GB2165661A

GB2165661A - Optical fibre junction box

Info

Publication number: GB2165661A
Application number: GB08518694A
Authority: GB
Inventors: John Victor Smoker; Edward Kitchener George; Roger Erwin Jung
Original assignee: Telephone Cables Ltd
Current assignee: Telephone Cables Ltd
Priority date: 1984-10-15
Filing date: 1985-07-24
Publication date: 1986-04-16
Also published as: GB8518694D0; GB8426008D0; GB2165661B

Abstract

In order to allow an optical cable to be accessed by spur cables (12) at various points along its length after it has been laid, connection housings (2) are provided at intervals along its length. A loop of the main cable (1) is passed into each housing (2) so that at a later date there is an excess of cable (6) to enable connections to be made to it. Each housing contains fittings such as manifolds (13) and organiser trays (15) where the optical fibres are spliced and includes several access ports (10) which are covered over until it is required to connect a spur cable to the main cable. <IMAGE>

Description

SPECIFICATION Optical communication system This invention relates to optical communication systems of the type comprising a main optical fibre cable having a plurality of optical fibres within a protective cover and in which the cable is required to be accessed by spur cables at spaced points along its length.

When such access points are known at the time of laying the main cable no problem arises since allowance can be made for the extra length of cable required for making the connections. However, if, at a future date, further connections are necessary, it could be found that the main cable does not have enough slack to allow the connections to be made.

Accordingly, the present invention provides an optical communication system incorporating a main optical fibre cable having a plurality of optical fibres within a protective cover, and at least one connection housing for allowing access to said cable intermediate its ends, the or each connection housing having an inlet and an outlet for the main cable, which is passed therethrough so as to provide an excess length of cable within the housing, and at least one access port which allows, in use, a spur cable to be passed into the housing and connected to the main cable.

Preferably there is a plurality of said connection housings provided at spaced intervals along the length of the cable.

Preferably also, the access port of the housing is normally closed off by a cover until it is required to connect a spur cable to the main cable, at which time the cover is removed to allow access to the interior of the housing.

Conveniently, the connection housing may already contain the fittings required to connect the fibres of the main cable to those of the spur cable, but alternatively, these may be positioned in the housing at the time of making the connections.

Such fittings may comprise means for allowing access to individual fibres in each of the main and spur cables as required, means for connecting the fibres of the main cable to those of the spur cable as required, and means for storing any excess length of fibre.

Preferably said excess length of cable provided within each housing is at least two metres and may be more so as to give sufficient length to allow several connections to be made if desired.

Preferably the connection housing incorporates a plurality of trays each arranged to accommodate excess lengths of optical fibres and each of which is movable in relation to the others to facilitate access to it. Thus the trays may be in the form of a stack of superposed drawers, each of which is withdrawable from the stack.

Two embodiments of the invention will now be described by way of example with reference to Figures to 4 of the accompanying drawings, in which Figure 1 illustrates a perspective view of part of one form of housing for use in an optical communication system in accordance with the invention, Figures 2 and 3 represent a perspective view and a side view respectively of an alternative form of housing for use in such an optical communication system, and Figure 4 represents a plan view of part of the housing.

Referring first to Figure 1, in order to allow access to a main optical cable 1 which forms part of an optical communications system, several connection housings 2, one of which is shown in the drawings, are provided at spaced intervals along the length of the cable 1.

The connection housing 2, which comprises four walls 3, a base 4 and a removable lid (not shown), has an inlet/outlet cable port 5 in one of the walls 3 for the main cable 1, the cable port being fitted with a tubular projection, as at 16 through which the cable passes. In this embodiment, the cable 1 is of the type in which a plurality of tubes 6, e.g.

sixteen, each containing several fibres 7, e.g.

ten, are stranded together within a protective sheath 8. The entry and exit of the cable to and from the cable port 5 is kept free of contamination by covering the projection and adjacent part of the cable sheath with a heatshrinkable sleeve 9 such as are well known in the art.

When the cable 1 enters the housing 2, it is looped round the housing several times to provide an excess length of cable, e.g. two metres, within the housing and is then led out again via the cable port 5, the part of the cable within the housing being stripped off the protective sheath 8 so as to expose the stranded tubes 6.

The housing is also provided with a number of access ports 10 in the walls 3, four being shown in the drawings. These access ports 10 are closed off by the wall of housing extending over them until such time as it is required to connect a spur cable 11 to the main cable 1, when the part of the wall closing off the access port is removed to allow the spur cable 11 to be passed into the housing 2 as is shown in the drawings for one of the access ports. The spur cable 11 may incorporate any number of fibres, e.g. between ten and eighty fibres, and may be of any desired construction.

Such a spur cable 11 is passed through a tubular projection 17 fitted to the access port 10 and the projection and adjacent part of the cable are covered by a heat-shrinkable sleeve 12 in a similar manner to that of the main cable 1 as described above, the end of the spur cable 11 within the housing being clamped by a clamp 14.

In order to make the connection between the fibres 7 from the main cable 1 and the spur cable 11, the requisite number of tubes 6 are unravelled from the main cable 1 as at 6' and are passed to manifolds 13. In the case of the embodiment as illustrated this is only done for one tube having up to ten optical fibres 7. At this point the tube 6' is broken into, allowing the optical fibres 7, only some of which are shown, to be passed through the manifold 13, to a respective organiser tray 15 as shown, where the fibres are joined to the fibres of the spur cable which have similarly been passed from the clamp 14 via a manifold (not shown) to the organiser tray 15.

Any fibres not connected at this time are stored in the organiser tray and may be connected at a later date if desired.

As will be appreciated, further cable connections are also possible at later times due to the other access ports provided and a system according to the invention thus provides means whereby many connections may be made to a cable after it has been laid.

An alternative form of housing for use in a communication system in accordance with the invention is illustrated in Figures 2 to 4.

The housing incorporates an inner unit comprising a frame 22 having upper and lower plates 23, 24 fixed to an end plate 21, and supporting between them two spaced tray supports 25 which are provided on their inner surfaces with a plurality of horizontally-extending grooves 26. Each corresponding pair of grooves supports between them a respective organiser tray 27 which can be slid out sideways from the stack of trays as shown in Figure 4.

The frame/organiser tray assembly is arranged to be accommodated in a rectangular metal enclosure 28 (Figs 2 and 3). The enclosure has one open end and the frame/organiser tray assembly is introduced into the enclosure by sliding it in from the open end. The enclosure is provided, around the open end with an outwardly directed flange 29 to which the end plate 21 of the inner unit is arranged to be secured, as by screws 31, a gasket between the end plate and the flanges providing a moisture-proof seal.

The end plate 21 of the inner unit has a cable port 30 for the main cable 1 in the form of an elongate opening surrounded on the external face of the plate with a tubular crosssection of a corresponding cross-section. The cable, as in the first embodiment, also consists of a plurality of tubes 35 stranded together in a protective sheath 36 and each accommodating several optical fibres.

Within the enclosure 28 the cable 1, stripped of its protective sheath 36 so as to expose the stranded tubes 35, is looped around a tray 39 fixed to the top of the upper frame plate 23, as shown in Figure 4, to provide an excess length of cable for forming connections to one or more spur cables as will subsequently be described. The cable then passes out of the enclosure through the same cable port.

To prevent the entry of moisture into the enclosure 28 the projection 34 and the adjacent parts of the cable sheath 36 are covered by a heat-shrinkable sleeve 38.

The end plate 21 is also provided with a number of access ports 40, for example four as shown in Figure 2, by which spur cables, as required, may enter the enclosure 28, each access port 40 being surrounded on the outside of the end plate 21 by a tubular projection 43, and where a spur cable, as at 42, enters the enclosure the respective projection and adjacent part of the cable are enclosed by a heat-shrinkable sleeve 44. The projections 43 of those access ports 40 which are not used are enclosed by a close-ended heatshrinkable sleeve (not shown).

In order to make a connection between fibres 45 from the main cable 1 and fibres 46 from a spur cable 42, the inner unit incorporating the frame/organiser tray assembly is first withdrawn from the enclosure 28. The requisite number of tubes 35 (only one of which is shown at 35') are unravelled from the unsheated part of the main cable 1 and passed to a manifold 47. The tubes are then broken into and fibres 45 from them led from the manifold to one or more of the organiser trays 27. Fibres 46 from the spur cable 42 are similarly passed to the respective organiser trays via a manifold shown at 48. Connections are made between the fibres 45 of the main cable 1 and the spur cable fibres 46 by means of any suitable form of connector, shown diagrammatically at 49 in Figure 4.

Any excess lengths of fibres, and those fibres not employed, are looped several times around the respective organiser trays, and the fibres not connected at this time may be connected at a later date if required. The excess length of cable and fibres facilitates the making of the connections as and when desired, and as in the first embodiment the housing provides means enabling many connections to be made to a cable after the cable has been laid.

Claims

1. An optical communication system incorporating a main optical fibre cable having a plurality of optical fibres within a protective cover and at least one connection housing for allowing access to said cable intermediate its ends, the or each connection housing having an inlet and an outlet for the main cable, which is passed therethrough so as to provide an excess length of cable within the housing, and at least one access port which allows, in use, a spur cable to be passed into the housing and connected to the main cable.

2. An optical communication system according to Claim 1 wherein the access port of the housing is normally closed off by a cover until it is required to connect a spur cable to the main cable, at which time the cover is removed to allow access to the interior of the housing.

3. An optical communication system according to Claim 1 or 2 wherein the connection housing is provided with fittings for connecting one or more fibres of the main cable to the respective fibre or fibres of the spur cable.

4. An optical communication system according to Claim 1 or 2 wherein fittings for connecting one or more fibres of the main cable to the respective fibre or fibres of the spur cable are positioned in the housing at the time of making the connection.

5. A communication system according to Claim 3 or 4 wherein said fittings comprise means for allowing access to individual fibres in each of the main and spur cables as required, means for connecting the fibres of the main cable to those of the spur cable as required, and means for storing any excess length of fibre.

6. A communication system according to any preceding Claim qherein said excess length of cable provided within the housing is at least two metres.

7. A communication system according to any preceding Claim wherein the connection housing incorporates a plurality of trays each arranged to accommodate excess lengths of optical fibres and each of which is movable in relation to the others to facilitate access to it.

8. A communication system according to Claim 7 wherein the trays are in the form of a stack of superposed drawers, each of which is withdrawable from the stack.

9. An optical communication system according to any preceding Claim incorporating a plurality of said connection housings provided at spaced intervals along the length of the cable.

10. For use in a connection system according to any preceding Claim a connection housing having an inlet and outlet for an optical fibre cable means for accommodating an excess length of the cable, an access port for one or more spur cables, and a plurality of trays for accommodating excess lengths of optical fibres.

11. For use in a communication system a connection housing substantially as shown in and as hereinbefore described with reference to Figure 1 or Figures 2 to 4 of the accompanying drawings.