KR102255089B1 - Residential Node for Optical cable - Google Patents

Abstract

The present invention discloses an optical splitter for optical cables, which includes an optical adapter module, a case in which a fixing structure on which the optical adapter module is seated is disposed, and a cover covering the case, wherein the optical adapter module includes at least one optical adapter fixed to the fixing structure and having a screw pattern formed therein; a front end of the optical cable connected to one side of the optical adapter; and a rear end of the optical cable connected to the other side of the optical adapter. According to the present invention, there is no additional space for unnecessary tension reinforcement, thereby implementing a compact size.

Description

Optical splitter for optical cable {Residential Node for Optical cable}

The present invention relates to a splitter, and to an optical splitter for an optical cable that provides a more robust cable fixing structure and a compact size.

FTTH (Fiber To The Home) means connecting optical fiber to the house, and it is a type of high-speed giga internet facility. Also known as FTTP (Fiber to the premises). Since an optical cable is connected to the house and communicates with a laser beam, it is excellent in quality and speed. Compared to a copper-made coaxial cable, it is not affected by external weather, lightning, electricity, and radio waves.

Referring to FIG. 1, the FTTH use environment 10 refers to a network 12 that connects from the communication company's equipment room 11 to the modem in the premises of the home 13 with an optical cable 15, and the network 12 connected in this way. Through this, the home 13 can simultaneously receive a TPS (Triple Play Service: TV, Internet, telephone) service based on an unshielded twisted pair cable (UTP) connected to the optical cable 15. The communication company equipment room 11 may be connected to the home 13 Roset 400 through a distributor 19 (or an optical splitter, an optical splitter, etc.) connected by an optical cable 15. Since FTTH needs to newly build an expensive optical cable (15), in order to reduce the optical cable (15) when building the FTTH network (12), the distributor (19) (or RN (Splitter + enclosure), hereinafter referred to as RN) is called RN (19). ) The internal splitter serves to reduce the optical cable 15 by dividing the optical cable 15 of one strand into several strands.

RN(19) has various types of RN(19) depending on the purpose, but there is a pole type RN that is installed on a pole or wall, and there is a line type RN that is installed on an optical cable line. When 1 strand of optical cable enters RN(19), it is branched into 8 strands or 16 strands of optical cable through the splitter inside RN(19). It is done.

The optical cable branched through the splitter (15) is attached to the optical adapter inside the RN (19) for convenience of opening when Internet subscribers are opened. In general, the RN (15) is equipped with a splitter and optical cable to protect the splitter and optical adapter. It has a structure that wraps the adapter.

The RN 19 used in the conventional FTTH described above is a structure in which a structure for fixing an optical cable is connected in a push-pull type, so when a pressure acts on the structure for a long time, the fixing structure becomes loose or breaks, resulting in Network failure may occur. In order to prevent this, when a separate space for reinforcing the tensile force of the optical cable is provided inside the RN 19, there is a problem that the size of the RN 19 must be larger than necessary. In addition, even if a free space for reinforcing tensile force is provided, the push-pull type fixing structure ultimately has a problem in that the fixing structure may be damaged after a long time.

The present invention provides a more stable fixing structure by applying a screw-type adapter to an optical splitter for an optical cable to fix an optical cable or an optical cord, and for an optical cable that can form a compact size because there is no space for additional unnecessary tension reinforcement. It is to provide an optical splitter.

The optical splitter of the present invention for achieving the above object includes an optical adapter module, a case in which a fixed structure in which the optical adapter module is mounted, and a cover covering the case, and the optical adapter module is attached to the fixed structure. It characterized in that it comprises at least one optical adapter that is fixed to form a screw pattern, a front end of the optical cable connected to one side of the optical adapter, and a rear end of the optical cable connected to the other side of the optical adapter.

Here, the fixing structure comprises a side wall formed with a certain inclination upward from the bottom surface of the case, at least one hole penetrating through the front and rear surfaces of the side wall, and a screw pattern formed inside the at least one hole. do.

In particular, the optical adapter is coupled with a screw pattern formed inside the at least one hole and has a central body in which a hole is formed in the center, and is formed on one side of the central body and is formed larger than the size of a vertical cross section of the central body, and the center A wing portion including a hole connected to a hole of the body, a front end center disposed in the center of the wing portion and including a hole connected to the wing portion hole, and provided in a cylindrical tubular shape, coupled to the front end of the optical cable, and at the center of the front end. A front edge disposed to surround at least a portion, a hole formed on the other side of the center body and connected to the hole of the center body, and a rear end center formed to be symmetrical with the front center center with respect to the center body, the optical cable It is characterized in that it comprises a rear end edge that is coupled to the rear end and disposed to surround at least a portion of the center of the rear end.

Here, the optical splitter may further include a nut fastened to the central body while the optical adapter is inserted into at least one hole formed in the fixing structure.

Alternatively, the optical splitter may further include a cap structure disposed at a front end of the optical cable or a rear end of the optical cable and including a screw pattern capable of being coupled to a screw pattern formed outside the front edge or the rear edge.

Meanwhile, the optical adapter includes a support substrate fixed to one side of the fixing structure and having a hole formed at the center thereof, a hole formed in a first direction from the center of the support substrate and extending from the hole of the support substrate, and has a cylindrical tubular shape. A front end center provided as a front end, a front end edge coupled to the front end of the optical cable and disposed to surround at least a portion of the front end center, and a hole formed in a second direction from the center of the support plate and extending from the hole of the support substrate, The support substrate may include a rear end center formed symmetrically with the front end center, and a rear end edge coupled to the rear end of the optical cable and disposed to surround at least a portion of the rear end center.

In addition, the case includes a bottom surface, first to fourth sidewalls disposed at an edge of the bottom surface, and a groove through which one side of the fourth sidewall is removed to penetrate inside and outside, and the fixing structure includes the groove It characterized in that it is disposed on one side of the formed bottom surface.

In addition, the optical adapter module includes a plurality of optical adapters, and the plurality of optical adapters are arranged to be stacked in a direction perpendicular to the bottom surface.

According to the present invention, the occurrence of network failure can be suppressed by making the connection and fixing of the optical cable more robust, and unnecessary space waste for reinforcing the tensile force at the connection portion of the optical cable can be minimized.

1 is a diagram showing an example of a general FTTH environment.
2 is a diagram showing an example of an internal configuration of a repeater according to an embodiment of the present invention.
3 is a view showing an example of a structure in which the screw-type optical adapter of the present invention is disposed.
4 is a view showing an example of a structure in which a cover is arranged to cover a case in an optical splitter including a screw-type optical adapter of the present invention.
5 is a view showing an example of a screw-type optical adapter structure according to an embodiment of the present invention.
6 is a view showing an example of another structure of a screw-type optical adapter according to an embodiment of the present invention.
7 is a view showing an example of another form of a case of an optical splitter according to an embodiment of the present invention.
8 is a view showing an example of a line type optical splitter to which a screw type optical adapter according to an embodiment of the present invention is applied.
9 is a view showing an example of a Roset to which the screw type optical adapter according to an embodiment of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those of ordinary skill in the art without departing from the technical gist of the present invention.

The terms or words used in the present specification and claims described below should not be construed as being limited to a conventional or dictionary meaning, and the inventor is appropriate as a concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention on the basis of the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all the technical ideas of the present invention, and various equivalents that can replace them at the time of application And there may be variations.

Hereinafter, exemplary embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 2 is a view showing an example of an internal configuration of a repeater according to an embodiment of the present invention, and FIG. 3 is a view showing an example of a structure in which the screw-type optical adapter of the present invention is disposed. 4 is a view showing an example of a structure in which a cover is arranged to cover a case in an optical splitter including a screw-type optical adapter of the present invention.

2 to 4, the optical splitter 100 of the present invention may include a case 110, a support frame 130, a cover 120, a splitter 140, and an optical adapter module 200. have. In the optical splitter 100 of this structure, at least a portion of the at least one optical adapter 210 included in the optical adapter module 200 is provided in a screw type, so that one end of the optical cable 19 can be coupled with a screw method. . Accordingly, as the one end of the optical cable 19 is firmly fixed to the optical adapter 210, the contact failure of the optical cable 19 is prevented, and there is no need to provide a separate space for the connection of the optical cable 19, making it compact. It supports to configure the size of the case 110, the support frame 140, and the cover 120.

The case 110 includes a bottom surface 115, a first side wall 111, a second side wall 112, a third side wall 113, and a fourth side wall 114, and is provided in a shape that is opened upward. Can be. The first sidewall 111 may be disposed in a direction perpendicular to the bottom surface 115 from the first one side edge of the bottom surface 115 or in a direction having a predetermined inclination upward with respect to the bottom surface 115. have. One side of the second sidewall 112 may be connected to the first sidewall 111, and a lower portion of the second sidewall 112 may be formed to extend from an edge of the second side of the bottom surface 115. While one side of the third sidewall 113 is connected to the second sidewall 112, a lower portion of the third sidewall 113 may be formed to extend from an edge of the third side of the bottom surface 115. The fourth side wall 114 is formed by having one side connected to the third side wall 113 and the other side being connected to the other side of the first side wall 111, and the lower side extending from the fourth side edge of the bottom surface 115. I can. The case 110 may be determined as a box shape having a hollow center and opening upward. A hinge structure or a hinge structure connected to the cover 120 may be disposed on at least one of the side walls 111, 112, 113, and 114. At least a part of the optical adapter module 200 may be disposed on the bottom surface 115 of the case 110, for example. In addition, at least some grooves or protrusions in which the support frame 130 is disposed may be disposed inside the case 110. Alternatively, at one side of the case 110, a groove or a protrusion may be arranged to be hinged so that at least a portion of the support frame 130 may be hinged. At least a portion of the case 110 may include a plastic structure. In addition, the case 110 may further have a gasket disposed in an area adjacent to the side walls 111, 112, 113 and 114 to block the inflow of moisture or foreign substances. The size of the upper open area of the case 110 or the rim formed by the sidewalls 111, 112, 113, and 114 may be formed equal to or smaller than the size of the cover 120.

The support frame 130 may be formed with a flat top surface and a predetermined thickness. At least a portion of the support frame 130 may be formed of the same material as the case 110. At least a part of the support frame 130 may be mounted and fixed inside the case 110. Alternatively, one side of the support frame 130 may be disposed to be coupled to the inner side of the case 110 to perform a hinge operation. At least a part of the splitter 140 may be disposed on one surface (eg, the rear surface) of the support frame 130. At least a part of the optical adapter module 200 may be disposed on the front surface of the support frame 130. On the other hand, the support frame 130 is disposed to be spaced apart from the bottom surface 115 of the case 110 at a predetermined interval, and is a structure for securing a space in which various optical distributors 100 elements can be arranged, and the case 110 When the size of the optical splitter 100 is large enough to allow all the elements of the optical splitter 100 to be disposed, or the components of the optical splitter 100 are manufactured to be small, the configuration of the support frame 130 may be omitted.

The cover 120 may be provided to cover the opening area of the case 110. To this end, the size of the cover 120 may be larger than the size of the opening area of the case 110. The cover 120 may be formed of the same material as the case 110, for example, a plastic structure. A gasket is provided on at least a portion of an area of the cover 120 in contact with the upper end of the sidewalls 111, 112, 113, 114 of the case 110, for example, in the process of covering the case 110, the case 110 By completely closing the opening of the case 110 from the outside it is possible to block the inflow of foreign matter or moisture into the interior.

The splitter 140 may be configured to separate the optical cable 19 into a plurality of lines. The splitter 140 may separate one optical cable 19 strands into various numbers, such as 8, 16, 24, depending on the purpose of the optical splitter 100. The splitter 140 may be disposed on the rear surface of the support frame 130, and may be disposed on the bottom surface 115 or at least one sidewall of the case 110 according to the intention of the designer.

The optical adapter module 200 may be disposed on at least one side inside and outside the case 110. The optical adapter module 200 may serve to fix the optical cable 19. In this regard, the optical adapter module 200 may include at least one optical adapter 210, front ends 220 of an optical cable connected to the optical adapter 210, and rear ends 230 of an optical cable. At least a portion of the optical adapter 210 may have a screw pattern formed thereon. The screw pattern formed on the optical adapter 210 may be provided in a shape corresponding to a fastening structure disposed at an end of the optical cable 19. The optical cable front ends 220 may include at least one of the optical cables 19 connected to the communication company's equipment room 11. The optical cable front ends 220 may be coupled to one side of the optical adapter 210. In this regard, a coupling structure including a screw pattern corresponding to one side of the optical adapter 210 may be formed on the front ends 220 of the optical cable. The rear ends 230 of the optical cable may be arranged such that one side is connected to the optical adapter 210 and the other side is connected to another electronic device element. A plurality of optical adapters 210 may be continuously arranged in parallel on the bottom surface 115 of the case 110. One side of the optical adapters 210 may be disposed to face one sidewall (for example, the fourth sidewall 114). In this regard, a fixing structure 116 to which the optical adapters 210 may be fixed may be formed on one side of the case 110. The fixing structure 116 may be formed on one of the side walls 111, 112, 113 and 114, for example, a portion of the fourth side wall 114. In the optical adapters 210, the fixing structure 116 is fixed, the optical cable front ends 220 are located in the outer direction of the fourth side wall 114, and the optical cable rear ends 230 are the fourth side wall 114 In order to be located in the inner direction of the case 110, it may be disposed on the fixed structure 116 in a form penetrating inside and outside the case 110. In this regard, the fixing structure 116 may be formed as a hole or groove penetrating the inner and outer surfaces of the fourth sidewall 114. At least a portion of the fixing structure 116 may have a screw pattern that meshes with the screw patterns formed on the optical adapters 210. As the front ends 220 of the optical cable and the rear ends 230 of the optical cable are fastened and fixed with the optical adapters 210, they are formed to be spaced apart from the bottom surface of the case 110 by the optical adapters 210 by a predetermined distance. They can be placed side by side between each other.

Meanwhile, in the illustrated drawing, the optical adapter module 200 illustrates a structure in which a plurality of optical cable front ends 220 and a plurality of optical cable rear ends 230 are arranged based on a plurality of optical adapters. It is not limited. For example, the optical adapter module 200 includes only one optical adapter 210, has a front end of one optical cable connected to the one optical adapter 210, and one side is the optical cable through the optical adapter 210. While connected to the front end, the other side may include a rear end of the optical cable connected to the splitter 140.

As described above, the optical splitter 100 to which the screw-type optical adapter 210 is applied has a strong self-tensioning force of the fixed structure through screw fastening (e.g., experimentally measured 10 times or more stronger than the push-pull type), optical cables (19) As a separate device and space for fixing are not required, network failure due to separation of optical adapters and optical cords (or optical cables) caused by vibrations and wind-induced vibrations due to the characteristics of RNs mainly installed on electric poles is prevented in advance. Can be prevented. In addition, the optical splitter 100 to which the screw-type optical adapter 210 is applied can be manufactured 30% smaller than that of the existing RN, reducing the occurrence of various civil complaints according to the size, and enabling cost reduction due to size reduction compared to the existing RN. can do.

5 is a view showing an example of a screw-type optical adapter structure according to an embodiment of the present invention.

5, the screw type first optical adapter 210a includes a center body 211, a wing part 212, a front edge 213, a front center 214, and a rear edge 215, and additionally , It may include a rear end central portion 216 formed in the central portion of the rear edge 215. At least part of the first optical adapter 210a may be made of a metal material (eg, aluminum or aluminum alloy) in order to maintain rigidity of a predetermined size or more.

The central body 211 may have a hole penetrating in the x-axis direction, and may include a flat area that can be gripped by a tool on the outside, and a curved area in which a screw pattern is formed while continuing to the flat area. The size of the hole may have a size corresponding to the size of the optical cable 19 passing through it. The central body 211 is disposed through the hole of the fixing structure 116 formed on one side of the case 110, and can firmly fix the optical adapter to the fixing structure 116 through a separate fixing member, for example, nut coupling. have. The nut may include a screw pattern formed on the outer surface of the central body 211 and a pattern capable of being screwed together.

The wing part 212 is disposed on one side of the center body 211, for example, at an edge in the -x-axis direction, and has a cross-sectional size larger than the size of the z-axis cross-section of the center body 211, and the center is the center Holes having the same size as the holes formed in the body 211 may be formed. A gear pattern that can be used to couple the optical adapter 210a may be formed on the edge of the wing part 212. When the gear pattern is gripped by the tool, it may contribute to preventing the tool from spinning.

The shear rim 213 may be provided in a ring shape so that the center surrounds the empty cylindrical shear center 214. The outer surface of the front edge 213 may have a screw pattern that can be fastened to a cap (eg, a screw pattern is formed inside the cap) formed on the front ends 220 of the optical cable to be connected. At least a portion of the front edge 213 may be removed to form an opening or a groove. The inside of the shear edge 213 may be provided in a plain pattern without a separate pattern. The z-axis cross-sectional size of the shear edge 213 may be smaller than the z-axis cross-sectional size of the wing part 212 or the z-axis cross-sectional size of the central body 211. One side of the shear edge 213 may include a cutout portion formed to expose at least a portion of the shear center 214. The cutout may be used to fasten the cap structure formed at one end of the optical cable to the front end center 214.

The front end center 214 may be provided in the shape of a cylindrical tube in which the center is hollow in the form of a hole. The front end center 214 may be disposed at the center of the front end edge 213. The central hole of the front end central portion 214 may be formed to be continuous with the center of the rear end central portion 216 located at the center of the rear end edge 215 of the wing portion 212 and the central body 211. The size of the central hole of the front end center 214 may have the same size as the size of the optical cable 19 or larger than the diameter of the optical cable 19 for ease of insertion of the optical cable 19. The outer surface of the shear center 214 may be formed to be spaced apart from the inner surface of the shear edge 213 by a predetermined distance.

The rear edge 215 may be formed on the other side of the center body 211 (eg, an edge opposite to the center body 211 on which the wing portions 212 are disposed). The shape of the rear edge 215 may be formed substantially the same as the front edge 213. For example, a cutout may be formed on one side of the rear edge 215.

The rear end center 216 is formed on the other side of the center body 211 (for example, an edge opposite to the center body 211 where the wing part 212 is disposed), and is disposed at the inner center of the rear edge 215. I can. The shape of the rear central portion 216 may be formed to be the same as or similar to the front portion central portion 214. The rear ends 230 of the optical cable may be fixed to the rear center 216 and the rear edge 215 by inserting and screwing.

6 is a view showing an example of another structure of a screw-type optical adapter according to an embodiment of the present invention.

6, the screw-type second optical adapter 210b includes a support substrate 221a, a shear edge 223 formed in the ?x-axis direction of the support substrate 221a, a shear center 224, and a fastening groove. It may include 222, the fastening member 225. Additionally, the second optical adapter 210b may further include a rear edge and a rear central portion formed symmetrically on the x-axis with respect to the support substrate 221a on the x-axis direction side of the support substrate 221a. .

The support substrate 221a may have a predetermined shape, for example, a shape having a predetermined thickness in which the z-axis cross-section is a square. At least a portion of the support substrate 221a may be made of a metal material. A front edge 223, a front center 224, a rear edge, and a rear edge extending in the ?x-axis or axial direction may be disposed in the center of the support substrate 221a.

At least one of the fastening grooves 222 may be disposed at a corner of the support substrate 221a. The fastening grooves 222 may be formed lower than the surface of the adjacent support substrate 221a. The size of the fastening groove 222 may be formed at least larger than the header portion of the fastening member 225. A hole penetrating in the x-axis direction may be formed in the bottom surface of the fastening groove 222. At least a part of the fastening member 225 may be inserted into the hole penetrating in the x-axis direction.

The fastening member 225 is connected to a body having at least a portion disposed through the fastening hole formed on the bottom surface of the fastening groove 222, and is connected to one end of the body and at least partially seated in the fastening groove 222. May contain headers. The fastening member 225 may be, for example, in the form of a screw.

The shear rim 223 may be provided in the same or similar shape as the shear rim 213 described in FIG. 5. The shear center 224 may be provided in the same or similar shape as the shear center 214 described in FIG. 5.

7 is a view showing an example of another form of a case of an optical splitter according to an embodiment of the present invention.

Referring to FIG. 7, the overall shape of the case 110a may be provided in the same or similar shape as the case 110 described in FIG. 3. For example, the case 110a has the same or similar shape as the bottom surface 115, the first sidewall 111, the second sidewall 112, and the third sidewall 113 of the case 110 described in FIG. 3 above. It may include a bottom surface, a first sidewall, a second sidewall, and a third sidewall. The fourth sidewall 114 may be provided in a slightly different shape from the sidewall of the case 110. For example, in the structure of the optical splitter 100 described in FIG. 3 above, it has been exemplified that the position where the optical adapters 210 are disposed is on the fourth sidewall 114, but the case of the optical splitter according to another embodiment of the present invention ( 110a) may include an optical adapter module 200 disposed at a position spaced apart from the fourth sidewall 114 in the direction of the center by a predetermined distance. In addition, in the fourth sidewall 114, a through portion or a groove passing through the inside and outside of the fourth sidewall 114, which can be connected to the external optical cable 19, of the optical cable front ends 220 of the optical adapter module 200 Can be formed. The groove formed in the fourth side wall 114 of the case 110 may form a hole shape while the cover 120 is covered on the upper portion of the case 110.

As the optical adapter module 200 is oriented toward the center of the case 110, the fixing structure 116 for fixing the optical adapter module 200 may also be oriented toward the center of the case 110. The fixing structure 116 may be a structure to which at least one of the optical adapter modules 200 can be fixed. For example, the fixed structure 116 includes a sidewall structure extending from the bottom surface 115 of the case 110 by a predetermined height in the opening direction, and penetrating the front and rear surfaces of the sidewall structure (or parallel to the bottom surface 115). It may include a plurality of holes penetrating the sidewall structure in a direction. A specific screw pattern may be formed in the plurality of holes to be fastened with a screw pattern formed in the central body 211 of the optical adapter 210. Alternatively, the plurality of holes are formed as holes equal to the size of the front edge 213 and 223 described in FIG. 6 or larger than the size of the front edge 213 and 223, and the rear edge 215 and the rear center 216 ) Is disposed therethrough, and the support substrate 221a of the second optical adapter 210b may be coupled to the sidewall structure.

The optical adapter module 200 may include optical adapters 210, front ends 220 of an optical cable, and rear ends 230 of an optical cable, similar to the structure described in FIG. 3. The optical adapters 210 may be fixedly disposed on the fixing structure 116 described above.

8 is a view showing an example of a line type optical splitter to which a screw type optical adapter according to an embodiment of the present invention is applied.

Referring to FIG. 8, the line type optical splitter 300 may include a case 310, an upper cover 320, and a support frame 330. The cover 320 may be hinged to the outside of the case 310 to cover or open the opening surface of the case 310. The support frame 330 may be coupled to at least a portion of the inner side of the case 310 and may operate to cover or open at least a portion of the splitter 340 disposed inside the case 310. The cover 320 may cover the opening surface of the case 310 while the support frame 330 is disposed to cover the splitter 340. A first optical adapter module 200sa may be disposed on one side of the case 310 (eg, a left edge), and a second optical adapter module 200sb may be disposed on the other side (eg, a right edge). A first fixing structure 316a for fixing at least one of the first optical adapter modules 200sa and a second fixing structure for fixing at least one of the second optical adapter modules 200sb (316b) may be disposed on at least one side of the bottom surface of the case 310. At least one of the optical adapters included in the first optical adapter module 200sa and the second optical adapter module 200sb may be formed of a metal material, and may include a screw pattern. As described above, by applying a screw pattern to the optical adapter modules 200sa and 200sb to which the optical cable is connected, the line type optical splitter 300 of the present invention may be fixed by screw coupling with the optical cable.

9 is a view showing an example of a Roset to which the screw type optical adapter according to an embodiment of the present invention is applied.

Referring to FIG. 9, the Roset 400 according to the embodiment of the present invention is disposed at one end of the household 13, as described in FIG. 1 above, and one side is connected to the optical cable 19, and the other side is UTP ( 17) can be configured to be connected. As shown, the Roset 400 includes a bottom surface 415, a first side wall 411, a second side wall 412, a third side wall 413, and a fourth side wall 41, in the z-axis direction. It may include a case 410 provided in the shape of an opened box. Additionally, the roset 400 may further include a cover disposed to cover the opened surface of the case 410 in the z-axis direction.

A groove 414a in which optical adapters 200ra and 200rb may be disposed may be formed in one of the sidewalls of the case 410, for example, the fourth sidewall 414. The groove 414a is formed in a portion of the fourth sidewall 414, and the size of the groove 414a may be formed corresponding to the size and opening of the optical adapters 200ra and 200rb placed thereon. The groove 414a may be formed to pass through the y-axis and ??y-axis back and forth, for example. At least some of the optical adapters 200ra and 200rb may be disposed in the groove 414a. As another example, at least one hole formed in a direction passing through the y-axis or ??y-axis may be formed in the fourth sidewall 414. A screw pattern may be formed inside the hole to mesh with a screw pattern provided in the optical adapters 200ra and 200rb.

The optical adapters 200ra and 200rb may include a first optical adapter 200ra and a second optical adapter 200rb fixed to the groove 414a (or hole) of the case 410. As an example, the first optical adapter 200ra is disposed close to the bottom surface of the groove 414a, and the second optical adapter 200rb is an upper portion of the first optical adapter 200ra (eg, z-axis It may be disposed in a groove or a hole formed on the upper part of the direction). That is, the optical adapters 200ra and 200rb may have a structure stacked in the z-axis direction. In the illustrated drawing, a structure in which two optical adapters 200ra and 200rb are stacked in the z-axis direction perpendicular to the bottom surface 415 of the case 410 is illustrated, but the present invention is not limited thereto. For example, one optical adapter or three or more optical adapters may be disposed on one side of the fourth sidewall 414 of the case 410. One side (eg, portions exposed to the outside) of the optical adapters 200ra and 200rb having the screw pattern formed therein may be fixed in a screw type while an optical cable having a cap structure having a screw pattern formed thereon is inserted therein. A UTP cable is connected to the other side of the optical adapters 200ra, 200rb, for example, a portion disposed inside the case 410, and a cap structure having a screw pattern is disposed at the end of the UTP cable, so that the optical adapters 200ra , 200rb) and can be screwed together.

As described above, when the screw type optical adapter according to the embodiment of the present invention is applied to the RN, it is possible to provide a tensile reinforcement characteristic of about 10 times that of the conventional push/full type general optical adapter. Network failure due to optical code departure can be prevented in advance. In addition, when applying the screw-type optical adapter of the present invention to RN, there is no need for a separate optical cord space for reinforcing tensile force compared to the existing RN, so it can be manufactured in a size 30% smaller than that of the existing RN, and without using a separate cap. Therefore, it is possible to provide convenience of installation and maintenance, and various benefits according to size reduction, such as prevention of civil complaints according to size, and cost reduction can be achieved.

On the other hand, the embodiments disclosed in the specification and drawings are only presented specific examples to aid understanding, and are not intended to limit the scope of the present invention. It is obvious to those of ordinary skill in the art that other modifications based on the technical idea of the present invention may be implemented in addition to the embodiments disclosed herein.

10: FTTH environment
100: optical splitter
110: case
120: cover
116, 316a, 316b, fixed structure
130: support frame
140, 340: splitter
200, 200sa, 200sb: optical adapter module
210, 210a, 210b, 200ra, 200rb: optical adapter
220: fiber optic cable shear
230: the rear end of the optical cable
211: central body
212: wing
213, 223: shear border
214, 224: center of shear
215: trailing edge
216: rear center
221: support substrate

Claims (8)

Optical adapter module;
A case in which a fixing structure in which the optical adapter module is mounted is disposed;
Includes; a cover covering the case,
The optical adapter module
At least one optical adapter fixed to the fixed structure and having a screw pattern formed thereon;
A front end of an optical cable connected to one side of the optical adapter;
Including; a rear end of the optical cable connected to the other side of the optical adapter,
The fixed structure is
A side wall formed with a certain inclination upward from the bottom surface of the case;
At least one hole penetrating the front and rear surfaces of the sidewall;
Including; a screw pattern formed inside the at least one hole,
The optical adapter
A central body coupled with a screw pattern formed inside the at least one hole and having a hole formed in a central portion;
A wing portion formed on one side of the central body, formed larger than a size of a vertical section of the central body, and including a hole connected to the hole of the central body;
A front end center disposed in the center of the wing portion, including a hole connected to the wing portion, and provided in a cylindrical tubular shape;
A shear edge coupled to the front end of the optical cable and disposed to surround at least a portion of the center portion of the front end;
A rear end center formed on the other side of the center body and including a hole connected to the hole of the center body, and formed symmetrically with the front end center with respect to the center body;
And a rear end edge coupled to the rear end of the optical cable and disposed to surround at least a portion of the center of the rear end. delete delete The method of claim 1,
And a nut fastened to the central body while the optical adapter is inserted into at least one hole formed in the fixing structure. The method of claim 1,
An optical splitter for an optical cable, further comprising: a cap structure disposed at a front end of the optical cable or a rear end of the optical cable, and including a screw pattern capable of being coupled with a screw pattern formed outside the front edge or the rear edge. The method of claim 1,
The optical adapter
A support substrate fixed to one side of the fixed structure and having a hole formed in the center thereof;
A shear center formed in a first direction from the center of the support substrate, including a hole and a hole extending from the support substrate, and provided in a cylindrical tubular shape;
A shear edge coupled to the front end of the optical cable and disposed to surround at least a portion of the center portion of the front end;
A rear end center formed in a second direction from the center of the support substrate, including a hole extending from the support substrate, and symmetrically formed with the front end center relative to the support substrate;
And a rear end edge coupled to the rear end of the optical cable and disposed to surround at least a portion of the center of the rear end. The method of claim 1,
The above case is
Bottom side;
First to fourth sidewalls disposed at an edge of the bottom surface;
Including; a groove through which one side of the fourth side wall is removed to penetrate the inside and outside,
The fixed structure is an optical splitter for an optical cable, characterized in that disposed on one side of the bottom surface in which the groove is formed. The method of claim 7,
The optical adapter module
Including a plurality of optical adapters,
The plurality of optical adapters
An optical splitter for an optical cable, characterized in that it is arranged to be stacked in a direction perpendicular to the bottom surface.

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