KR100850925B1 - Fiber Optic Integrated Fiber Optic Tap - Google Patents

Abstract

The present invention relates to an optical fiber integrated optical adapter, which can be miniaturized and reduced in cost by integrating the optical fiber to the optical adapter, and smoothly processes the outer surface of the first housing in which the optical fiber is inserted and fixed to the second housing. The optical fiber integrated optical adapter is structurally secured by being prevented from being separated.

To this end, the present invention is an optical fiber integrated optical adapter in which the optical fiber is integrally assembled on one side, and the optical connector is detachable on the other side, the ferrule is enclosed in the ferrule holder having an end portion of the optical fiber and a radially formed protrusion on the bottom outer surface thereof. A first housing including a spring installed to surround the ferrule holder, a first coupling member accommodating the ferrule holder and the spring in a hollow shape, and a head portion integrally inserted into the first coupling member, the first housing including: Located in the lower portion of the sleeve to receive the ferrule exposed from the ferrule holder in the cylindrical shape, the hollow housing receives one side of the sleeve and is inserted and fixed to the first coupling member of the first housing and the protrusion of the ferrule holder inside one side And a flange formed on the outer circumference of the other side of the second coupling member, the second coupling member including a protrusion seating groove on which the shaft is seated. A second housing, a sleeve for accommodating the other side of the sleeve, and a connector clip including a detachable means for attaching and detaching the optical connector, and a mounting groove is provided in one side to seat the connector clip, and one side of the flange of the second housing. Disclosed is an optical fiber integrated optical adapter comprising a third housing coupled thereto.

Description

Optical Fiber Integrated Optical Taper {OPTICAL ADAPTER WITH COMBINED OPTICAL FIBER}

The present invention relates to an optical fiber integrated optical adapter, and more particularly, it is possible to reduce the size and cost by integrating the optical fiber to the optical adapter and to reduce the cost, and to insert an optical fiber into an outer surface of the first housing fixed to the second housing. The present invention relates to an optical fiber integrated optical adapter in which structural stability is secured by smoothly preventing components from being separated.

In general, optical communication is a communication method for transmitting information by transmitting light through a double glass optical fiber, which can transmit tens of thousands of times more information than electric communication using a coaxial cable. In addition, optical communication is a trend that is currently being used in various communication and industrial fields because the information transmission state is good because there is no interference by external electromagnetic waves. For example, a home network service based on FTTH (Fiber To The Home) is a typical application of optical communication.

Typically, an optical fiber is connected to the end of the optical connector is made to facilitate the coupling and separation of the optical fiber. Such optical connectors are made of various types such as SC, FC, ST, LC, MU, EC, SMA, MT, and FDDI depending on the arrangement of the optical fibers to be coupled. In this case, the optical connectors are interconnected by optical adapters to facilitate the alignment of the core interfaces in order to prevent transmission loss at the core interface of the optical fiber when connected to other optical connectors. Accordingly, the optical connector and the optical adapter are installed in the middle of the line installed at a distance of several tens of meters to several tens of kilometers or more and are used for branching of the optical fiber.

1 is an exploded perspective view illustrating a method of connecting an optical fiber according to the conventional method, and FIG. 2 is a combined perspective view of FIG. 1.

As shown in FIGS. 1 and 2, the first and second optical connectors 21, 22, to which the first and second optical fibers 11, 12 are coupled, are interconnected via an optical adapter 30. . As shown, the first and second optical connectors 21, 22 are coupled in a push-pull fashion with the first and second optical fibers 11, 12, respectively, aligned by ferrules (not shown). It is SC type. In this case, the optical adapter 30 interconnecting the first and second optical connectors 21 and 22 includes external housings 30a and 30b, one end of which is open at both sides thereof to accommodate them, and the external housings 30a, 30b) is a sleeve for guiding the cores of the first and second optical fibers 11 and 12 and the coupling member (not shown) configured to easily detach the first and second optical connectors 21 and 22, respectively. (Not shown) and the like provided therein. Accordingly, the first and second optical connectors 21 and 22 are coupled to both ends of the optical adapter 30, respectively, and the core wires of the first and second optical fibers 11 and 12 are respectively inside the optical adapter 30. Aligned.

However, in the above-described coupling method of the optical fiber, when the mounting or detaching of the first and second optical connectors 21 and 22 is repeatedly performed from the optical adapter 30, the coupling member (not shown) installed inside the optical adapter 30 C) and the sleeve (not shown) have a problem in that it is deformed or worn. In particular, the coupling member (not shown) formed for attachment and detachment of the first and second optical connectors 21 and 22 is more likely to be deformed because it is made of a grip shape that can be elastically deformed. Therefore, the first and second optical connectors 21 and 22 may not be stably coupled due to deformation and wear of the optical adapter 30, and core wires between the first and second optical fibers 11 and 12 may be accurately formed. There is a problem that cannot be supported. Of course, the optical adapter 30 can be repaired and replaced as necessary, but when manufacturing the optical adapter 30, such as a coupling member (not shown) and a sleeve (not shown) inside the outer housing (30a, 30b) Since it must be assembled one by one, there was a problem that the cost increases accordingly.

On the other hand, as described above, the optical adapter 30 interconnecting the first and second optical connectors 21 and 22 is typically a splitter (not shown) of a line constructed between a communication provider and a subscriber. Multiple can be installed. The conventional optical adapter 30 has a structure in which the first and second optical connectors 21 and 22 are detached at both ends thereof, and thus, the splitter and the branch of the optical fiber are limited in size and shape because the volume occupies the inside of the splitter relatively large. There was a problem in that wiring was restricted.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide an optical fiber integrated optical adapter capable of miniaturization and cost reduction by integrating an optical fiber with an optical adapter.

In addition, the present invention provides a fiber-optic integrated optical adapter with improved optical stability by ensuring structural stability by preventing the separation of parts after the assembly is integrally processed by smoothly processing the outer surface of the first housing fixed to the second housing is inserted into the optical fiber There is another purpose to provide.

Optical fiber integrated optical adapter according to the present invention In the optical fiber integrated optical adapter (100, 1100) in which the optical fiber 110 is integrally assembled on one side and the optical connector (200) is detachable on the other side, the ends of the optical fiber (110) are wrapped, and are radially formed on the lower outer surface. Ferrule 120 accommodated in the ferrule holder 122 having a protrusion 121, the spring 130 is installed to surround the ferrule holder 122, the ferrule holder 122 and the hollow inside A first housing 140 including first coupling members 141 and 1141 for accommodating the spring 130 and head portions 143 and 1142 integrally inserted into the first coupling members 141 and 1141. 1140, located in the lower portion of the first housings 140 and 1140, a sleeve 150 accommodating the ferrule 120 exposed from the ferrule holder 122 in a cylinder shape, and a hollow inside It accommodates one side (150a) of the sleeve 150, the first coupling member (141, 1141) of the first housing (140, 1140) Second coupling members 161 and 1161 which are inserted and fixed and include protrusion mounting grooves 161b and 1161b on which the protrusion 121 of the ferrule holder 122 is mounted, and the second coupling member 161. Second housings 160 and 1160 including flanges 162 and 1162 formed on the outer circumference of the other side 1161, a sleeve accommodating portion 171 to accommodate the other side 150b of the sleeve 150, and the optical connector 200. The connector clip 170 including a detachable means 172 for attaching and detaching a seat and a mounting groove 181a is provided in one side 181 to seat the connector clip 170, and the one side 181 is formed of the connector clip 170. And a third housing 180 coupled to the flanges 162 and 1162 of the two housings 160 and 1160. In this case, the outer circumferential surface of the first coupling member 140 is smoothly formed in the first housing 140, and at least one surface has an angled pillar shape between the first coupling member 140 and the head part 143. The rotating unit 142 further includes an inner circumferential surface of the first coupling member 141 and an outer circumferential surface of the second coupling member 161 of the second housing 160. It can be coupled using any one of, pin coupling, fixed ring coupling and coder coupling.

In addition, the second coupling member 1161 may have protrusions 1161a formed on an outer surface thereof, and the first coupling member 1141 may have a smooth outer surface formed thereon, and the protrusions 1161a may be inserted into and fixed from the inner surface to the outer surface thereof. and a protrusion opening 1141a formed of a hole, and a flexible groove 1141b is formed at an end of the first coupling member 1141 such that the first coupling member 1141 is temporarily opened. The protrusion 1161a may be elastically bound to the opening 1141a.

In addition, the first housings 140 and 1140 are integrally formed between the first coupling members 141 and 1141 and the head parts 143 and 1142, and have a diameter greater than that of the head parts 143 and 1142. It further comprises a small hook (144, 1143), the protective neck 190 may be fitted to the hook (144, 1143) to surround the head portion (143, 1142).

In the present invention, the optical connector 200 may be any one of SC, FC, LC, and ST.

The optical fiber integrated optical adapter according to the present invention includes a first housing and a second housing fastened by screw coupling in an optical connector connection structure, and thus can be miniaturized by integrally forming an optical fiber in the optical adapter without a separate optical connector.

 In addition, the present invention provides a miniaturized optical fiber integrated optical adapter, the wiring and branching of the optical fiber is relatively free within the confined space, and the one side connected to the optical fiber does not cause problems due to frequent detachment and detachment of the optical connector. It has a stable effect.

In addition, the present invention does not need to assemble the optical connector and the optical adapter separately for the branching and wiring of the optical fiber has the effect of reducing the assembly cost of the component.

In addition, the present invention has the effect of ensuring the structural stability by improving the reliability by preventing the departure of the parts after the optical fiber is inserted into the assembly is integrally processed by smoothly processing the outer surface of the first housing fixed to the second housing.

In addition, the present invention can be modified by the third housing coupled to the second housing and the connector clip seated thereon, there is an effect that the various types of optical connector can be attached and detached.

In addition, the present invention is formed so that the projection opening and the projection to each other in the first housing and the second housing corresponding to each other, there is an effect that can be assembled relatively simply without using a tool such as a spanner.

Hereinafter, an optical fiber integrated optical adapter according to the present invention will be described in detail with reference to the accompanying drawings and embodiments. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

First, an optical fiber integrated optical adapter according to an embodiment of the present invention will be described.

Referring to FIG. 3, there is shown a combined perspective view showing a state in which an optical connector is mounted on an optical fiber integrated optical adapter according to an embodiment of the present invention.

As shown in Figure 3, the optical fiber integrated optical adapter 100 according to an embodiment of the present invention, the optical fiber 110 is integrally assembled on one side, the optical connector 200 is detachably coupled to the other side. The optical fiber integrated optical adapter 100 to which the optical connector 200 is coupled is fixed to a circuit board 300 such as a splitter (not shown) via a coupling member 400 such as a bolt. The other side (not shown) of the optical fiber 110 connected to the optical fiber integrated optical adapter 100 may be connected to the same optical fiber integrated optical adapter 100 or another type of optical connector, but is not limited thereto. . As shown, the optical connector 200 mounted on the optical fiber integrated optical adapter 100 is an SC (Subscriber Connector or Square Connector) in which the ferrule-type optical fiber is arranged, for example, Fiber transmission system connector (FC) Also, the LC (Lucent Connector) and the ST (Straight Tip) or equivalent may be replaced by an optical connector and the present invention is not limited to the type of optical connector 200 mounted on the optical fiber integrated optical adapter 100. In addition, the optical fiber integrated optical adapter 100 may be changed in some structures corresponding to the type of the optical connector 200 described above, but since the optical connector 200 can be modified by the person skilled in the art of the optical connector 200 Detailed description of the modification of the optical fiber integrated optical adapter 100 according to the type will be omitted. The optical fiber integrated optical adapter 100 according to the present invention has one side integrated with the optical fiber 110, and the assembly parts are relatively reduced as compared to the optical adapter that attaches or detaches the optical connector on both sides, thereby reducing manufacturing costs. have. In addition, since the optical fiber integrated optical adapter 100 is relatively small in size, branching and arranging of the optical fiber 110 can be more freely and structurally stable when applied to a splitter or the like. Hereinafter, the optical fiber integrated optical adapter 100 of the present invention will be described in more detail with reference to other drawings.

4 is an exploded perspective view of an optical fiber integrated optical adapter 100 according to an embodiment of the present invention, and FIG. 5 is an exploded cross-sectional view of the optical fiber integrated optical adapter 100 of FIG. 4 taken along line AA ′. It is. FIG. 6 is a cross-sectional view illustrating the coupling of the optical fiber integrated optical adapter 100 of FIG. 4, and FIG. 7 illustrates a coupling surface of the second housing and the third housing of the optical fiber integrated optical adapter 100 according to the present invention. Partially coupled perspective is shown.

4 to 7, the optical fiber integrated optical adapter 100 includes the optical fiber 110, the ferrule 120, the spring 130, the first housing 140, the sleeve 150, and the second housing ( 160, the connector clip 170, the third housing 180, and the protective rubber 190. According to the present invention, the ferrule 120, the spring 130, the first housing 140 and the protective rubber 190 are inserted into the optical fiber 110, and the connector clip 170 and the third housing are inserted into the second housing 160. After assembling the 180 first, the first housing 140 and the second housing 160 are integrally formed, so that the connection of the optical fiber 110 is miniaturized, structurally stable, and assembly costs are reduced. The optical fiber integrated optical adapter 100 may be provided.

First, the optical fiber 110 is an optical fiber made of a glass material to allow total reflection of light, and a cladding and a protective coating of a core 110c having a size of several to several tens of micrometers (μm) are provided. It consists of a wrapping structure. One side (110a) of the optical fiber 110 is assembled as described below is made of an optical fiber integrated optical adapter 100, the other side (110b) is formed of the same integrated optical adapter as the present invention, or another optical connector (not shown) Can be connected.

The ferrule 120 is formed to surround an end portion of one side 110a of the optical fiber 110. Substantially, the ferrule 120 is well aligned with the core wire of the optical fiber included in the optical connector 200 in the core wire 110c of the optical fiber 110 in the connection structure between the optical connector 200 and the optical fiber integrated optical adapter 100. To be used. The ferrule 120 is selected to have the same size as the ferrule of the optical connector to be connected, such as diameter and length. According to the present invention, the ferrule 120 is configured to be accommodated in the ferrule holder 122 including the protrusion 121 radially formed on the lower outer surface. A portion of the ferrule 120 is accommodated inside the ferrule holder 122, and the other portion is made to be exposed below the protrusion 121. The protrusion 121 is fixed to the second housing 160 to be described below to fix the ferrule 120 and the ferrule holder 122, and the polishing surface of the ferrule 120 polished together with the optical fiber 110. To guide. Since the polishing surface of the ferrule 120 is made flat (0 ㅀ) or obliquely (8 ㅀ) according to the optical connector type, the ferrule 120 is assembled in consideration of the polishing surface when assembling the optical fiber integrated optical adapter 100. do. The ferrule holder 122 is fixed inside the first housing 140 by a spring 130 to be described below, and the ferrule 120 is fixed inside the second housing 160 by the protrusion 121.

The spring 130 is installed to surround the ferrule holder 122 and is located inside the first housing 140 to be described together with the ferrule 120. The spring 130 serves to elastically support the polishing surface of the ferrule 120 to be coupled with a compressive force when in contact with the polishing surface of the ferrule (not shown) included in the optical connector 200.

The first housing 140 has a hollow shape to accommodate the ferrule holder 122 and the spring 130. In more detail, the first housing 140 may include a first coupling member 141, a rotation part 142, a head part 143, and a locking part 144. First, the first coupling member 141 is a portion coupled to the second housing 160 to be described below, and includes a female screw thread 141a on an inner circumferential surface thereof. Rotating portion 142 is formed integrally with the first coupling member 141 may be formed in an angled pillar shape. The head part 143 may be insert molded into the first coupling member 141 and the rotation part 142. At this time, the locking portion 144 formed between the head portion 143 and the rotating portion 142 is relatively smaller in diameter than the head portion 143, so that the protective rubber 190 to be described below is fitted to the locking portion 144. It can be made to be combined. According to the present invention, the optical fiber integrated optical adapter 100 includes a screw coupling, a key coupling, a pin coupling, and a fixing with the second housing 160 in which the first housing 140 receives and describes the ferrule 120 and the spring 130. Ring coupling and coder coupling, or equivalent, are combined to integrate the optical fiber 110 in a relatively simple manner. The first housing 140 may be enabled using a tool such as a spanner (not shown) corresponding to the shape of the pivoting part 142. On the other hand, the outer circumferential surface of the first coupling member 141 may be processed relatively smoothly so as not to be easily released after the first housing 140 and the second housing 160 are coupled.

The sleeve 150 has a cylindrical shape and is configured to accommodate the ferrule 120. One side 150a of the sleeve 150 is accommodated in the second housing 160 to be described below, and the other side 150b is configured to be seated in the connector clip 170 to be described below. The sleeve 150 is accurately aligned with the ferrule 120 of the optical fiber integrated optical adapter 100 and the ferrule (not shown) of the optical connector 200 so that optical transmission loss does not occur.

The second housing 160 is positioned below the first housing 140, and may have a hollow shape to accommodate one side 150a of the sleeve 150. In more detail, the second housing 160 includes a second coupling member 161 and a flange 162 formed under the second coupling member 161. The second coupling member 161 is formed in a cylindrical shape, and the outer circumferential surface is formed of the male thread mountain 161a corresponding to the female thread mountain 141a of the first coupling member 141. A protrusion mounting groove 161b is formed in the second coupling member 161 so that the protrusion 121 is seated. The flange 162 is formed in a plate shape on the lower outer periphery of the second coupling member 161. The flange 162 is coupled to the third housing 180 to be described below by ultrasonic welding or the like, and includes a fusion protrusion 162a or a fusion groove 162b for coupling with the third housing 180. In addition, the flange 162 may include a guide pillar 162c and a guide hole 162d formed to guide the engagement with the third housing 180 to be described at least in part. The flange 162 may further include a bent portion 163 bent in the direction in which the second coupling member 161 is formed. The bent portion 163 is for fixing a substrate such as a PCB, and a hole may be formed in the center thereof so that a bolt or the like may be fastened. However, the shape of the bent portion 163 of the second housing 160 is not limited thereto. Accordingly, one side of the second housing 160 is coupled to the first housing 140 by a screw coupling method, and the other side of the second housing 160 is integrated with the third housing 180 by ultrasonic welding.

The connector clip 170 is mounted inside the third housing 180 to be described below, and serves to attach and detach the optical connector 200. To this end, the connector clip 170 is detachable means in the form of a grip for attaching and detaching the sleeve accommodating portion 171 and the optical connector 200 having a cylindrical shape to accommodate the other side 150b of the sleeve 150. And 172. Although not shown, a ferrule (not shown) of the optical connector 200 is accommodated in the sleeve 150 accommodated in the connector clip 170 so that the ferrule 120 and the polishing surface of the optical fiber integrated optical adapter 100 are aligned. Can be done. The connector clip 170 may be any shape as long as the connector clip 170 is seated in the third housing 180 to be described below, and thus does not limit the shape of the connector clip 170 in the present invention.

The third housing 180 seats the connector clip 170 therein to be detachable through the third housing 180 in which the optical connector 200 is opened. The third housing 180 has a seating groove 181a at one side 181 in contact with the flange 162 of the second housing 160 such that the connector clip 170 is seated inside the third housing 180. . In addition, a fusion protrusion 181b or a fusion groove 181c for coupling with the second housing 160 may be formed at one side 181 of the third housing 180. The fusion protrusion 181b and the fusion groove 181c of the third housing 180 may be formed at positions corresponding to each of the fusion protrusion 162a and the fusion groove 162b respectively formed in the flange 162. In addition, a guide hole 181e and a guide pillar 181d corresponding to the guide pillar 162c and the guide hole 162d of the second housing 160 may be formed at one side 181 of the third housing 180. have. Accordingly, the coupling surface of the flange 162 of the second housing 160 and the one side 181 of the third housing 180 is guided to enable accurate coupling.

The protective rubber 190 is typically installed to prevent damage due to the bending phenomenon of the optical fiber 110 and loss of optical transmission, and may be coupled to the engaging portion 144 of the first housing 140 by fitting. Can be. That is, the protective rubber 190 is installed to surround the head portion 143 of the first housing 140, and the optical fiber 110 exposed at the end of the first housing 140 is damaged due to bending, such as bending. It prevents optical transmission loss. The protective rubber 190 may be formed in different colors according to the shape of the polishing surface of the ferrule 120, as is commonly known.

Next, a method of assembling the optical fiber integrated optical adapter 100 according to an embodiment of the present invention will be described schematically.

Referring to FIG. 8, a partially coupled perspective view of an optical fiber integrated optical adapter 100 according to an embodiment of the present invention is shown.

As shown in FIG. 8, the optical fiber integrated optical adapter 100 according to the embodiment of the present invention first forms the first assembly 100a and the second assembly 100b and then assembles them to complete. First, the first assembly 100a is formed by sequentially inserting the protective rubber 190, the first housing 140, the spring 130, and the ferrule 120 into the optical fiber 110. The ferrule 120 is formed to surround the end of the optical fiber 110, and when the protective rubber 190 to the ferrule 120 is sequentially inserted, the end of the ferrule 120 is polished according to the shape of the optical connector to be connected. Ensure that the core wire of 110) is properly ground. The second assembly 100b is formed by integrally forming a third housing 180 in which the connector clip 170 is seated in the second housing 160. A sleeve 150 is interposed between the second housing 160 and the connector clip 170 as described with reference to FIGS. 3 to 7. The second housing 160 and the third housing 180 may be integrated by a method such as ultrasonic welding, but are not limited thereto. In addition, the connector clip 170 and the third housing 180 may be formed in other forms according to the type of the optical connector. Finally, the optical fiber integrated optical adapter 100 according to the embodiment of the present invention is completed by combining the first assembly 100a and the second assembly 100b. In more detail, the first coupling member 141 of the first housing 140 and the second coupling member 161 of the second housing 160 are screwed, keyed, pin-coupled, retaining ring-coupled and coder. Engaged in an equivalent or equivalent manner. First, the protrusion 121 of the ferrule holder 122 is seated on the second coupling member 161 of the second housing 160, and then the pivoting unit 142 is rotated with a tool such as a spanner to rotate the first coupling member 141. ) Is mounted to the second coupling member 161. At this time, since the outer circumferential surface of the first coupling member 141 is smoothly formed, the first housing 140 does not easily detach from the second housing 160 after assembly.

According to the present invention described above, the optical fiber integrated optical adapter 100 includes the first housing 140 and the second housing 160 which are integrally coupled in the optical connector connection structure to integrate the optical fiber 110 without a separate optical connector. As a result, the parts can be relatively simplified and small in size. That is, unlike the connection structure in which the optical connector is interposed between the optical connector and the optical connector in the related art, miniaturization may be possible by providing an optical adapter in which an optical fiber is integrated on one side. Therefore, the optical fiber integrated optical adapter 100 is structurally more stable because wiring and branching of the optical fiber are relatively free in a confined space, and one side connected to the optical fiber 110 does not cause problems due to frequent detachment and detachment of the optical connector. Can be. In addition, since the optical fiber integrated optical adapter 100 does not need to separately assemble the optical connector and the optical adapter for the branching and wiring of the optical fiber, the assembly cost of the component is reduced. In addition, the optical fiber integrated optical adapter 100 is smoothly processed on the outer surface of the first housing 140 to prevent the component from being separated after assembly of the component to ensure structural stability. Since the optical fiber integrated optical adapter 100 according to the present invention can be modified by the third housing 180 coupled to the second housing 160 and the connector clip 170 seated therein, various types of optical connectors can be attached and detached. Of course it can. Accordingly, it is possible to provide the optical fiber integrated optical adapter 100 with improved reliability due to miniaturization, structural stability and cost reduction.

Next, an optical fiber integrated optical adapter according to another embodiment of the present invention will be described.

FIG. 9 is a perspective view illustrating an optical fiber integrated optical adapter according to another embodiment of the present invention coupled to an optical connector 200. FIG. 10 illustrates an optical fiber integrated optical adapter according to another embodiment of the present invention. An exploded perspective view of is shown. 11 is an exploded cross-sectional view of the optical fiber integrated optical adapter of FIG. 10 taken along the line B-B ', and FIG. 12 is a cross-sectional view of the optical fiber integrated optical adapter of FIG.

9 to 12, the optical fiber integrated optical adapter 1100 according to another embodiment of the present invention, the optical fiber 110 is integrally assembled on one side, the optical connector 200 is detachably coupled to the other side. do. In addition, the optical fiber integrated optical adapter 1100 to which the optical connector 200 is coupled is fixed to a circuit board 300 such as a splitter (not shown) through a coupling member 400 such as a bolt. In more detail, the optical fiber integrated optical adapter 1100 includes an optical fiber 110, a ferrule 120, a spring 130, a first housing 1140, a sleeve 150, a second housing 160, and a connector. It may include a clip 170, the third housing 180 and the protective rubber 190. According to another embodiment of the present invention, the optical fiber integrated optical adapter 1100 except for the first housing 1140 and the second housing 1160 is made the same as the embodiment of Figures 3 to 8. Therefore, the following description will focus on differences from one embodiment of the present invention.

The first housing 1140 includes a columnar first coupling member 1141 and a head portion 1142 formed on the first coupling member 1141. Between the first coupling member 1141 and the head portion 1142 is provided a hook 1431 having a smaller diameter than the head portion 1142 so that the protective rubber 190 is fitted into the first housing 1140. Is made possible. According to another embodiment of the present invention, the first coupling member 1141 includes a protrusion opening 1141a for coupling with the second housing 1160 to be described below. The protrusion opening 1141a is a hole penetrating through the outer surface of the first housing 1140 and may be formed on at least two outer surfaces of the first coupling member 1141. The first coupling member 1141 may further include a flexible groove 1141b. The flexible groove 1141b assists in facilitating the engagement with the second coupling member 1161 to be described below by allowing the first coupling member 1141 to temporarily open. The flexible groove 1141b is formed to a length that is about half the length of the first coupling member 1141 so that the first coupling member 1141 may be coupled to the second coupling member 1161 without deformation.

The second housing 1160 includes a columnar second coupling member 1161 and a flange 1162 formed on a lower outer circumference of the second coupling member 1161. The second coupling member 1161 is formed to be inserted into the first coupling member 1141, and at least two protrusions 1161a are formed on an outer surface thereof. The protrusions 1161a may be formed on opposite sides of the outer surface of the second coupling member 1161, respectively. When the protrusion 1161a is one, it is preferable that the first coupling member 1141 and the second coupling member 1161 are composed of at least two or more protrusions 1161a because they cannot be completely fixed. The projection 1161a of the second coupling member 1161 may be formed in a triangular pillar or a square pillar shape to be formed in close contact with the protrusion opening portion 1141a, and correspond to the protrusion opening portion 1141a of the first coupling member 1141. It can be formed at the position. However, in the present invention, the shape of the projection 1161a is not limited thereto. The first coupling member 1141 may include a protrusion seating groove 1161b to seat the protrusion 121 of the ferrule holder. Since the flange 1162 of the second housing 1160 is substantially the same as the flange 162 of the optical fiber integrated optical adapter 100 according to an embodiment, detailed description thereof will be omitted.

According to another embodiment of the present invention, the protrusion 1161a of the second coupling member 1161 is elastically fixed to the protrusion opening 1141a of the first coupling member 1141 so that the first housing 1140 is the second housing. 1160 is inserted and fixed inside. In this case, the flexible housing 1141b is formed in the first housing 1140 to assist the first coupling member 1141 to be temporarily opened when the protrusion 1161a and the protrusion opening 1141a are coupled to each other. On the other hand, since the outer surface of the first coupling member 1141 is smoothly polished, since the disassembly is difficult after assembling the first housing 1140 and the second housing 1160, the first housing 1140 and the first The two housings 1160 are formed in one piece.

Referring to FIG. 13, there is shown a partially coupled perspective view of an optical fiber integrated optical adapter 1100 according to another embodiment of the present invention.

As shown in FIG. 13, the optical fiber integrated optical adapter 1100 according to another embodiment of the present invention may be formed after the first optical fiber integrated optical adapter 100 forms the first assembly 1100a and the second assembly 1100b. These are assembled and completed. The first assembly 1100a and the second assembly 1100b may be assembled in the same order as the first assembly 100a and the second assembly 100b of FIG. 7, respectively. Next, the optical fiber integrated optical adapter 1100 according to the present invention is completed by inserting and coupling the first coupling member 1141 of the first housing 1140 to the second coupling member 1161 of the second housing 1160. . That is, the protrusion 1161a formed on the outer surface of the second coupling member 1161 is attached to the protrusion opening portion 1141a of the first coupling member 1141 so that the first housing 1140 is inserted into the second housing 1160. To be fixed. A flexible groove 1141b is formed at an end portion of the first coupling member 1141, so that the first coupling member 1141 may be temporarily opened, thereby facilitating engagement with the second coupling member 1161.

According to another embodiment of the present invention described above, the protrusion opening portion 1141a and the protrusion 1161a are formed to correspond to each other in the first housing 1140 and the second housing 1160 to correspond to each other, so that a tool such as a spanner is used. If not, the first housing 1140 and the second housing 1160 may be integrally fastened relatively simply. Other basic operations are the same as in the exemplary embodiment of FIGS. 3 to 8, and thus, the detailed description will be referred to the optical fiber integrated optical adapter 100 of FIGS. 3 to 8.

The present invention is not limited to the above specific preferred embodiments, and any person skilled in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

1 is an exploded perspective view showing a connection method of an optical fiber according to a conventional method.

2 is a perspective view illustrating a coupling method of the optical fiber of FIG. 1.

3 is a combined perspective view illustrating a state in which an optical connector is mounted on an optical fiber integrated optical adapter according to an embodiment of the present invention.

4 is an exploded perspective view of an optical fiber integrated optical adapter according to an embodiment of the present invention.

5 is an exploded cross-sectional view taken along line AA ′ of the optical fiber integrated optical adapter of FIG. 4.

6 is a cross-sectional view of combining the optical fiber integrated optical adapter of FIG.

FIG. 7 is a partially coupled perspective view illustrating a coupling surface of a second housing and a third housing of an optical fiber integrated optical adapter according to an embodiment of the present invention.

8 is a partially coupled perspective view of an optical fiber integrated optical adapter according to an embodiment of the present invention.

9 is a perspective view illustrating a state in which an optical fiber integrated optical adapter according to another embodiment of the present invention is mounted on an optical connector.

10 is an exploded perspective view of an optical fiber integrated optical adapter according to another embodiment of the present invention.

FIG. 11 is an exploded cross-sectional view taken along line BB ′ of the optical fiber integrated optical adapter of FIG. 10.

12 is a cross-sectional view of the optical fiber integrated optical adapter of FIG.

13 is a partially coupled perspective view of an optical fiber integrated optical adapter according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100, 1100: optical fiber integrated optical adapter 110: optical fiber

120: ferrule 130: spring

140, 1140: first housing 141, 1141: first coupling member

150: sleeve 160, 1160: second housing

161, 1161: second coupling member 170: connector clip

180: third housing 190: protective rubber

Claims (5)

In the optical fiber integrated optical adapter (100, 1100) in which the optical fiber 110 is integrally assembled on one side and the optical connector (200) is detachable on the other side, A ferrule (120) surrounding an end of the optical fiber (110) and accommodated in the ferrule holder (122) having a protrusion (121) formed radially on an outer surface of a lower end thereof; A spring 130 installed to surround the ferrule holder 122; First coupling members 141 and 1141 for accommodating the ferrule holder 122 and the spring 130 in a hollow shape, and a head portion integrally inserted into the first coupling members 141 and 1141. First housings 140 and 1140 including 143 and 1142; A sleeve 150 positioned below the first housing 140 and 1140 and accommodating the ferrule 120 exposed from the ferrule holder 122 in a cylindrical shape; The one side 150a of the sleeve 150 is accommodated in the hollow, and the first coupling member 141 and 1141 of the first housing 140 and 1140 is inserted into and fixed to the inside of the ferrule holder 122. The second coupling members 161 and 1161 including the protrusion mounting grooves 161b and 1161b on which the protrusions 121 of the upper and lower protrusions 121 are mounted, and the flanges 162 formed on the outer circumference of the second coupling members 161 and 1161. Second housings 160 and 1160 including 1162; A connector clip (170) including a sleeve receiving portion (171) for receiving the other side (150b) of the sleeve (150) and a detachable means (172) for attaching and detaching the optical connector (200); And A mounting groove 181a is provided in one side 181 to seat the connector clip 170, and the one side 181 is coupled to the flanges 162 and 1162 of the second housings 160 and 1160. Optical fiber integrated optical adapter, characterized in that comprises a third housing (180). The method of claim 1, The first housing 140, The outer circumferential surface of the first coupling member 140 is smoothly formed, Further comprising a rotating part 142 formed of an angled column shape at least one surface between the first coupling member 140 and the head portion 143, The inner circumferential surface of the first coupling member 141 and the outer circumferential surface of the second coupling member 161 of the second housing 160 are screwed, keyed, pinned, fixed ring engaged, and coder coupled by a female thread / male thread. Optical fiber integrated optical adapter, characterized in that coupled using any one of. The method of claim 1, The second coupling member 1161 may have a protrusion 1161a formed on an outer surface thereof. The first coupling member 1141 has a smooth outer surface, and includes a protrusion opening 1141a formed of a hole to insert and fix the protrusion 1161a from the inner surface to the outer surface. A flexible groove 1141b is formed at an end of the first coupling member 1141 to temporarily open the first coupling member 1141, and the protrusion 1161a is elastically fastened to the protrusion opening 1141a. Optical fiber integrated optical adapter, characterized in that. The method of claim 1, The first housing 140, 1140, It is formed integrally between the first coupling member (141, 1141) and the head portion (143, 1142), and further comprises a hook 144, 1143 having a smaller diameter than the head portion (143, 1142) , The hanger (144, 1143) optical fiber integrated optical adapter, characterized in that the protective rubber 190 is fitted to surround the head portion (143, 1142). The method of claim 1, The optical connector 200, An optical fiber integrated optical adapter, which is any one of SC, FC, LC, and ST.

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