SE520463C2 - Multifibre cabling system for optical fibre network - Google Patents

Abstract

The optical fibre network includes at least one cable (15). The cable holds a number of ribbon fibres (9,11,13) and is connected to a line station (7) at a head end to transmit and receive information on individual optical fibres (19) comprised in the ribbon fibres. The optical fibre network also has several branching points provided between the head end of the cable and a far end of the cable. At each branching point at least one of the ribbon fibres is cut-off and at least one of the individual optical fibres in a cut-off ribbon fibre is connected to a subscriber. A cut-off ribbon fibre is divided into one head end ribbon fibre piece which extends from the head end to a branching point and one far end ribbon fibre piece which extends from a branching point to the far end. In a branching point, where there is an end of an individual optical fibre in a head end ribbon fibre piece which is not connected to a subscriber, this end is connected to an end of an individual optical fibre in a far end ribbon fibre piece.

Description

5 35 462 subscribers, the remaining defoaming fibers are connected by means of connecting fiber pieces, so that these fibers continue uninterrupted through the branch point. At a different branch point there are subscribers other than individual fibers in the skimming bands and then the subscribers are connected with individual fibers both in the proportion of fiber bands which lie in the direction of the line cards and with the skimmed portions which are at a distance from them. At the unconnected end of the cable, suitable ends of the optical fibers therein are connected to each other, so that a subscriber can, for example, be connected by a length of fiber, which extends to the end of the cable, at this point via a short piece of fiber to one end of another fiber, this second fi ber extending to a branch point where it is connected for passage to a fiber, which extends directly to the central station. In this way, the capacity of the fiber ribbons can be efficiently utilized, even when there are a number of subscribers in one place, which is not an even multiple of the number of individual fibers in a fiber ribbon.

In this way, this system reduces the above-mentioned disadvantage, by combining partially filled fiber ribbons at a distal end of a cable, so that fully or almost completely used fiber ribbons are obtained. The cable system is thus used almost completely and almost all fiber lengths are used to transmit information.

DESCRIPTION OF THE DRAWINGS The invention will now be described in detail as a non-limiting exemplary embodiment with reference to the accompanying drawings, in which: Fig. 1 is a schematic view of a part of a telecommunication network, showing the connection of subscribers with line cards, and - Figs. . Fig. 2 is a view showing a mechanical connecting unit to be used when branching from the net of Fig. 1.

DESCRIPTION OF THE PREFERRED EMBODIMENT The system depicted in Fig. 1 is part of a telecommunication network which utilizes fi professional communication from line cards 1 to subscribers, which are located at two different geographical locations 3, 5. The line cards 1 are located in a telecommunication station 7, which is connected to a slightly larger, not shown, transport network. In the line cards 1 there are optical transmitters and devices in matrix devices (not shown) and are connected to output optical lines. Thus, a fiber ribbon 9, 11, 13 extends from each line card 1, which is connected to the matrix devices on the card, for example via a fiber ribbon connector (not shown). A large number of such fiber bands 9, 11, 13 are combined into a professional cable 15, which provides a common housing for the plurality of fiber bands 9, 11, 13. The cable 15 extends from the telecommunication station 7 within a limited geographical area, for example, to reach subscribers to this at various locations along the cable. At a location 3, 5, where there are one or fl your subscribers, a branch is made from the cable 15. At such a branch point one or fl your fiber bands are cut off, at the location 3 the fiber band 9 and at the location 5 the fiber band 11, as shown in the figure . At the suitably cut ends of the fiber ribbons, these are released from their outer protective and cohesive casing to divide them into individual fibers. At one branch point, the rest of the fiber strips continue to other branch points and also the portions located at the remote end or the remote portions 17 of the cut fiber strips, which are not used, continue to the unconnected end of cable 15.

To use these spaced portions 17 of the truncated branched fi bands, both of the truncated ends are divided into individual fi bres 19. A single piece of fiber extending from a line card 1 to a branch point and not connected to a subscriber at this branch point, then connect to a fiber length in the carrier band portion 17 at the distal end extending from the branch point to the end of the cable 15, as shown by the fiber lengths 21 at location 3. If there is no such individual fiber length, since there are fls subscribers than there are individual fibers in the carrier band, first the cut ends of the fiber portion near the line board are connected to subscribers and then the rest of the subscribers are connected to individual fibers in the fiber band portion 17, which extends away from the branch point to the distal end of the cable 15, as shown at location 5. In this way, the far end, i.e. the end, which is not connected to the station 7, of the cable 15 to contain both fiber ribbons with fibers which can be used for connections to new subscribers and fiber ribbons which have fibers connected to subscribers which must be connected to a line card 1.

At the distal end of the cable 15, all the fiber ribbons in the cable are made available and then the suitable ribbons are connected there with other suitable ribbons, as shown by the fiber ribbon length 23 in the figure. A band which is not used or is only partially used and which thus has fibers which are connected to the line card is connected to another fiber band which has fibers which are connected to subscribers. Assume that the fibers in a fiber band are always numbered in the same way 1, 2, and that the connection of subscribers at the branch point is always made in the same way starting with fiber No. 1, then No. 2, etc., then this will lead to the combination of two bands at the end of the cable can be done by arranging a reverse connection order. Then, in the case shown in the figure, in which the fiber ribbons contain four fibers, fiber No. 1 in the first fiber ribbon is connected to fiber No. 4 in the second fiber ribbon, fiber No. 2 in the first fiber ribbon is connected to fiber No. 3 in the second ribbon, etc. Alternatively, other means may be provided to connect the fibers to the distal end of the cable 15, for example by using individual fiber lengths which interconnect ends of two individual fibers in different fiber bands.

Provided that there is a statistical distribution of subscribers (this ratio can be approximately valid, if the number of subscribers and fiber bands in the cable is large), the use of matrix devices and fiber bands in the manner described above will be more efficient than using only fibers , which extend directly from the line card to the subscriber.

Fig. 2 shows a mechanical splicing device 27, which can be used when a branch is made from the cable 15, for example at the geographical location 5 in Fig. 1. The device 27 has an inlet 29 for a fiber ribbon 11, which extends directly from a line card, the inlet being located at one side of a rectangular housing 31. To the opposite sides of the housing 13, four standard type MT connectors 33 are attached, each for two fibers, which are intended to be connected to the corresponding connector 35 for pairs of optical fibers 37, which extend directly to a subscriber. Inside the housing 27, the four fibers 39 in the incoming carrier 11 are divided into two groups of two fibers, so that the fibers in one group are connected to a corresponding MT interface 33. Thus, two MT interfaces are connected to the incoming carrier 11.

The other two MT interfaces are connected to the optical fibers of the remote portion 17 of the same carrier band, one end of this remote portion entering the housing 31 on the side where the MT interfaces are located.

Claims (4)

20 520 463 5 PATENT CLAIMS An optical fiber network comprising at least one cable containing a plurality of fiber ribbons which are connected to a line station at a main end for transmitting and receiving information on individual optical fibers contained in the fiber ribbons, a plurality of branch points being arranged between the head end and a distal end thereof, at each branch point at least one of the fiber bands is cut off and at least one of the individual optical fibers therein is connected to a subscriber, so that a cut fiber band is divided into a fiber band length at the head end, extending from the main end to a branch point, and a fiber band length at the distal end extending from a branch point to the distal end, characterized in that at a branch point, where there is one end of an individual fiber in a fiber band length at the main end, which is not connected to a subscriber, this end is connected to one end of a single fiber in a fiber band length at the far end. Optical fiber network according to claim 1, characterized in that at a branch point subscribers are connected to individual fibers both in the fiber band length at the main end and the fiber band length at the distal end. Optical according to one of Claims 1 to 2, characterized in that at the far end of the cable at least one individual fiber in a fiber band is connected to another individual fiber in another fiber band. Optical fiber network according to claim 3, characterized in that at the far end of the cable at least one fiber band is connected to another fiber band, so that all individual fibers in these fiber bands are connected to another individual fiber.