 and 74 included in the convector are compressed and the guide bushings 75 and 76 of the projectors in the grooves formed by the conical surfaces 77 and 78 of the centralizer 12 and the housing 11 of the fiber optic outlet, which ensures both the alignment of the ferrules 65 and 66 of the convectors, and their rigid, gapless mechanical connection with the housing of the proposed fiber optic outlet, which is attached with the holes 79 and 80. Also, the housing contains grooves 81 and 82 for entering keys 83 and 84 located on the guide bushings 75 and 76 of the optical convectors, necessary to prevent the ferrules from turning when turning Nuts of union nuts 69 and 70.

On Fig shows the appearance of the proposed fiber optic outlet containing the housing 11 and the floating connector 12.

Bibliography

1. US patent No. 5317663002B 6/38.

2.http: //www.qtech.ru/catalog/fiberopticcomp/69/info.htm#2.

3. US patent No. 5680494002B 6/38.

Claims (6)

1. Fiber-optic socket containing a housing with a centralizer, characterized in that the centralizer is made in the form of a floating coupling having an annular groove in the central part of the outer cylindrical surface, opposite ends of the floating coupling are made with external conical surfaces, and the fiber-optic housing the socket contains an inner annular groove into which an additionally inserted locking element is inserted, located in the annular groove of the floating coupler. 2. The fiber optic outlet according to claim 1, characterized in that the floating coupling contains one or more elements made in the form of sectors with an external annular groove. 3. The fiber optic outlet according to claim 1, characterized in that the fixing element of the floating coupling is made in the form of an elastic split ring. 4. The fiber optic outlet according to claim 1, characterized in that the fixing element of the floating coupling is made in the form of coils of an annular spring. 5. The fiber optic outlet according to claim 1, characterized in that the floating coupling is made in the form of an elastic collet element having an annular groove in the central part of the outer cylindrical surface, and the opposite ends of the elastic collet element are made with external conical surfaces. 6. The fiber optic outlet according to claim 5, characterized in that the elastic collet element comprises a protrusion in the central part of the outer cylindrical surface for fixing it in the annular groove of the housing of the fiber optic outlet.

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