KR101103631B1 - Mass optical line cable switching system - Google Patents

Abstract

PURPOSE: A bulk optical cable disconnecting system is provided to automatically change broken bulk optical cable into a protecting type bulk optical cable by automatically detecting the broken optical cable. CONSTITUTION: A switching head apparatus(30) includes an integration center(11), a non-integration center(12), a walking switch head(31), and a reserve switch head(32). A disconnection apparatus(50) connects the reserve switch head of the integration center with the reserve switch head of the non-integration center. A robot apparatus is optically connected with the disconnection apparatus by determining the disconnecting location of a light line cable in the switch head apparatus. The switching head apparatus uses an optical adaptor, an optical fiber array, and an optical connector.

Description

Mass optical line cable switching system

The present invention relates to a large-capacity optical fiber cable switching system, and more particularly, to prevent service interruption when the integrated station FTTH pressurizer network is accommodated in the integrated station. The present invention relates to a large-capacity fiber cable switching system suitable for constructing a protection line and performing cost-effective FTTH service protection switching.

In general, there are three ways to protect the wide trunk line between stations. First, the working optical line and the protective optical line are constructed first, and then, the transmission equipment is secured at both stations to secure redundancy, or at the location of the optical fiber distribution boards at both stations. By using optical switch, it is possible to selectively connect the working optical line and the protective optical line, or thirdly, the operating optical worker in the optical fiber distribution boards of both sides of the stations is transferred manually to the protective optical line.

In the first method, fault detection and transfer are possible automatically by the transmitting device, and there are advantages such as fast switching time. However, considering the subscriber network environment in which various signals flow, a transmitting device having a large number of various interfaces is required. If the cost is increased, and the received signal is different, there is a problem such as the interface of the transmission apparatus or a new introduction of the transmission apparatus itself.

The second method is that the existing optical switch developed at present is expensive and the capacity is not large. Therefore, the number of optical switches becomes expensive and bulky for switching large capacity optical cables. In addition, when multi-stage connection is required, insertion loss may increase, and thus performance may not be realized.

The third method can be configured without additional devices in the fiber distribution board, but the error recovery time is longer due to manual failure detection and transfer, or the frequency of human error due to the simple repetitive operation in complex fiber distribution boards. There is a problem that increases.

An object of the present invention for improving the conventional problems as described above, in the configuration of the FTTH subscriber network, the optical fiber cable failure is automatically detected when a failure such as cutting in the optical fiber network between the integrated station and the integrated country, It is to provide a large-capacity optical fiber cable switching system to implement the function of automatically converting optical fiber cable to protective large-capacity optical fiber cable at low cost and efficiently to meet the FTTH subscriber network service dimension.

In order to achieve the above object, the present invention provides a system that can be switched to the protective optical fiber cable in the event of cutting of the optical fiber cable between the integrated station and the integrated station of the FTTH network: a respective working switch to the integrated station and the integrated station Switching head means having a head and a preliminary switch head; Connecting means for optically connecting the spare switchhead of the integrated station and the spare switchhead of the integrated station via a protection line; And a robot means for determining the cutting position of the optical fiber cable by the switching head means and continuing the optical connection through the wiring means, wherein the switching head means is a multi-core optical fiber array on the working switch head and the preliminary switch head. An optical connector and a multi-core optical fiber array optical adapter are used, wherein the robotic means includes a biaxial arm for transferring in a two-way motion to a desired position on the working switch head of the connecting means, and one direction to a desired position on the spare switch head of the connecting means. It is characterized in that it comprises an optical axis switching controller which performs the switching of the optical fiber cable by uniaxial arm conveying by movement, driving of the biaxial arm and monoaxial arm and intermittent solenoid.

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In addition, according to the present invention, the switching head means is characterized in that the working switch head is radially arranged around the preliminary switch head on the frame, or the preliminary switch head is arranged in a line in the form of first or last position. .

At this time, the multi-core optical fiber array optical connector of the present invention is provided with a solenoid of the side and a protrusion on the side on the housing, the multi-core optical fiber array optical adapter is characterized in that it comprises a guide groove on the side of the housing.

In addition, according to the present invention, the connection means is characterized in that it is configured by connecting the optical fiber cable and the detection cable between the one end and the preliminary switch head of the other end, respectively.

In this case, according to the present invention, the optical fiber switching controller detects the disconnection position through the optical signal and the optical receiver connected to the detection cable.

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On the other hand, the terms or words used in the present specification and claims are not to be construed as limiting the ordinary or dictionary meanings, the inventors should use the concept of the term in order to explain the invention in the best way. It should be interpreted as meanings and concepts corresponding to the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, and various alternatives may be substituted at the time of the present application. It should be understood that there may be equivalents and variations.

As described above, according to the present invention, when a failure such as cutting occurs in the optical fiber network between the integrated station and the integrated country, a function of automatically detecting an optical fiber cable failure and automatically switching the failed large optical fiber cable to a large capacity optical fiber cable for protection. Low cost and efficient implementation.

1 is a configuration generally connecting a large capacity optical fiber cable.
Figure 2 is a block diagram showing an overall switching system according to the present invention.
3 is a configuration diagram of a multi-core optical fiber array optical connector and an optical adapter applied to the system of the present invention.
Figure 4 is a block diagram showing the connection means applied to the system of the present invention.
Figure 5 is a block diagram showing a robot means applied to the system of the present invention.

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

The present invention relates to a system capable of switching to a protective fiber optic cable in the event of a fiber optic cable cutting accident between the integrated station 11 and the integrated station 12 of the FTTH network. Referring to FIG. 1, the integrated station 11 includes an optical fiber distributor 13, an optical switch 14, and a transmission device 15, and the integrated station 12 includes an optical fiber distributor 13 and an optical switch. 14, a one-dimensional space node 16, and a two-dimensional space node 17 is provided. The integrated station 11 and the integrated station 12 are connected with a plurality of working lines 21 and a few protection lines 22. In the case of the accident of cutting the optical fiber cable corresponding to the optical fiber section established between the integrated station 11 and the integrated station 12 of the FTTH network, the optical fiber cable of the optical fiber section is prevented in order to prevent a large number of FTTH subscribers from temporarily stopping service. Is transferred from the working line 21 to the protective line 22.

In FIG. 2, the switching head means 30 has the working switch head 31 and the spare switch head 32 in the integrated station 11 and the integrated station 12, respectively. The working switch head 31 is provided in the terminal on the integrated station 11 side, and the working switch head 31 is provided in the terminal of the integrated station 12. A plurality of working lines 21 are hypothesized between the working station 11 and the working switch head 31 of the integrated station 12. The preliminary switch head 32 is intermittently connected with a few protection lines 22 having the same optical fiber as the number of optical fibers accommodated in the working switch head 31 corresponding thereto.

According to the present invention, the switching head means 30 uses a multi-core optical fiber array optical connector 24 and a multi-core optical fiber array optical adapter 25 on the working switch head 31 and the preliminary switch head 32. do. The switching head means 30 uses a multi-core optical fiber array optical connector 24 and a multi-core optical fiber array optical adapter 25 on the working switch head 31 and the preliminary switch head 32. The multi-core optical fiber array optical The connector 24 is an optical connector for accommodating and simultaneously connecting a large number of optical fibers 26. A hole having a matrix lattice arrangement is formed in a substrate made of a quartz or similar rigid and low temperature variation material. Here, the optical fibers 26 are fixed and arranged, and the optical fibers 26 are fixed to the housing 41 and manufactured in the form of a detachable optical connector. The multi-core optical fiber array optical adapter 25 is for connecting the multi-core optical fiber array optical connector 24 to each other. Like the general optical adapter, the multi-core optical fiber array optical connector 24 can be connected to each other through the optical adapter. It is made in the form. Detailed structure according to this will be described later.

That is, as shown in FIG. 3, the multi-core optical fiber array optical connector 24 is connected through the multi-core optical fiber array optical adapter 25 and maintains optical connection to the optical fibers 26 on both sides (optical equipment side and optical path side). . Here, the optical fiber 26 means the working line 21 or the protection line 22. The working switch head 31 of the working line 21 includes a multi-core optical fiber array optical connector 24 on one side and a multi-core optical fiber array optical adapter 25 and a multi-core optical fiber array optical connector 24 on the other side. The preliminary switch head 32 of the protection line 22 includes a multi-core optical fiber array optical connector 24 and a multi-core optical fiber array optical adapter 25 on the other side. The working switch head 31 and the preliminary switch head 32 are controlled using a robot means 60 to be described later.

In this case, according to the present invention, the switching head means 30 has a working switch head 31 radially arranged around the preliminary switch head 32 on the frame F, or the preliminary switch head 32 is firstly placed. Or arranged in a line in the last position. That is, the optical fiber 26 connected to the square ratio side is connected to a plurality of multi-core optical fiber array optical connector 24, the multi-core optical fiber array optical connector 24 is mounted to the working switch head 31. In the case of the optical path side of the working line 21 similarly, it is connected to the multi-core optical fiber array optical connector 24 and mounted on the working switch head 31, and the two multi-core optical fiber array optical connectors 24 are It is fastened to each other through the core optical fiber array optical adapter 25. On the other hand, the multi-core optical fiber array optical connector 24 is connected via the multi-core optical fiber array optical adapter 25, and maintains the optical connection to the optical fiber 26 on the optical device side and the optical path side.

The switching head means 30 has a shape in which the working switch head 31 is radially arranged around the preliminary switch head 32 on the frame F, or the preliminary switch head 32 is positioned first or last. The multi-core optical fiber array optical adapter 25 is fastened to a multi-core optical fiber array optical connector 24 connected from an optical line for the protection line 22, and the opposite square ratio side is cut in the optical line. The spare switch head 32 connected to the city square ratio side is left to be connected. The switching head means 30 configured as described above is a multi-core optical fiber array of the spare switch head 32 that is empty by detaching the multi-core optical fiber array optical connector 24 on the non-square side connected thereto when the working switch head 31 is cut. It is made by fastening to the optical adapter 25. FIG. This operation is automatically controlled using the robot means 60.

At this time, the multi-core optical fiber array optical connector 24 has a guide 42 on the side and a solenoid 43 on one side on the housing 41, the multi-core optical fiber array optical adapter 25 is the housing 45 It is provided with a guide groove 46 on the side. The guide groove 46 of the multicore optical fiber array optical adapter 25 slides with the guide 42 of the multicore optical fiber array optical connector 24 and induces smooth engagement. On the other hand, the housing 41 of the multi-core optical fiber array optical connector 24 is used a solenoid 43 for smooth coupling with the multi-core optical fiber array optical adapter 25, which is two multi-core optical fiber array optical connector 24 By energizing the final solenoid 43 for the purpose of fastening, the magnetic force acts between these multiconducting optical fiber array optical connectors 24 and the multiconducting optical fiber array optical adapters 25. This final fastening requires a separate load cell in order to recognize the completion of the fastening when the robot is used as a robot, and can prevent damage of the multi-core optical fiber array optical connector 24 due to malfunction of the robot means 60 and the sensor. There is an advantage.

In addition, according to the present invention, the connecting means 50 is a preliminary switch head 32 of the integrated station 11 and the preliminary switch head 32 of the integrated station 12 are optically via the protective line 22. It is a configuration to be connected. The connecting means 50 performs optical connection by using the protection line 22 parallel to the working line 21 between the integrated station 11 and the integrated station 12, and ends of the working line 21. Is connected to the working switchhead 31, but both ends of the protective line 22 is connected to the spare switchhead 32.

At this time, the connection means 50 of the present invention is configured by connecting the optical fiber cable 51 and the detection cable 55 between one end and the other end of the movable deck (32). The optical fiber cable 51 serves as a protective line 22. The detection cable 55 loops several optical cores in the outermost part of the working line 21 to be monitored at the integrated station 11 and the integrated station 12. The monitoring signal is sent from the optical signal receiver 56 to be described later, and this signal flows along the aforementioned detection cable 55 and is received and monitored by the optical receiver 57 to be described later. If the cutting line 21 is broken, it detects that a monitoring signal is not received and transmits a signal for controlling the robot means 60 from the optical path switching controller 65 which will be described later to switch over the optical fiber cable 51. Will perform. In FIG. 2, reference numeral 52 denotes a ribbon cable used as the working line 21 and the protective line 22.

In FIG. 4, the optical fiber cable 51 for the protection line 22 may be configured in various ways. For example, the optical fiber cable 51 for the protection line 22 is collected by collecting some optical fiber cores in each optical fiber cable without configuring the optical fiber cable 51 for the protective line 22 in a one-to-one manner for each working line 21. To use. That is, a part of each optical fiber cable is allocated for the working line 21 and a part for allocating for the protective line 22. Here, the number of cores of the optical fiber cable for the protection line 22 is equal to or larger than the total number of cores of one optical fiber cable.

In addition, according to the present invention, the robot means 60 determines the cutting position of the optical fiber cable in the switching head means 30 to continue the optical connection through the wiring means (50). Regardless of the communication signal flowing in the optical path that is received by using the robot-type optical switch instead of the transmission device, it can be accommodated, and fault detection is automatically performed, and the switching time by the robot means 60 takes about several seconds. It can solve the disadvantage of recovery.

At this time, the robot means 60 of the present invention is a biaxial arm 61 and the preliminary switch of the connecting means 50 to transfer in two directions to the desired position on the working switch head 31 of the connecting means 50 Switching of the optical fiber cable is carried out by driving the uniaxial arm 62, the biaxial arm 61 and the uniaxial arm 62, and the solenoid 43 which are fed in a unidirectional motion at a desired position on the head 32. And a light beam switching controller (65). The robot means 60 is composed of a triaxial arm consisting of a biaxial arm 61 and a monoaxial arm 62 to move the working switch head 31 of the connection means to the preliminary switch head 32, which is an optical cable cutting. Mounts the multi-core optical fiber array optical connector 24 of the square ratio side connected to the optical cable cut at the time to move to the preliminary switch head 32 that is not connected to the square ratio side.

That is, in FIG. 5, the robot means 60 is a biaxial arm that moves the working switch head 31 of the wiring means 50 in the up and down direction on a plane where the multi-core optical fiber array optical adapters 25 are arranged. 61, and when the working switch head 31 is located on the same axis as the multi-core optical fiber array optical adapter 25 of the preliminary switch head 32 to be fastened, the multi-core of the working switch head 31 The optical fiber array optical connector 24 is provided as a uniaxial arm 62 which pushes the multi-core optical fiber array optical adapter 25 to guide the fastening. The final fastening is performed by applying electricity to the solenoid 43. This optical cable protection switching is made automatically, and made through the optical fiber switching controller (65). The final fastening is performed by the operation of the solenoid 43 mounted on the working switch head 31, and the arms 61 and 62 move the working switch head 31 to the multi-core optical fiber array optical stage until the initial fastening is performed. Close to adapter 25. The light beam switching controller 65 performs the planar motion of the biaxial arm 61 and the motion on the central axis of the monoaxial arm 62, and finally adjusts the solenoid 43 to the working line 21 at the disconnected position. Instead it is transferred to the protective line (22).

On the other hand, the optical path switching controller 65 detects the disconnection position through the optical signal 56 and the optical receiver 57 connected to the detection cable 55. The optical signal receiver 56 and the optical receiver 57 are connected to the terminal of the integrated station 11 and the integrated station 12 via the detection cable 55, and the signal for the disconnection position of the working line 21 ( Information) at a cycle set in the optical path controller 65.

In operation, assuming that No. 1 of the working line 21 of the optical fiber cable has failed, it is detected by the optical fiber transfer controller 65 of the integrated station 11 and the integrated station 12, and the optical fiber transfer controller 65 ) Mounts the multi-axis optical fiber array optical connector 24 of the working switch head 31 on the equipment side connected to the working line cut by operating the biaxial arm 61, and the multi-core optical fiber of the working switch head 31. The array optical connector 24 is moved to where the multi-core optical fiber array optical adapter 25 of the spare switch head 32 is located. Subsequently, when the multi-axial optical fiber array optical connector 24 of the working switch head 31 is moved to the multi-core optical fiber array optical adapter 25 of the preliminary switch head 32 using the uniaxial arm 62, the solenoid 43 After final tightening, the large capacity optical fiber cable switching function is completed.

If the failed optical fiber cable is accommodated in several working switch heads 31, all the corresponding optical connector working switch heads 31 are automatically reproduced sequentially in order to complete the protection switching. Of course, the information such as the details and the position of the optical fiber cable for the working line 21 accommodated in the working switch head 31 is stored in the optical fiber switching controller 65. Accordingly, the contents stored in the optical fiber switching controller 65 or the information of the switching system can be transmitted to the outside through a separate external communication line, and on the contrary, a command for changing the contents or function of the optical fiber switching controller 65 can be sent. You can also pass it.

Thus, the working switch head 31 composed of the multi-core optical fiber array optical connector 24, the solenoid 43, the multi-core optical fiber array optical adapter 25, and the robot means 60 and the optical path switching controller for controlling them ( When the large-capacity optical cable switching system consisting of 65) is installed and operated at each optical fiber cable point where large-capacity switching is required, it is possible to temporarily switch tens or hundreds of core optical fibers at a time when cutting the optical cable.

The use of a low cost and high capacity multi-core optical fiber array optical connector and optical adapter is important for switching optical paths according to the present invention. Conventional bulk optical optical switches, optical waveguide optical switches, and MEMS optical switches are expensive and switches. In view of the structure of the light beam, it is impossible to increase the capacity due to the adjustment of the light beam or the increase of insertion loss, and there are problems in that the total volume of the optical switch is increased and the points to be controlled are increased when using multiple small optical switches.

Next, 50msec, which is the protection switching time required for the network using the transmission device, is too strict, and the manual method, which consumes a dozen hours for switching cables of hundreds of cores, causes too long service interruption. Therefore, in view of the reality of the FTTH subscriber network, if a few hundred core optical fiber cable switching takes several minutes in the present invention, it can be regarded as a meaningful time for subscriber service.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

11: unified country 12: integrated country
13: optical fiber distribution board 15: transmitter (OLT)
21: Working Line 22: Protection Line
24: Multi-Central Fiber Optic Array Optical Connectors
25: Multicore Optical Fiber Array Optical Adapter
30: switching head means 31: working switch head
32: spare switchhead 41,45: housing
42: Guide 43: Solenoid
46: guide groove 50: connection means
51: optical fiber cable 55: detection cable
56: optical signal receiver 57: optical receiver
60: robot means 61: biaxial arm
62: single axis arm 65: optical fiber controller (OCU)

Claims (7)

In a system that can be switched to a protective fiber optic cable in the event of a fiber cable disconnection between the integrated station (11) and the integrated station (12) of the FTTH network:
Switching head means (30) having respective working switch heads (31) and spare switch heads (32) in the integrated station (11) and the integrated station (12);
Wiring means (50) for optically connecting the preliminary switchhead (32) of the integrated station (11) and the preliminary switchhead (32) of the integrated station (12) via a protective line (22); And
And a robot means (60) for continuing the optical connection through the connection means (50) by determining a cutting position of the optical fiber cable in the switching head means (30),
The switching head means 30 uses a multi-core optical fiber array optical connector 24 and a multi-core optical fiber array optical adapter 25 on the working switch head 31 and the preliminary switch head 32,
The robot means (60) is a biaxial arm (61) for conveying in a two-way motion at a desired position on the working switch head (31) of the connecting means (50), and on the preliminary switch head (32) of the connecting means (50). The optical path switching controller which performs the switching of the optical fiber cable by driving the single axis arm 62, the dual axis arm 61 and the single axis arm 62, and the solenoid 43 which are fed to the desired position in one direction movement. A large capacity optical fiber cable switching system comprising (65). delete The method of claim 1,
The switching head means 30 has a shape in which the working switch head 31 is radially arranged around the preliminary switch head 32 on the frame F, or the preliminary switch head 32 is positioned first or last. Large capacity optical fiber cable switching system, characterized in that arranged in a row. The method of claim 1,
The multi-core optical fiber array optical connector 24 has a guide 42 on the side and a solenoid 43 on one side on the housing 41, and the multi-core optical fiber array optical adapter 25 is a side of the housing 45. Large-capacity optical fiber cable switching system characterized in that it comprises a guide groove (46). The method of claim 1,
The connecting means 50 is a large-capacity optical fiber cable switching system, characterized in that configured to connect the optical fiber cable 51 and the detection cable 55 between one end and the preliminary switch head 32 of the other end. delete The method of claim 1,
The optical fiber cable switching system (65) is characterized in that for detecting the disconnection position through the optical signal receiver (56) and the optical receiver (57) connected to the detection cable (55).

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