JP2007020134A - Optical fiber connection unit and optical wiring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical fiber connection unit which improves expansibility to cope with the case that the number of users increases or the like can be manufactured at low cost, attains downsizing and also facilitates wiring, and an optical wiring system. <P>SOLUTION: An optical fiber connection unit 30 comprises a cross wiring unit 31 to which transmission devices 21, 22 of a plurality of systems are connected. The cross wiring unit 31 is connected to each of the transmission devices by device side multi-core optical fibers 25, 26 of which at least a cross wiring unit side is fused for connection, and a plurality of user side multi-core optical fibers 36 are connected to a user side of the cross wiring unit 31 by fused connection. A cross wiring module 35 of the cross wiring unit 31 distributes a plurality of optical fibers from each of transmission devices to each of users. Furthermore, an optical wiring system using the device side optical fibers 25, 26 between the optical fiber connection unit 30 and the transmission devices 21, 22 employs connector connection (Fig 1) or fused connection (Fig 7). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical fiber connection unit for distributing optical fibers from a plurality of transmission apparatuses for each user and connecting the optical fibers to a user-side optical cable, and an optical wiring system between the transmission apparatus and the optical fiber connection unit.

For example, as a facility for introducing an optical fiber into a large-scale apartment building or the like, a data transmission device 1 and a video transmission device 2 are installed in an MDF (main wiring board) room as shown in FIG. In the cross wiring unit 3 arranged in the termination box or the like, a system for introducing an optical fiber to each user is employed.
In FIG. 8, 4 is an optical adapter, and 5 is an optical fiber sheet. For example, four-fiber optical cords 7 and 8 with connectors at both ends are connected to the optical adapter 4 of the cross wiring unit 3, and the connection optical cords 10 and 11 connected to the single-fiber connector in the optical adapter 4 are fused. The optical fiber sheet 5 is drawn into the optical fiber sheet 5 through the connecting portion 12 and melted together with the two-core optical fiber tape 14 for each user including the two optical fibers of the transmission apparatuses 1 and 2 by cross wiring in the optical fiber sheet 5. The splicing connection part 13 is fusion spliced.

In the conventional optical fiber connection unit 20, since the cross wiring unit is constituted by the optical fiber sheet 5, the wiring pattern in the optical fiber sheet 5 and the number of accommodations are determined, and cannot be handled when the number of users increases. , Has the disadvantage of lack of extensibility.
In addition, there is a drawback in that the optical fiber sheet 5 is expensive to manufacture.
Further, the optical adapter 4 and the single-core cords (connection optical cords 10 and 11) are bulky, so that the cross wiring unit is not miniaturized, and wiring in the cross wiring unit 3 is complicated.

  The present invention has been made to eliminate the above-mentioned conventional drawbacks, and does not use an optical fiber sheet, can easily cope with an increase in the number of users, has excellent expandability, can be manufactured at a low cost, It is an object of the present invention to provide an optical fiber connection unit and an optical wiring system that enable miniaturization of an optical termination box by miniaturization of the wiring unit and simplify wiring work.

The optical fiber connection unit of the present invention that solves the above problems includes a cross wiring unit to which transmission devices of M systems (M is a number of 2 or more) are connected,
The cross wiring unit has one or a plurality of apparatus side multi-cores each having a total number of cores of N (N is the number of users) or more, wherein at least the cross wiring unit side is fusion-bonded to each transmission apparatus. Connected by optical fiber,
N user side M-core optical fibers are connected to the user side of the cross wiring unit by fusion splicing,
The cross wiring unit includes a cross wiring module, and the cross wiring module receives a total of N × M optical fibers from each transmission device and M optical fibers corresponding to each transmission device for each user. It is characterized by cross wiring so as to be distributed.

  According to a second aspect of the present invention, in the optical fiber connection unit of the first aspect, there are a plurality of cross wiring units, which are housed in a single wiring box.

The invention of claim 3 is an optical wiring system in which the optical fiber connection unit of claim 1 and the transmission device are connected by a device-side multi-core optical fiber,
An FO cord is used as the device-side multi-fiber, and one end of the FO cord is fused and connected to the cross wiring unit side, and the other end is connected to the transmission device by a connector.

The invention of claim 4 is an optical wiring system in which the optical fiber connection unit of claim 1 and the transmission device are connected by a device-side multi-core optical fiber,
A multi-fiber tape cord is used as the device-side multi-core optical fiber, and one end of the multi-fiber tape cord is fused and connected to the cross wiring unit side, and the other end is also fused and connected to the transmission device. To do.

According to the optical fiber connection unit of the present invention, since the cross wiring portion uses the cross wiring module in the case instead of the optical fiber sheet, even if the number of users increases or the number of transmission systems increases, the cross wiring Since it can be handled simply by connecting the optical fiber inside the unit and the external optical fiber, it has excellent expandability.
In addition, unlike an optical fiber sheet, only cross wiring is performed in the case, so that it can be manufactured at a low cost.
Moreover, an optical adapter and a single-core cord are not required, and the cross wiring unit can be downsized and the optical termination box can be downsized accordingly.
Further, since there is no connector connecting portion in the cross wiring unit, wiring work is easy.

  According to the optical wiring system of the third aspect, since the transmission device side is a connector connection, the switching connection can be easily performed on the transmission device side.

  According to the optical wiring system of the fourth aspect, since not only the optical fiber connection unit side but also the transmission device side is fusion spliced, no optical adapter is required on the transmission device side, and the transmission device can be miniaturized.

  Hereinafter, an optical fiber connection unit embodying the present invention will be described with reference to the drawings.

FIG. 1 is a schematic configuration explanatory view of an optical fiber connection unit 30 according to an embodiment of the present invention. This optical fiber connection unit 30 is a case where two systems of transmission devices, a data transmission device 21 and a video transmission device 22, are installed, and there are four users. In other words, two transmission devices 21 and 22 and a cross wiring unit 31 to which these two systems (system number M = 2) transmission devices 21 and 22 are connected, and the cross wiring unit 31 is connected to each transmission device 21. , 22, respectively, FO cords (device-side multi-core optical fiber) in which the transmission devices 21 and 22 are connected by connectors and the cross wiring unit 31 side is fusion-bonded (N-core: number of users N = 4) ) 25 and 26, and the user side of the cross wiring unit 31 has four (N = 4) user side two-core optical fiber tapes (user side M-core optical fiber) 36 connected by fusion splicing. Yes.
The cross wiring unit 31 includes a cross wiring module 35. The cross wiring module 35 includes a total of eight optical fibers (N × M = 4 × 2 = 8) from the transmission apparatuses 21 and 22 in four units. Cross wiring is performed so that two (M = 2) optical fibers corresponding to the respective transmission apparatuses 21 and 22 are distributed to each user.
An apparatus side end portion 35 a of the cross wiring of the cross wiring module 35 and a fusion splicing portion of the four-core FO cords 25 and 26 are indicated by 37. A fusion splicing portion 38 between the user side end portion 35 b of the cross wiring of the cross wiring module 35 and the user side two-core optical fiber tape 36 is indicated by 38.
As described above, in the cross wiring unit 31, a total of eight optical fibers including the four optical fibers from the data transmission device 21 and the four optical fibers from the video transmission device 22 are included in the cross wiring unit 31. And are distributed to four two-fiber optical fiber tapes 36 that are routed to four users. Each two-fiber optical fiber tape 36 includes one optical fiber from the data transmission device 21 and one optical fiber from the video transmission device 22.
The optical wiring system between the optical fiber connection unit 30 and the transmission devices 21 and 22 in this embodiment is as described above, and the four-fiber FO cords 25 and 26 are used as the device-side multi-core optical fibers. One end (fiber end) of the FO cords 25 and 26 is fusion-bonded to the cross wiring unit 31 side, and the other end (connector end) is connector-connected to the transmission devices 21 and 22. Optical connectors at the other ends of the four-fiber FO cords 25 and 26 are indicated by 25a and 26a.

The optical fiber connection unit 40 of the embodiment shown in FIGS. 2 to 4 is a case where there are four transmission apparatuses (M = 4), and in addition to the data transmission apparatus 21 and the video transmission apparatus 22, A line transmission device 23 and a spare transmission device 24 are provided. The number of users is 4 as described above.
In other words, the optical fiber connection unit 40 is a cross wiring unit in which four systems of transmission devices 21, 22, 23, and 24 and these four systems (number of systems M = 4) of transmission devices 21, 22, 23, and 24 are connected. As shown in FIG. 3, the cross wiring unit 41 has four cores (N cores: the number of users N = 4) with respect to the four systems of transmission devices 21, 22, 23, and 24, respectively. Connected by FO cords (device side multi-core optical fibers) 25, 26, 27, and 28, the user side of the cross wiring unit 41 has four (N = 4) user side four-core optical fiber tapes (user side M An optical fiber 46 is connected by fusion splicing.
The cross wiring module 45 of the cross wiring unit 41 has a total of 16 (N × M = 4 × 4 = 16) optical fibers from the transmission devices 21, 22, 23, and 24 for each of four users. Cross wiring is performed so that four (M = 4) optical fibers corresponding to the transmission apparatuses 21, 22, 23, and 24 are distributed. In the illustrated example, three cross wiring units 41 are accommodated in an optical termination box 49.
Reference numeral 47 denotes a fusion splicing portion between the device side end 45 a of the cross wiring of the cross wiring module 45 and the four-core FO cords 25, 26, 27, and 28. A fusion splicing portion 48 between the user side end 45 b of the cross wiring of the cross wiring module 45 and the user side four-core optical fiber tape 46 is indicated by 48.
As described above, in the cross wiring unit 41, the four optical fibers from the data transmission device 21, the four optical fibers from the video transmission device 22, and the four optical fibers from the separate line transmission device 23 are used. And four optical fibers from the spare transmission device 24, a total of 16 optical fibers are cross-wired by the cross wiring module 45, and four user-side four-core optical fiber tapes heading to four users 46. Each user-side four-core optical fiber tape 46 includes an optical fiber from the data transmission device 21, an optical fiber from the video transmission device 22, an optical fiber from the separate line transmission device 23, and a light from the backup transmission device 24. One fiber at a time.
If the spare transmission device 24 is in the original spare state, the four-fiber FO cord 28 is not yet connected. The description has been made with the core FO cord 28 connected.

  FIG. 4 schematically shows an example of a specific internal structure of the optical termination box 49. (A) of the figure is a plan view, (b) is a front view, and (c) is a side view. This optical termination box 49 is arranged in such a manner that three cross wiring modules 45 are stacked in three stages at the center in a horizontally installed wiring box 49a, and one apparatus side fusion splicing tray (fusing) The fusion splicing connection tray (fusion splicing portion) 48 on the other end side is arranged in such a manner that they are laminated in three stages. The fusion splicing trays 47 and 48 can be pulled out by sliding outward. Note that the cross wiring module 45 and the fusion splicing trays 47 and 48 in each of the upper, middle, and lower stages may constitute the cross wiring units 41, 42, and 43 for each stage. It doesn't have to be a relationship. In the example of FIG. 2, only one of the three cross wiring units 41, 42, 43 is used.

FIG. 5 shows an optical fiber connection unit 40A of another embodiment. This optical fiber connection unit 40A is a case where four systems of transmission devices 21, 22, 23 and 24 are provided as in the embodiment of FIG. 2, but the number of users is twelve. In this embodiment, all three cross wiring units 41, 42, 43 in the optical fiber connection unit 40 of FIG. 2 are used, and each cross wiring unit 41, 42, 43 corresponds to four users, respectively. Yes.
The device side of each cross wiring unit 41, 42, 43 is connected to each transmission device 21, 22, 23, 24 via an individual four-fiber FO cord (device-side multi-core optical fiber) 25, 26, 27, 28. In addition, user side four-core optical fiber tapes (user side M-core optical fibers) 46 for four users are connected to the user side of each cross wiring unit 41.
Thus, in this embodiment, the increase in the number of users is dealt with by adding cross wiring units.

FIG. 6 shows an optical fiber connection unit 50 of still another embodiment. This optical fiber connection unit 50 is a case where four transmission devices 21, 22, 23, 24 are provided as in the embodiment of FIG. 2, but the number of users is eight. In this optical fiber connection unit 50, one cross wiring unit 51 has two four-fiber FO cords (device-side multi-core optical fibers) 25, 26, and each transmission device 21, 22, 23, 24. 27 and 28 are connected. In addition, eight user-facing (eight) user-side four-core optical fiber tapes (user-side M-core optical fibers) 56 are connected to the user side of the cross wiring unit 51. In this case, the cross wiring module 55 performs a total of 32 (N × M = 8 × 4 = 32) cross wirings from the transmission devices 21, 22, 23, and 24.
As described above, in this embodiment, as the number of users increases, the number of four-fiber FO cords (device-side multi-core optical fibers) for each transmission device is increased, and the number of wires of the cross wiring module is increased. It corresponds.

The optical wiring system between the optical fiber connection unit and the transmission device in each of the above embodiments uses an FO cord as the device-side optical fiber and is connected to the transmission device side by a connector, as shown in FIG. As in the embodiment, the connection with the transmission apparatus side may be a fusion connection.
FIG. 7 shows a case where there are two transmission devices as in FIG. The connection between the data transmission device 21 and the optical fiber connection unit 30 is made by the four-fiber FO cord 25, which is the same as the embodiment of FIG. 1, but the image transmission device 22 ′ and the optical fiber connection. For connection with the unit 30, a four-fiber tape cord 26 'is used as the device-side multi-core optical fiber, and the video transmission device 22' side of the four-core tape cord 26 'is fused in the same manner as the cross wiring unit 31 side. Incoming connection.
Although the image transmission device 22 ′ in the illustrated example is schematically illustrated, the image transmission device 22 ′ includes an optical splitter fusion unit 62 connected to an electric / optical converter 61 for image signals, and an output fiber of the optical splitter 63. 63a and the optical fibers of the four-core tape cord 26 'are fused and connected. If necessary, another optical splitter and an optical amplifier are interposed between the electric / optical converter 61 and the optical splitter fusion unit 62.

According to the optical wiring system shown in FIG. 7, since the video transmission device 22 ′ is fusion-bonded not only on the optical fiber connection unit 30 side but also on the transmission device side, no optical adapter is required on the transmission device side. Can be miniaturized.
In FIG. 7, only the video transmission device is fusion-bonded on both sides of the device-side optical fiber. However, the same optical wiring system as that of the video transmission device 22 ′ in FIG. 7 can be adopted for all the transmission devices. .

In each of the above embodiments, it is assumed as a facility for introducing an optical fiber into a large-scale apartment building, etc., and the opposite side of the transmission device cross wiring unit is a communication line, but the transmission device and the cross wiring unit are It is also possible to apply it as equipment in a station building. In this case, the user-side four-core optical fiber tapes 36, 46, and 56 serve as communication lines, but maintenance on the line side is facilitated by previously performing cross wiring on the station side. As the number of systems increases, the maintainability on the line side becomes more important, and the effect of the present invention is exhibited.

It is typical structure explanatory drawing of the optical fiber connection unit and optical wiring system of one Example of this invention. It is typical structure explanatory drawing of the optical fiber connection unit and optical wiring system of the other Example of this invention. It is a figure which shows the structure of the cross wiring unit in FIG. 2, and illustrates the cross wiring state of a cross wiring module. An example of the specific internal structure of an optical termination box is schematically shown, (A) is a plan view, (B) is a front view, and (C) is a side view. It is typical structure explanatory drawing of the optical fiber connection unit and optical wiring system of other Example of this invention. It is typical structure explanatory drawing of the optical fiber connection unit and optical wiring system of other Example of this invention. It is typical structure explanatory drawing which shows the other Example of an optical wiring system. It is typical structure explanatory drawing of the conventional optical fiber connection unit and an optical wiring system.

Explanation of symbols

21, 22, 22 ', 23, 24 Transmission devices 25, 26, 27, 28 4-core FO cord (device side multi-core optical fiber)
26 '4-core tape cord (multi-fiber optical fiber)
30, 40, 40A, 50 Optical fiber connection unit 31 Cross wiring unit 41, 42, 43 Cross wiring unit 51, 52, 53 Cross wiring unit 35, 45, 55 Cross wiring module 35a, 45a, 55a Cross wiring of cross wiring module Device side end portions 35b, 45b, 55b Cross-wiring module cross-wiring user side end portions 36, 46, 56 User-side 4-core optical fiber tapes 37, 47, 57 Device-side fusion splicing portions 38, 48, 58 User side fusion splicer 49 Optical termination box

Claims (4)

A cross wiring unit to which transmission devices of M systems (M is a number of 2 or more) are connected;
The cross wiring unit has one or a plurality of apparatus side multi-cores each having a total number of cores of N (N is the number of users) or more, wherein at least the cross wiring unit side is fusion-bonded to each transmission apparatus. Connected by optical fiber,
N user side M-core optical fibers are connected to the user side of the cross wiring unit by fusion splicing,
The cross wiring unit includes a cross wiring module, and the cross wiring module receives a total of N × M optical fibers from each transmission device and M optical fibers corresponding to each transmission device for each user. An optical fiber connection unit characterized by cross wiring so as to be distributed.   2. The optical fiber connection unit according to claim 1, wherein there are a plurality of the cross wiring units, and they are accommodated in one wiring box. An optical wiring system for connecting between the optical fiber connection unit of claim 1 and the transmission device by a device-side multi-core optical fiber,
An optical wiring system characterized in that an FO cord is used as the device-side multi-core optical fiber, one end of the FO cord is fusion-bonded to the cross wiring unit side, and the other end is connected to the transmission device by a connector. An optical wiring system for connecting between the optical fiber connection unit of claim 1 and the transmission device by a device-side multi-core optical fiber,
A multi-fiber tape cord is used as the device-side multi-core optical fiber, and one end of the multi-fiber tape cord is fused and connected to the cross wiring unit side, and the other end is also fused and connected to the transmission device. Optical wiring method.

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