JP4268067B2 - Premise wiring method and premise network system - Google Patents

Description

  The present invention relates to a premises wiring method and a premises network system for laying communication optical cables in a building.

  Conventionally, in order to carry out optical wiring to each floor in a building such as a building using an optical cable, an optical cable is installed in the vertical direction of the building, and this optical cable is branched by an optical connection box on each floor. It was wired to the floor communication device (for example, see Non-Patent Document 1).

The applicant has not yet found prior art documents related to the present invention by the time of filing other than the prior art documents specified by the prior art document information described in this specification.
“Optical Connection Box / SPE Series”, Optical Connection Box / HUB Storage Cabinet System Rack Catalog, Nitto Kogyo Co., Ltd., May 2003, p. 16

In the conventional premises wiring method, an optical cable with a predetermined connection destination is laid in the vertical direction of the building, and this optical cable is connected to an optical connection box by a connector and optically connected to a floor communication device via an optical cord. The connection between the optical cable and the communication device was realized by connecting the box. For this reason, with the conventional on-site wiring method, optical wiring can be realized only between predetermined floors or within floors, and in order to realize connections that were not initially planned, optical cables must be laid again. There was a possibility of having to.
The present invention has been made to solve the above-described problems, and provides a local area wiring method and a local area network system that can flexibly respond to a user's needs and can easily realize an optical line desired by the user. For the purpose.

The present invention relates to a branch wiring block in which a trunk optical cable composed of a plurality of cores is laid and a floor is divided in a premises wiring method for laying an optical cable in a building so that connection between any two floors is possible. laying the branch line optical cable, the arrangement mains light cabinet for each floor, one end of said branch line optical cable laid in the placement destination floor accommodates one end or the middle portion of the trunk optical cable with unconnected free to It is accommodated in a connected state, and the other end of the branch line optical cable laid in the branch line block at the placement destination is accommodated in the branch line optical cabinet arranged for each branch block on each floor.
In addition, according to one configuration example of the on-premises wiring method of the present invention, the main line optical cable and the branch line optical cable are connected by the main line optical cabinet according to the needs of the user, and the communication device arranged in the branch line block and the branch line A branch line optical cable laid on the block is connected by the branch line optical cabinet.
Further, in one configuration example of the on-premises wiring method of the present invention, the trunk optical cabinet accommodates one end or a middle portion of the trunk optical cable in units of tape cores, and the trunk optical cable and the branch line as required by a user. It has a plurality of core wire storage shelves to which optical cables are connected, and can be locked for each of the core wire storage shelves.

Further, the campus network system of the present invention is a trunk optical cable composed of a plurality of core wires preliminarily laid between any two floors, a branch optical cable laid in advance for each branch block dividing each floor, Arranged for each floor , accommodates one end or a middle portion of the trunk optical cable in a non-connected state, and accommodates one end of the branch optical cable laid on its floor in a non-connected state, and stores the trunk optical cable The main optical cabinet that enables the connection between the branch optical cable and the branch optical cable and the other end of the branch optical cable that is arranged for each branch block on each floor and is laid on the own branch block. A branch line optical cabinet enabling connection with a communication device arranged in a block is provided.
Further, according to one configuration example of the local area network system of the present invention, the main line optical cable and the branch line optical cable are connected by the main line optical cabinet according to the needs of the user, and the communication device arranged in the branch line block and the branch line are connected. A branch line optical cable laid on the block is connected by the branch line optical cabinet.
Further, in one configuration example of the local network system according to the present invention, the trunk optical cabinet accommodates one end or a middle portion of the trunk optical cable in units of tape cores, and the trunk optical cable and the branch line as required by a user. It has a plurality of core wire storage shelves to which optical cables are connected, and can be locked for each of the core wire storage shelves.

  According to the present invention, a trunk optical cable composed of a plurality of core wires is laid so that connection between any two floors is possible, and a branch optical cable is laid for each branch block obtained by dividing each floor. In the trunk optical cabinet that is placed, accommodate one end of the trunk optical cable or the middle part, and accommodate one end of the branch optical cable laid on the floor of the placement destination, to the branch optical cabinet arranged for each branch block on each floor, By accommodating the other end of the branch line optical cable laid on the branch line block at the placement destination, optical wiring can be easily realized between any floors and within any floor, according to the needs of the user, etc. Can respond flexibly.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a local network system according to an embodiment of the present invention, and FIG. 2 is a diagram three-dimensionally showing the local network system of FIG.
The on-site network system of this embodiment is constructed in a four-story building consisting of floors 1F to 4F, and is laid in advance so that connection between any two floors is possible without disconnection. Further, a trunk optical cable 11 composed of a plurality of core wires, and branch optical cables 12 (12A-2 to 12D-2, 12A-3 to 12D-3) previously laid for each branch block A to D obtained by dividing each floor 1F to 4F. , 12A-4 to 12D-4) and each floor 1F to 4F, and accommodates one end or a middle portion of the trunk optical cable 11 and also accommodates one end of the branch optical cable 12 laid on its floor. Main optical cabinet 13 (13-1, 13-2, 13-3, 13-4) that enables connection between the main optical cable 11 and the branch optical cable 12, and each floor 1F to F is arranged for each of the branch line blocks A to D of F, accommodates the other end of the branch line optical cable 12 laid on its own branch line block, and communication devices 101 to 101 such as computers arranged on this branch line optical cable 12 and its own branch line block. The branch line optical cabinet 14 (14A-2 to 14D-2, 14A-3 to 14D-3, 14A-4 to 14D-4) that enables connection to the 104, the communication devices 101 to 104, and the branch line optical cabinet 14 And an optical cord 15 (15B-2, 15B-3, 15C-3, 15D-3).

  FIG. 3 is a diagram showing the internal structure of the trunk optical cabinet 13. In FIG. 3, the inside of the trunk optical cabinet 13 is seen through, but the optical cables 11 and 12 and the tape cores 110 and 120 are indicated by solid lines. FIG. 3 shows an example of the trunk optical cabinet 13 installed on the floor N. 11- (N + 1) is the trunk optical cable heading to the upper floor (N + 1), and 11- (N-1) is the bottom. The trunk optical cable which goes to the floor (N-1) of a floor is shown.

The trunk optical cable 11 is composed of a plurality of tape cores 110 laid in advance so as to enable connection between any two floors, for example, between the floors 1F and 4F. How many tape cores 110 are laid in advance between which floors is determined, for example, from past wiring results.
The branch line optical cable 12 includes a plurality of tape cores 120 laid in advance so that the communication apparatuses 101 to 104 arranged on the branch line blocks A to D of the floors 1F to 4F can be connected to the trunk line optical cable 11. . In the present embodiment, the tape cores 110 and 120 have eight cores.

The trunk optical cabinet 13 includes a trunk conductor 130 for housing the trunk optical cable 11, a branch receptacle 131 for accommodating the branch optical cable 12, and a core wire for connecting the trunk optical cable 11 and the branch optical cable 12 in units of tape cores. And a storage shelf 132.
The trunk optical cable 11 accommodated in the trunk accommodating section 130 is drawn out from the trunk accommodating section 130 onto the tray 1320 of the core accommodating shelf 132 for each tape core 110. There are a plurality of core wire storage shelves 132 in the trunk optical cabinet 13, and one core wire storage shelf 132 has, for example, ten trays 1320. Therefore, for example, 8 × 10 = 80 cores are stored in one core wire storage shelf 132.

On the other hand, the tape core 120 of the branch line optical cable 12 accommodated in the branch line accommodating part 131 is accommodated in the branch line accommodating box 1310 of the branch line accommodating part 131 as a reserved core line when the trunk optical cable 11 to be connected is undecided.
In the state of FIG. 3, the trunk optical cable 11 and the branch optical cable 12 are only accommodated in the trunk optical cabinet 13, and the trunk optical cable 11 and the branch optical cable 12 are not connected. The connection between the trunk optical cable 11 and the branch optical cable 12 will be described later.

FIG. 4 is a diagram showing the internal structure of the branch line optical cabinet 14. The branch line optical cabinet 14 includes a branch line storage unit 140 that stores the branch line optical cable 12, and a cord storage unit 141 that stores an optical cord (not shown in FIG. 4) that connects the branch line optical cable 12 and the communication devices 101 to 104. And a conversion module 142 for converting the tape core 120 of the branch line optical cable 12 into a single core.
The tape core wire 120 of the branch line optical cable 12 accommodated in the branch line accommodating portion 140 is connected to the conversion module 142 by the MT connector 121.

  As described above, the branch line optical cabinet 14 is arranged for each of the branch line blocks A to D of the floors 1F to 4F. The number of tape core wires 120 necessary for each floor 1F to 4F is determined in advance for each floor from the past wiring performance. The tape core wires 120 of each floor 1F to 4F are distributed to a plurality of branch line blocks, and the number of branch line blocks is determined for each floor so that the number of core wires per unit area when distributed is a predetermined number. In the example of FIGS. 1 and 2, the floors 2F to 4F are divided into four branch lines blocks A to D, respectively.

  Next, the case where the communication apparatus 101 arrange | positioned at the branch line block B of the floor 2F and the communication apparatus 102 arrange | positioned at the branch line block C of the floor 3F are connected according to a user's need etc. is demonstrated. FIG. 5 is a diagram illustrating a wiring method for connecting the communication apparatuses 101 and 102. In the example of FIG. 5, the connection work in the trunk optical cabinet 13-2 and the branch optical cabinet 14B-2 on the floor 2F is shown.

  First, on the floor 2F, the operator opens the core wire storage shelf 132 in which the tape core wires 110 laid between the floor 3F and the core wire storage shelves 132 of the trunk optical cabinet 13 are stored. Then, the tray 1320 on which the corresponding tape core wire 110 is placed is pulled out from the core wire storage shelf 132. Further, the operator pulls out the tape core wire 120 accommodated in the branch line accommodation box 1310 of the branch line accommodation portion 131 as a reserved core wire toward the tray 1320 side.

  Then, the operator cuts the tape core 110 on the tray 1320 at the location indicated by “x” in FIG. 5 and mechanically connects the tape core 110 directed to the floor 3F and the tape core 120 pulled out on the tray 1320. Splice connection. In this way, in the trunk optical cabinet 13-2, the trunk optical cable 11 directed to the floor 3F and the branch optical cable 12B-2 laid on the block B of the floor 2F are connected in units of tape cores.

  Next, the operator lays the optical cord 15B-2 on the block B of the floor 2F, connects one end of the optical cord 15B-2 to the communication device 101, and is attached to the other end of the optical cord 15B-2. The SC connector 151 is attached to the conversion module 142 of the branch line optical cabinet 14B-2. Thus, in the branch line optical cabinet 14B-2, the communication apparatus 101 is connected to the main line optical cable 11 by connecting the branch line optical cable 12B-2 and the optical cord 15B-2.

  The connection work on the floor 3F is the same, and the worker opens the core wire storage shelf 132 of the main line optical cabinet 13-3 and connects the tape core 110 of the main line optical cable 11 connected to the branch line optical cable 12B-2 on the floor 2F. The optical fiber cable 12C-3 of the branch line optical cable 12C-3 laid on the block C of the floor 3F is connected. Further, the operator lays the optical cord 15C-3 on the block C of the floor 3F, connects one end of the optical cord 15C-3 to the communication device 102, and is attached to the other end of the optical cord 15C-3. The SC connector 151 is attached to the conversion module 142 of the branch line optical cabinet 14C-3.

  Through the above operation, the communication device 101 on the floor 2F and the communication device 102 on the floor 3F can be connected. In the example of FIG. 5, since the tape core 110 of the trunk optical cable 11 is laid from the floor 1F to the floor 3F through the floor 2F, the middle portion of the tape core 110 is placed on the trunk optical cabinet 13 of the floor 2F. -2 is cut and connected to the tape core 110 of the branch optical cable 12B-2 and the tape core 110 toward the floor 3F, but the terminal end of the tape core 110 of the trunk optical cable 11 is accommodated. In the case of the trunk optical cabinet 13, the end of the tape core wire 110 and the branch optical cable 12 are connected.

  As described above, in this embodiment, the trunk optical cable 11 is laid in advance so that the connection between any two floors can be performed without disconnection, and the branch optical cable 12 is laid in advance for each branch block on each floor. Then, the tape core 110 of the trunk optical cable 11 and the tape core 120 of the branch optical cable 12 are connected by the trunk optical cabinet 13 according to the needs of the user. For this reason, the tape core 110 of the main optical cable 11 accommodated in the main optical cabinet 13 is cut at the middle part and connected to the tape core 120 of the branch optical cable 12 or is accommodated in the main optical cabinet 13. By connecting the end of the tape core 110 of the trunk optical cable 11 and the tape core 120 of the branch optical cable 12, optical wiring can be easily realized between arbitrary floors and within arbitrary floors. It is possible to respond flexibly according to the situation.

Moreover, according to this Embodiment, since it was made possible to lock for every core wire storage shelf 132 of the trunk optical cabinet 13, it is made impossible to unlock the core wire storage shelf 132 not related to the wiring work. Security can be ensured.
In addition, by pulling out only the tray 1320 on which the core wire to be subjected to wiring work is placed from the core wire storage shelf 132, it is possible to prevent other core wires from being touched. Workability can be improved.

  The present invention can be applied to premise wiring in the information communication field.

It is a block diagram which shows the structure of the local network system used as embodiment of this invention. It is the figure which represented the local area network system of FIG. 1 in three dimensions. It is a figure which shows the internal structure of the trunk line optical cabinet in embodiment of this invention. It is a figure which shows the internal structure of the branch line optical cabinet in embodiment of this invention. It is a figure which shows the wiring method which connects between communication apparatuses.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 ... Main line optical cable, 12 ... Branch line optical cable, 13 ... Main line optical cabinet, 14 ... Branch line optical cabinet, 15 ... Optical cord, 110, 120 ... Tape core wire, 121 ... MT connector, 130 ... Main line accommodation part, 131 ... Branch line accommodation , 132 ... core wire storage shelf, 140 ... branch line storage part, 141 ... cord storage part, 142 ... conversion module, 150 ... two core cord, 151 ... SC connector, 1310 ... branch line storage box, 1320 ... tray, AD ... branch block.

Claims (6)

In the premises wiring method of laying optical cables in buildings,
Laying a trunk optical cable consisting of multiple cores so that any two floors can be connected,
A branch optical cable is laid for each branch block that divides each floor,
In the trunk optical cabinet arranged for each floor , accommodate one end of the trunk optical cable in a non-connected state and accommodate one end of the branch optical cable laid on the placement destination floor in a non-connected state ,
A premises wiring method characterized in that the branch line optical cabinet disposed for each branch block on each floor accommodates the other end of the branch line optical cable laid on the branch block at the placement destination. The premises wiring method according to claim 1,
The main line optical cable and the branch line optical cable are connected by the main line optical cabinet as required by the user, and the communication device arranged in the branch line block and the branch line optical cable laid in the branch line block are connected by the branch line optical cabinet. A premise wiring method characterized by connecting. In the local wiring method according to claim 1 or 2,
The trunk optical cabinet accommodates one end or a middle portion of the trunk optical cable in units of tape cores, and has a plurality of core wire storage shelves to which the trunk optical cables and the branch optical cables are connected as required by the user. And
A premises wiring method, wherein each core wire storage shelf can be locked. A trunk optical cable composed of a plurality of core wires pre-laid between any two floors;
A branch optical cable laid in advance for each branch block dividing each floor;
Arranged for each floor, accommodates one end or a middle portion of the trunk optical cable in a non-connected state, and accommodates one end of the branch optical cable laid on its floor in a non-connected state, and stores the trunk optical cable And a trunk optical cabinet that enables connection with a branch optical cable,
A branch line that is arranged for each branch line block on each floor, accommodates the other end of the branch line optical cable laid on its own branch line block, and enables connection between this branch line optical cable and a communication device disposed on its own branch line block A premises network system comprising an optical cabinet . In the local area network system according to claim 4,
The main line optical cable and the branch line optical cable are connected by the main line optical cabinet as required by the user, and the communication device arranged in the branch line block and the branch line optical cable laid in the branch line block are connected by the branch line optical cabinet. A campus network system characterized by connecting. The local area network system according to claim 4 or 5,
The trunk optical cabinet accommodates one end or a middle portion of the trunk optical cable in units of tape cores, and has a plurality of core wire storage shelves to which the trunk optical cables and the branch optical cables are connected as required by the user. And
A local area network system capable of being locked for each of the core wire storage shelves.

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