KR200167148Y1 - Optical fiber connector union body for multi-core optical cable - Google Patents

Abstract

The present invention relates to an optical fiber connector for connecting an optical cable, and more particularly, to an optical fiber connector that can easily and easily connect the connection and alignment between the ends of each optical cable.

It is an object of the present invention to provide an optical fiber connector binder that facilitates alignment of the most important optical fibers in a multicore fiber connection, maintains a secure connection during use, and facilitates binding and disconnection.

Means for achieving the object of the present invention, in the optical fiber connector for coupling the ferrule formed in the pair of plugs in which the optical cable is built in a mechanical connection method, a pair of ferrules (11) in which the optical cable is built in a mechanical connection method An optical fiber connector for joining, comprising: a disk-shaped connecting surface (13) integrally formed at an end of the ferrule (11) so that the front end of the ferrule protrudes;

A pair of plugs 10 formed to penetrate the disc of the disc-shaped connecting surface 13 and composed of a plurality of fastening holes having a plurality of cutouts 41;

An adapter (20) interposed between the plugs (10) and formed in the same shape as the disc-shaped connecting surface (13) and having a coupling groove into which an end of the ferrule is inserted in the center thereof;

It consists of a fastening pin 50 for coupling the plug 10 and the adapter 20 by penetrating the fastening hole 40 of both the plug 10 and the adapter 20,

The fastening pin 50 has a stopper 55 having a size that does not pass through the fastening hole 40 at an outer end thereof, and a fastening shaft having a fixing protrusion 58 inserted into the fastening hole 40 at an inner end thereof. 51;

A fixing jaw 53 is formed to pass through the fastening hole 40 only through the cutout portion 41 of the fastening hole 40 at an outer end thereof, and the fixing protrusion 58 of the fastening shaft is fitted to the inner end thereof so as to slide. An inner space portion is provided, and an end portion of the space portion is provided with a bent portion 57 that is bent in a radially inward direction, and a shaft cover 52 inserted into the fastening hole 40;

One end is supported by the fixing protrusion 58 of the fastening shaft, and the other end is installed on the outer circumferential surface of the fastening shaft 51 so as to be supported by the bent portion 57 of the shaft cover, and the shaft cover 52 and the fastening shaft 51 It has a feature consisting of a compression spring 54 that acts an elastic force to pull each other.

Description

Optical Fiber Connector Binder for Ultra-Multi Core Optical Cables

The present invention relates to an optical fiber connector for connecting an optical cable, and more particularly, it is easy to insert and connect an optical cable to the connector when connecting the optical cable, and at the same time, the connection and alignment between the ends of each optical cable can be easily and conveniently connected. The present invention relates to an optical fiber connector.

In general, optical communication is to exchange information by transmitting light through optical fiber, which can transmit tens of thousands of times more information than electric communication by coaxial cable which is currently used and can exclude the influence of radio waves and magnetic fields from the outside. In addition, since the information transmission is good, it is widely used in the communication field, and its use range is gradually expanding to other fields.

Therefore, in recent years, the rapid recognition of informatization has required more optical cable lines. Recently developed optical cables have been used to process a lot of information by producing a ribbon-type multi-core optical cable in which a single optical fiber is integrated into a strip. Such an optical cable is installed at a distance of several hundred kilometers or more, and thus requires connection and branching of the cable in the middle.

However, since optical fibers made of very small diameters (125㎛) are formed inside the optical cables, it is very difficult to connect the cores of the optical fibers to each other, and in the case of multi-core optical cables, it is necessary to connect a plurality of optical fibers at once. More difficult.

Various methods are used for the connection of optical fibers, and representative examples thereof include a fusion splicing method and a mechanical splicing method. The electronic fusion splicing method is a method of melting and connecting optical fibers and is mainly used for permanent connection.In order to achieve this, expensive precision fusion splicing apparatus must be used and power must be used. There is an advantage of high reliability of optical characteristics.

In addition, the mechanical optical cable connector has various advantages, such as convenience of work and no additional equipment, so that it can be easily connected even without a power source, and the reliability of the optical characteristics is almost the same as that of fusion splicing.

In order to fundamentally solve the breakage of the optical fiber, it is useful to prevent the generated torsional tension directly applied to the optical fiber cladding and to perform the second clamping on the optical fiber coating. In addition, in the implementation of the double clamping function has a structure in which the primary clamping and the secondary clamping function is operated at the same time.

In the conventional optical fiber splice for the optical fiber connection, because a special tool is used for the clamping function that adds the force required for maintaining alignment when the optical fiber is connected between the optical fibers, the cost of the optical fiber connection and the use of the tool has been inconvenient. .

In addition, in performing the clamping function, when the force acts in the axial direction of the optical fiber, an axial sliding occurs even when the optical fiber is aligned, resulting in a connection failure and an increase in optical loss. As a countermeasure for this, the anti-rolling structure is added to prevent the pressing plate from being pushed in the axial direction. In this case, the additional device for the implementation is small, so it is difficult in terms of manufacturing technology and is weak in structure. It is a challenge that requires great care.

Therefore, according to such a request, various optical cable connection connectors are disclosed in Korean Patent Application Nos. 95-38970 and 95-71047, and Korean Patent Application Publication Nos. 95-007219, 95-021929, and 95-010737. It is disclosed in detail.

Therefore, when looking at the connection device of the conventional optical fiber connector, the conventional optical fiber connector is a pair of plugs 10 including a ferrule 11 protruded to a predetermined length on one side of the core wire of the multi-core optical cable is inserted, and The pair of reinforcing members 22 are provided on both sides of the adapter 20 having the through-hole 21 for accommodating the above-described ferrule 11, and both side walls of the body constituting the hollow rectangular shape. On the side, a pair of plugs 10 are symmetrically coupled to each other, and are composed of a case 30 having an elastic body 31 which couples and fixes the entire connector.

However, as described above, the conventional mechanical optical cable connector uses a screw when coupling to the case, so that a separate tool is used for fastening, which is cumbersome for the connection work in the field.

In addition, since the plug 10 is coupled to the adapter 20, the connector and the adapter are configured to be inserted into the case 30 so that the connector is fixed, so that the connector is kept in a separate state in order to remain bound. Need.

Therefore, there is a problem in that the plug 10 is installed in a place for connecting the multi-core optical fiber and the bulk is larger than necessary in binding the plugs together.

The purpose of the present invention is to facilitate the alignment of the most important optical fibers in multi-core optical fiber connection, to keep the connection securely during the use period, and to connect and disconnect the interconnectors, so that the optical fiber connector is easy to bind and separate. To provide a sieve.

1 is an exploded perspective view of an optical fiber connector according to the prior art.

2 is an exploded perspective view of the optical fiber connector according to the present invention.

3 is a plan sectional view of an optical fiber connector according to the present invention.

4 is a perspective view of a fastening pin according to the present invention.

*** Description of the main parts of the drawing ***

10: Plug 11: Ferrule

12: Connector 13: Connection surface

20: Adapter 21: Through-through

22: reinforcing member 30: case

31: elastic body 40: fastener

41: cut out 50: fastening pin

51: Tightening shaft 52: Shaft cover

53: fixed jaw 54: compression spring

55: stopper 56: support protrusion

57: bending portion 58: fixed protrusion

60: optical cable

The structure of the optical fiber connector for achieving the object of the present invention, in the optical fiber connector for coupling the ferrule formed in a pair of plugs with a built-in optical cable by a mechanical connection method, the end of the ferrule so that the front end of the ferrule protrudes A disk-shaped connecting surface integrally formed in the;

A pair of plugs formed to penetrate the disk of said disk-shaped connection surface and comprising a plurality of fastening holes having a plurality of cutouts;

An adapter interposed between the two plugs and formed in the same shape as the disc-shaped connection surface and having a coupling groove into which an end of the ferrule is inserted in the central portion thereof;

It consists of a fastening pin for coupling the plug and the adapter by passing through the fastening hole of both the plug and the adapter,

The fastening pin has a stopper having a size that does not pass through the fastening hole is formed in the outer end, the inner end is a fastening shaft formed with a fixing projection inserted into the fastening hole;

A fixing jaw through which the fastening hole passes only through the bent portion of the fastening hole is formed at the outer end thereof, and an inner space is provided at the inner side to slide the fixing protrusion of the fastening shaft, and the end of the space portion is bent in a radially inward direction. A shaft cover provided with a bent portion and inserted into the fastening hole; One end is supported on the fixing projection of the fastening shaft, and the other end is installed on the outer peripheral surface of the fastening shaft so as to be supported by the bent portion of the shaft cover has a feature consisting of a compression spring acting an elastic force to pull the shaft cover and the fastening shaft to each other.

Looking at the preferred embodiment according to the object of the present invention by the accompanying drawings as follows.

Reference numeral 51 is a fastening shaft which is coupled to the spring to be described later to form the axis of the fastening pin, and reference numeral 52 is a component of the fastening pin to which the tension of the spring is applied by being overlaid on the fastening shaft as the shaft cover. Reference numeral 53 is a fixed jaw, which is formed integrally with the shaft cover.

In addition, reference numeral 55 serves as a stopper to prevent the fastening pin from falling into the fastening hole and to support the fastening pin, and reference numeral 56 is a support protrusion formed on the fastening shaft to support the fastening shaft and the shaft cover. To keep them spaced apart.

Reference numeral 57 is a bent portion formed in the shaft cover to allow the support protrusion to be inserted so that the fastening shaft can be inserted into the shaft cover. Also, reference numeral 58 is a fixing protrusion integrally formed at an inner end of the fastening shaft 51 to support one end of the compression spring 54.

As shown in FIG. 2, the adapter 20 is coupled between the plug 10 in which the multi-core optical cable 60 is embedded, and the fastening pin 50 for coupling the optical fiber connector is connected to the fastening surface 13 of the plug. Inserted into the formed fastening hole 40 is inserted into the fastening hole formed in the adapter 20 and the plug of the other side in the same shape as the fastening hole is fastened.

And a coupling means for engaging the ferrule 11 of the plug, wherein the coupling means includes a compression spring 54 fitted on the coupling shaft so as to be interposed between the shaft cover 52 and the coupling shaft 51. Specific support rotation to limit movement of the fixing protrusion 58 and the shaft cover 52 or the coupling shaft integrally formed at the inner end of the coupling shaft 51 to support one end of the compression spring 54. It is configured to include a stopper 55 formed in the fastening shaft to pass only at an angle.

And the fastening pin 50 is composed of a fastening shaft 51 and the rotating cover 52, the spring 54 is coupled to the fastening shaft 51. In addition, the fastening hole 40 has a notch 41 formed laterally so that the shaft cover 52 of the fastening pin 50 can be inserted therein.

3 shows a fiber optic connector according to the present invention in a cross-sectional view, in which a pair of plugs 10 having optical cables inserted therein are symmetrically coupled to each other with an adapter 20 interposed therebetween, Fastening pins 50 to be coupled and fixed are penetrated.

Therefore, the working example of the present invention configured as described above is as follows.

First, both plugs 10 are inserted into the adapters. And the fiber bundle with the ferrule aligned inside is matched with the optical fiber arranged in the plug 10 of the other side again and the fastening pin 50 for coupling the optical fiber connector is inserted into the fastening hole 40 of the plug to rotate the fixing jaw By tightening.

At this time, the fastening shaft 51 and the shaft cover 52 of the fastening pin are spaced apart using the support means formed on the fastening pin, which is a support protrusion formed on the fastening pin 50. The shaft cover 56 is rotated and fixed so that 56 does not coincide with the bent portion 57 formed on the shaft cover 52.

Thereafter, the fastening pin is inserted into the fastening hole. The fixing jaw 53 formed at one end of the fastening pin is formed in a size similar to the diameter of the coupling support jaw so that the fastening pin can be inserted into the cutout. do.

After the fastening pin is inserted, the fixing jaw 53 is fixed to the rear surface of the fastening hole by rotating the shaft cover 52 of the fastening pin 50 so as to be supported by the surface of the other plug 10. do.

In addition, the fastening pin 50 has a spring 54 which is urged by a fixing protrusion 58 integrally formed at the inner end of the fastening shaft 51 to support one end of the compression spring 54 therein. The compression force of the spring 54 acts on the fastening surface 55 and the adapter 20 of the plug to press the fastening pin 50 and the adapter 20.

Therefore, the plug 10 has a resistive force because the compression force of the spring pulls each plug 10 against the torsional pressure that affects the optical fiber connector from the outside.

In addition, the fastening pin 50 rotates the fixing jaw formed at one end of the shaft cover 52 when the optical fiber connector is detached so that the fixing jaw 53 is matched with the support protrusion 56 so that the plug 10 Can be released.

Therefore, in the present design, the optical fiber connector coupling pin 50 having the optical spring connector 54 having a compression spring 54 inside the slope in order to improve the connection state of the optical cable of more than a few centimeters in each of the fastening holes 40 By means of pressurizing the pressure to a uniform pressure, it is resistant to the torsional pressure which affects the optical fiber connector from the outside.

In addition, when the phenomena occur in the axial direction, it is possible to prevent the connection failure and increase of the optical loss of the optical cable, and it is possible to separate both plugs 10 by only rotating the fixing jaw 53 during detachment. It has a convenient optical cable detachable structure.

Claims (2)

In an optical fiber connector for coupling a ferrule 11 formed on a pair of plugs in which an optical cable is embedded by a mechanical connection method, a disk-shaped connection surface integrally formed at an end of the ferrule 11 so that the tip of the ferrule protrudes. (13); A pair of plugs 10 formed to penetrate the disc of the disc-shaped connecting surface 13 and composed of a plurality of fastening holes having a plurality of cutouts 41; An adapter (20) interposed between the plugs (10) and formed in the same shape as the disc-shaped connecting surface (13) and having a coupling groove into which an end of the ferrule is inserted in the center thereof; It consists of a fastening pin 50 for coupling the plug 10 and the adapter 20 by penetrating the fastening hole 40 of both the plug 10 and the adapter 20, The fastening pin may include a fastening shaft 51 having a support protrusion 56 integrally formed at an outer end thereof and unable to pass through the fastening hole 40; A shaft cover 52 having a fixing jaw formed at an outer end thereof so as to pass through the fastening hole only through the bent portion 57 of the fastening hole 40; The shaft cover 52 and the coupling shaft is composed of a coupling means for coupling so as to always pull each other and rotatable, After passing through the fixing jaw of the shaft cover 52 to the bent portion 57 of the fastening hole 40, the shaft cover 52 is rotated to one side so that the fixing jaw is caught by the fastening hole. An optical fiber connector binder for an ultra multi-core optical cable, characterized in that for coupling the plug and the adapter. The method of claim 1, wherein the coupling means includes a compression spring (54) fitted on the coupling shaft so as to be interposed between the shaft cover (52) and the coupling shaft (51); A fixing protrusion 58 integrally formed at an inner end portion of the fastening shaft 51 to support one end of the compression spring 54; In order to limit the movement of the shaft cover 52 or the fastening shaft, an optical fiber connector for an ultra-high optical fiber connector, characterized in that it comprises a stopper (55) formed on the fastening shaft so as to pass through the support projection only at a specific rotation angle. .