KR20100095283A - Optical fiber splicer and optical connector with the splicer - Google Patents

Abstract

PURPOSE: An optical fiber and an optical connector thereof are provided to securely fix the optical fiber part of an optical cable by using a separate connection part instead of an existing sleeve. CONSTITUTION: A ferrule, an optical cable, or the line of an optical cable are fixed to the inside of a first and a second connection part bodies(30,40). A connection part body combining part is formed in the first and the second connection part bodies. The connection part body combining part is used in order to assemble the first and the second connection part bodies. The line of one side optical cable, the ferrule(10), and the other side optical cable(20) are fixed to the inside of the connection part body. A line path is formed in at least one among the first and the second connection part bodies.

Description

Optical fiber splicer and optical connector with the same

The present invention relates to an optical fiber connector and an optical connector including the same, in particular, an field-assembled optical connector, and more particularly, an optical fiber cable (hereinafter, ' Optical fiber '(or ferrule) to securely connect and fix the optical fiber (main line) portion of the optical fiber as well as to establish a stable optical communication, as well as to facilitate the field assembly of the ferrule and the optical cable using the connector, Ultimately, the present invention relates to an optical fiber connector and an optical connector including the same, which improves construction and stability of optical communication.

In recent years, due to the advancement of the optical cable network, the field assembly work of the optical cable is rapidly increasing. For example, instead of the (home) modem line (Internet communication line using a telephone line or a coaxial cable) currently used for Internet communication. Has been replaced by optical communication lines using optical cables.

An optical fiber is a fiber-shaped waveguide for the purpose of transmitting light, and is usually used in the form of an optical cable that is bound in several strands.

On the other hand, the optical fiber (main line) of the optical cable is a double structure of the core in the inner center and the cladding (cladding) surrounding it, the outside is composed of two or three layers of coating layer, the optical communication construction using the optical cable is an external electromagnetic wave Since there is no interference or interference caused by interference, hard wiretapping is difficult, and in particular, many communication lines can be accommodated in one optical fiber, it is essential for optical communication construction.

At this time, when assembling the optical communication using the optical cable is necessary for the field assembly work of the optical cable, for example, in order to connect the optical cable to the adapter of the optical modem connected to each computer (PC) of the home Use field-assembled optical connector to connect optical fiber (main line).

For example, a field assembly optical connector used for field assembly of an optical cable is known, and such an optical connector is used when connecting an optical cable between an outdoor terminal and an optical modem in each home. do.

For example, in the optical connector, the length of the optical cable in the field between the outdoor terminal and the optical modem in each home varies depending on the field environment, and thus, when the optical cable is assembled in the field, the main line of the optical cable is cut off to connect the optical connector to the optical connector. You are connected.

On the other hand, there are two methods of field connection of such an optical cable, one method is to connect the adapter to the main line of the ferrule (fiber) and the optical cable connected to the home to transmit the actual optical signal to the opposite optical cable. There is a mechanical connection method for connecting a main line (optical fiber) using a matching gel inside the connector.

Another method is to heat-bond a ferrule and an optical cable main line connection by arc discharge using a high voltage electrode, and to reinforce the deposition with a sleeve (tube) which contracts when heat is applied to such a fused main line connection site. It is.

By the way, in the case of the connection of the optical cable main line of the heat-sealing system known so far, the connection structure was not strong because the heat-sealing portion of the optical fiber was simply coated and reinforced with a sleeve made of synthetic resin.

Therefore, in recent years, although a fine rod (rod) is coupled to a sleeve for covering and reinforcing the heat-sealed connection portion of the optical cable main line, the structure is firm, but the effectiveness is not great.

Accordingly, the applicant of the present invention has proposed an optical connector and a optical connector including the same, which firmly press-fixes the a fusion splicing part when assembling the optical cable of the fusion splicing type.

But. The optical fiber connector of the present invention described in detail below is not necessarily limited to the main line (optical fiber) of the optical cable to be fusion-spliced, and can of course also be used for mechanical optical cable connection using a matching material (gel). For example, it can be used as an optical cable connector of the present invention or as an alternative to an existing sleeve.

The present invention has been proposed in order to solve the above-described conventional problem, and its object is that instead of the conventional sleeve covering and reinforcing the connected optical cable main line, it is easy to assemble and firmly crimps and secures the main line connection part for stable optical communication. As well as enabling the construction, as well as the connector including the connector to facilitate the field assembly of the ferrule and the optical cable, ultimately to provide an optical connector and an optical connector including the same to improve the construction and communication stability of optical communication There is.

As one technical aspect of the present invention, a ferrule and an optical cable connected to each other, or first and second connector bodies in which main lines of optical cables are seated and fixed therein; And,

Connector body coupling means provided in the first and second connector bodies and provided to enable assembly of the connector body in cooperation with each other;

It provides a fiber optic connector configured to include.

Moreover, as another technical aspect, this invention is an optical fiber connection port as described in any one of Claims 1-5; And,

Connector pressing means for tightly holding the ferrule and the optical cable or the main line connection of the optical cables by surrounding and pressing the optical fiber connector;

It provides an optical connector including a fiber optic connector configured to include.

According to the present invention, the optical fiber thermal fusion splicing part is securely connected by fixing the optical fiber (main line) of the optical fiber cable fusion-spliced by using a separate spherical connection port that is firmly bonded instead of the conventional shrink-coated sleeve It can be built.

It will also keep the mechanical connection of the optical cable using the matching material stable.

In particular, since the connector structure including the connection port facilitates field assembly of the ferrule and the optical cable while making the connection structure robust, the present invention ultimately provides excellent effects such as improving the construction and communication stability of the optical communication. It is.

Hereinafter, a preferred embodiment of the present invention according to the accompanying drawings.

Hereinafter, FIGS. 1 to 5 show an optical fiber (main line) connector 1 according to the present invention, and FIGS. 6 to 10 show an optical connector 100 according to the present invention including the same.

Therefore, first, the optical fiber connector 1 of the present invention will be described with reference to Figs. 1 to 5, and in the optical connector description of Figs. 6 to 10, the detailed description of the optical fiber connector is brief.

On the other hand, as described above, the present invention optical fiber splicing port 1 is not limited to the main line (optical fiber) connection fixing of the optical cable to be heat-sealed, but also to a mechanical optical cable connection using a matching material (gel). Of course, it is also possible to mechanically connect the main lines of both optical cables, but not to the ferrule main line and the optical cable main line, or to press-fix the heat-sealed main lines.

However, the following embodiment will be described based on the ferrule and the optical cable main connection state.

First, as shown in Figures 1 to 4, the optical fiber connector 1 according to the present invention, as an example, the main line of the ferrule and the optical cable or optical cables, that is, the main line of the ferrule 10 and the optical cable 20 ( 12) (22) is the first and second connector body 30 and 40, which is seated and supported therein, and the connector body which is provided in the first and second connector bodies to cooperate with each other and to provide assembly disassembly of the connector body. It may be configured to include a coupling means (50).

At this time, the main line 22 of the optical cable 20 to be connected to the main line 12 of the ferrule 10 is supported using a matching material (gel) or heat-sealed to be seated and supported inside the connector body.

Meanwhile, in the present embodiment, the ferrule and the optical cable main lines that are seated and fixed to the optical fiber connector 1 will be described in a state of being thermally fused by using a fusion machine (see 'C' in FIG. 1).

That is, as will be described in detail below, the optical fiber splice 1 of the present invention is press-fixed or fused while maintaining a connection state of the ferrule side main line and the optical cable side main line through the matching gel by inserting the matching gel into the main line connection part. It can serve to press-fix the connected main lines, and in any case as described in detail below, the ferrule-side flange portion and the cover portion (or one side optical cable sheathing) and (the other side) the optical cable sheathing are fixed. It can be fixed while maintaining the connection state of main boats stably.

At this time, in the optical fiber connector 1 of the present invention, the first and second connector bodies 30 and 40 are semi-circular bodies in cross-section, assembled as shown in FIG. 4 (see FIG. 7) to form a cylindrical body.

At least one of the first and second connector bodies 30 and 40, for example, is provided with the main lines 12 and 22 of the ferrule and the optical cable that are heat-sealed and connected to the lower first connector body 30. The main passage 60 is provided.

On the other hand, as shown in Figure 5, the surfaces of the first and second connector body 30, 40 in close contact with each other, when assembled with each other, the projecting contact surface (30a) and the concave contact surface (40a) to constant the crimping degree of the main line It may further include.

That is, if the protruding contact surface protrudes further in the vertical direction than the concave contact surface, the pressing crimp of the main line is constant even if the bodies are strongly compressed.

In addition, the main line passage 60 is formed in a V shape as shown in FIG. 5 so that the main line is guided and seated in the center of the passage.

1 and 3, at least one of the ferrule side flange portion 16 and the main line covering portion 14 and the optical cable may be provided on the first and second connector bodies 30 and 40. The flange crimping part 62 and the coating crimping parts 64 and 66 which press-fix the (20) side main line covering part 24 are further provided.

At this time, the flange crimping portion 62, as shown in Fig. 1, the catch of the front flange 16c of the unit flange (16a, 16b, 16c) of the stepped flange of the ferrule 10 is caught so as not to retreat The flange portion 16 of the ferrule, including the groove portion 62a, is firmly crimped and fixed when the first and second connector bodies 30 and 40 are assembled through the body coupling means 50 described in detail below. do.

1 and 3, the ferrule covering portion 14 and the optical cable covering portion 24 are formed on the cover crimp portions 64 and 66 formed on the first and second connector bodies 30 and 40. Protruding projections 64a and 66a are provided at the time of assembly.

In this case, the optical cable 20 has a coating part 24 formed through a protective layer 28 such as an inner glass fiber of the outer shell 26, and a main line (optical fiber) 22 is embedded in the coating part 24. do.

Therefore, the optical fiber splice 1 of the present invention, when the first and second splice body 30, 40 is assembled, the flange portion 16 and the cover portion 14 and the main line 12 and the ferrule 10 and Both the cover portion 24 and the main line 22 of the optical cable 20 can be firmly crimped and fixed.

1 and 3, in the optical fiber connector 1 of the present invention, the connector body coupling means 50 is formed to face the first and second connector bodies 30 and 40 to each other. The assembly protrusion 52 and the protrusion fixing groove 54 are provided.

At this time, the first and second connector bodies 30 and 40 are connected to the connecting portions 80 on both sides, and when the bodies are fitted to the assembly protrusion in the fixing groove, the connecting portion 80 is a thin strip of resin. It can be shorted out, and this connection serves to keep the bodies connected during manufacturing and storage installation.

Meanwhile, as shown in FIGS. 3 and 4, in the optical fiber connector of the present invention, recesses 70 are formed on the side surfaces of the first and second connector bodies to disassemble the bodies. Can be disassembled by inserting the body and opening the bodies (forced disengagement from the fixing groove).

At this time, the bodies of the optical fiber connector 1 of the present invention are made of transparent acrylic, etc., if the transmission state of the optical signal through the main line, that is, if there is a problem in the main line connection part, visually check the optical signal leaking from the main line connection part Can make it possible to do. At the same time, some configurations of the optical connector of the present invention described below can also be manufactured transparently.

6 to 9 show an optical connector 100 including the optical fiber connector 1 according to the present invention.

However, hereinafter, the embodiment of the present invention will be described in connection with fixing and fixing the main line of the ferrule 10 and the optical cable 20 assembled on-site, but is not necessarily limited thereto, as described above, connecting the main lines of both optical cables Of course, it can also be used.

That is, as shown in Figs. 6 to 8, the optical connector 100 of the present invention, the ferrule 10 and the main lines 12, 22 of the optical cable 20 are largely fused and connected to each other in front The optical fiber connector 1 described above, and the connector pressing means 110 for enclosing and pressing the optical fiber connector 1 to maintain the main line connection state of the optical cable.

In this case, preferably, the connector pressing means 110, the push holder 130 is inserted into the assembled optical fiber splice 1 and the frame-plug 150 is assembled to the push holder 130 do.

Therefore, inside the ring-shaped push holder 130 with a hollow inside, the ferrule and the fiber cable main line connected to each other are seated and fixed therein, the coupling means for simultaneously crimping and fixing the flange portion and the sheath of the ferrule and the sheath of the optical cable at the same time. The first and second connector bodies 30 and 40 assembled by the 50 are inserted into the cylindrical body as shown in FIG. 7.

In this case, the push holder 150 having the connector inserted therein is inserted into the frame-plug 150 having a hollow inside, and the frame-plug 150 is assembled to the frame 170.

In addition, the frame 170 is sequentially assembled to the housing 190 assembled to the adapter 210.

At this time, as shown in Figure 8 and 9b, the ferrule 10, the flange portion 16 and the cover portion 14 is crimped fixed to one side of the connection port through the space from the inside of the frame 170 to the inside Can be deployed.

7, 8, and 9B, the elastic member 230, that is, the spring, is formed at the outer edge of the optical fiber connector 1 between the flange 16 of the ferrule 10 and the tip of the frame plug 150. This is elastically supported.

Therefore, as shown in FIGS. 8 and 9B, when the ferrule 10 is assembled with the adapter 210 of the optical connector 100 of the present invention, when the spring is the elastic member 230, the spring is the ferrule flange portion 16. Since the ferrule flange portion 16 is elastically supported between the frame and the plug, the ferrule is fixed to the connector 1 as described above, and as a result, the entire ferrule and the connector 1 are elastic. It is supported by the elastic force of the member and consequently maintains the contact force between the adapter and the ferrule.

In addition, the push holder 130 protrudes through the opening 152 formed in the frame plug 150 so that the push holder 130 may be formed at the frame plug opening 154 as shown in FIG. 9B. After the rear side, the frame plug 150 is assembled to the frame 170, the push-up pusher 130 for pushing the operation protrusion 132 is pressed against the connector 1 without a tolerance.

In this case, as shown in FIG. 9, a stepped portion 160 into which the elastic member 230, which is a spring, is inserted and supported is formed at the front end of the frame plug 150.

Then, the rear end of the frame-plug 150, as shown in Figure 7, the boot (B) is assembled or the pleat portion 158 is assembled with the grip device 300 described in detail in Figure 10, the rear end The guide portion 156 is formed to guide the passage of the optical cable sheathing portion 24, and a stepped portion 162 is fitted to the inside of the frame 170 at the outer edge of the tip portion.

In addition, as shown in FIG. 8, a plurality of rail grooves 18 are formed in the flange portion 16 of the ferrule, and a rail portion passing through the flange rail groove 18 is formed inside the frame 1. 172 is formed.

Therefore, the ferrule is not rotationally flow, and stable linear flow is realized, which is to be constant when flowed to the spring which is the elastic member 230, as described above.

Meanwhile, as shown in FIGS. 7 and 9A, an opening 176 through which the operation protrusion 132 of the push holder passes is formed on the upper surface of the frame 17 so that the connector is inserted into the frame plug 150. In the pre-assembled state in which the holder 130 is inserted, when the frame-plug is assembled to the frame 170 as shown in FIG. 9B, the push holder is pushed to the connector by pushing the operation protrusion.

7 and 8, when the frame plug 150, the frame 170, and the housing 190 are inserted into each other, they are simply assembled and fixed, for example, on the outer edge of the frame plug 150. The formed fastening protrusions 152 are fitted into the fastening grooves 174 formed at the front end of the frame 170, and they are assembled.

In addition, the frame 17 has a square fastening protrusion 178 formed on the outer edge of the frame 17 is fitted into the fastening grooves 192 formed on both sides of the rear end side of the housing 190 to be sequentially assembled.

In addition, the optical connector 100 of FIG. 6, in which the connector-> push-holder-> frame-plug-> frame-> housing is assembled, is assembled to the adapter 210, and the adapter 210 is assembled to an outer edge of the assembly end ( Through the assembly 212).

On the other hand, if the arrangement step of the optical connector 100 of the present invention based on Figure 8, first, the main line 12, 22 of the optical cable passed through the ferrule, the frame-plug and the push holder as an example using a fusion machine Connect (see ① in the drawing), assemble the connector bodies 30 and 40 (see ② in the drawing), insert the assembled connector 1 into the push-holder 130 of the pressing means 110, In this state, it is assembled to the frame-plug 150 (refer to ③ in the drawing).

Then, the frame plug 150 is sequentially assembled to the frame 170 and the housing 170 (see ④ and ⑤ in the drawing), and finally the housing 190 is assembled to the adapter 210. ⑥ of)

At this time, as described above, the push holder 130 is inserted into the frame plug 150, the frame plug is assembled to the frame, and then pushes the operation protrusion 132 through the incision space to advance the connection port more firmly. Can be fixed.

That is, when the push-holder is pushed, the tolerance between the push-holder and the connection section inserted therein may be adjusted to be press-fixed more strongly.

Meanwhile, as shown in FIG. 7, surface contacts 134 and 90 which are in surface contact with each other on the side surfaces of the connector body 30 and 40 of the optical fiber connector 1 inserted into the push holder 130. Since the connection port 1 is formed correspondingly, the splice 1 does not rotate in the inside of the push holder 130, and the sliding of the push holder is performed stably.

Next, FIG. 10 illustrates another use state of the optical connector of the present invention, for example, an optical cable grip device 300 is used instead of the boot B. FIG.

That is, the circular fixing ring 28 is fixed to the end of the outer shell 26 of the optical cable 20, the upper body 310 of the grip device 300, that is, the connector-side first upper body 312 and the passage ( 322 and the fixing ring to be fitted when the upper body and the lower body are coupled to the fixing ring fixing groove 330a formed in the upper body 310 and the lower body 320 separated by the second body 314 on the cable side. The wrinkles 158 formed on the outer edge of the frame plug 150 of the optical connector 100 are fitted into the fixing grooves 330b of the upper body and the lower body.

In addition, the fixing groove 342 of the hook 340 protruding from the first body and the second body of the upper body fits the fixing protrusion 350 of the lower body 320 when the upper body and the lower body are coupled to each other. When the two bodies 312 and 314 are firmly fitted to the lower body 320, respectively, the optical cable sheathing portion 24 extends through the passage 322 inside the lower body to form a loop. As described above, a part of the abdomen 24 and the main line 22 are fixed to the optical fiber connector 1 inside the optical connector.

Therefore, since the grip device 300 of the present invention of FIG. 10 secures the optical cable sheath fixing ring and the optical connector more stably, it provides an advantage of effectively preventing the optical communication instability due to the optical cable flow, and at the same time in the field assembly of the optical cable. The gripper can be held by the operator, which will greatly facilitate the construction of optical communications.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be modified and modified in various ways without departing from the spirit or scope of the invention as set forth in the claims below. It will be appreciated that those skilled in the art can easily know.

1 is a block diagram showing a heat-sealed optical fiber connection state using the optical fiber connector according to the present invention

Figure 2 is a schematic diagram showing a state connected through the present invention connector of Figure 1

Figure 3 is an exploded perspective view showing the optical fiber splice of the present invention

FIG. 4 is a perspective view showing the assembled optical fiber connector of FIG. 3. FIG.

5 is a cross-sectional view showing an optical fiber connection state of the optical fiber connector of the present invention.

6 is a perspective view showing an optical connector including an optical fiber connector according to the present invention;

FIG. 7 is a partially exploded perspective view of FIG. 6.

8 is an exploded perspective view showing the assembled state of the optical connector of the present invention;

9A and 9B are cutaway perspective views and cross-sectional views showing optical fiber connection states of an optical connector of the present invention;

10 is a perspective view showing a state of using the optical connector of the present invention using another optical cable grip device

Explanation of symbols on the main parts of the drawings

1 .... fiber optic splice 10 .... ferrule

12,22 .... Main line (optical fiber) 20 .... Optical cable

30,40 .... First and second bodies of splice 50 .... Splice body coupling means

52 .... Assembling protrusion 54 .... Protrusion fixing groove

60 .... main passage 62 .... flange crimp

64,66 .... Cloth Crimp 70 .... Concave

80 .... Body connection 90,134 .... Face contact

100 .... optical connector 110 .... splice

130 .... Push holder 132 .... Operation protrusion

150 .... Frame-Plug 170 .... Frame

190 ... housing 210 ... adapter

230 ... elastic member 300 ... grip device

Claims (12)

Ferrules and optical cables connected to each other, or first and second connector bodies 30 and 40 to which main lines of optical cables are seated and fixed therein; And, Connector body coupling means (50) which is provided in the first and second connector bodies and is provided to enable assembly of the connector body in cooperation with each other; Fiber optic splice configured to include. The method of claim 1, The main line 12 of one optical cable or the main line 12 of the ferrule 10 and the main line 22 of the other optical cable 20 are seated and fixed inside the connector body using a matching material or fusion-spliced, At least one of the first and second connector bodies 30 and 40 is provided with a main line passage 60 in which the main line to be connected is seated and supported. The method of claim 2, The first and second connector bodies 30 and 40 may include a coating part of one optical cable or a main line covering part 14 of the ferrule 10 and a main line coating part of the other optical cable 20 when the connector body is assembled. An optical fiber splice according to claim 1, further comprising a coating crimping portion (64) (66) for crimping and fixing the (24). The method of claim 3, The first and second connector bodies (30) (40) further comprises a flange crimping portion (62) for crimping and fixing the flange portion (16) of the ferrule when assembling the connector body. The method of claim 1, The connector body coupling means 50 is composed of the assembling protrusions 52 and the protrusion fixing grooves 54 formed to face each other on the first and second connector bodies 30 and 40, The side surface of the first and second connector body further comprises a recess 70 for disassembling the body. The optical fiber connector (1) according to any one of claims 1 to 5; And, Connector pressing means (110) for enclosing and pressing the optical fiber connector (1) to closely maintain the ferrule and the optical cable or the main line connection of the optical cables; Optical connector comprising a fiber optic connector configured to include. The method of claim 6, The connector pressing means 110, the push holder 130 is inserted and pressed into the assembled optical fiber connector (1); And, A frame-plug 150 to which the push holder 130 is assembled; Optical connector comprising a fiber optic connector, characterized in that configured to include. The method of claim 7, wherein The frame-plug 150 to which the optical cable is associated is further assembled and further includes a frame 170 to which the ferrule or the optical cable is associated. The frame 170 includes an optical fiber connector, characterized in that assembled to the housing (190). The method of claim 8, The flange 16 of the ferrule and the frame-plug 150 passing through the frame 170 by an outer edge of the optical fiber connector 1 inserted into the push holder 130 assembled to the frame-plug 150. An optical connector comprising an optical fiber connector, characterized in that the elastic member 230 is disposed between. The method of claim 8, The push holder 130 assembled to the frame plug further includes an operation protrusion 132 that protrudes through the openings 152 and 176 provided in the frame plug and the frame to enable push-pushing of the connector of the push holder. Equipped, The connector body 30 and 40 of the push holder 130 and the optical fiber connector 1 further includes surface contact portions 134 and 90 which are in surface contact with each other. . The method of claim 8, Inside the frame 170 is further provided with a rail portion 172 inserted into the rail groove 18 formed in the flange portion 16 of the ferrule, The frame-plug 150, the frame 170, and the housing 190 are provided with fastening protrusions 152 and 178 and fastening grooves 174 and 192 to which the fastening protrusions are fastened. An optical connector comprising an optical fiber connector, characterized in that. The method of claim 8, The optical fiber connector 1 inserted and pressed into the push holder may pass through the main line 22 and the frame 170 of the optical cable 20 passing through the frame-plug 150 and the push holder 130 assembled thereto. An optical connector comprising a fiber optic connector, characterized in that the main line (12) of the ferrule (10) is seated and fixed in a fusion-spliced state and configured as a field assembly type of the optical cable.

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