DE4140701C1 - Buried container e.g. for fibre=optic cable junction - is partially held in shaft and has removable lid and lifting arrangement to allow easy working access e.g. for further splicing - Google Patents

Abstract

An underground container (1) has a withdrawable holder (8,11,13) in which components (9) are mounted. The holder has a removable cover (4). It is partly buried in a shaft and is accessible without further excavation when the shaft lid (3) is removed. The components mounted in the container can be pulled out by the holder perpendicularly upwards on a pull-out device (10). The cables and leads (6,7) of the components are wound spirally on the base of the holder and unwind as the components are withdrawn. ADVANTAGE - Inexpensive device enabling components buried underground to be easily accessible.

Description

So far, splice cassettes have been used in fiber optic networks Sleeves mounted in the ground or in a shaft were set. When laying in the ground, change work a correspondingly large earth in the splice cassettes be dug out to get to the sleeve and on of being able to work. This means high costs. The he direction of accessible shafts or rooms becomes more expensive Optical fiber network considerably. It is thought of instead the splice cassettes, for example opto-electronic Transducer in sleeves or a suitable underfloor container to accommodate.

The object of the invention is to provide an easily accessible sub to indicate corridor containers, the laying of which low costs causes.

Underfloor containers to solve this task are in the unab pending claims.

Advantageous developments of the invention are in the dependent claims Chen described.

It is advantageous to accommodate the connection cable or bundle veins in the lower part of the underfloor container. This can the bracket above it is removed upwards the to outside the underfloor tank - and if necessary the hole in the ground - to be able to work on the modules. Especially it is advantageous if the holder with the modules attached to an extractable pull-out is. The bracket with the modules is in a suitable Lockable working height, making assembly work essential be relieved.  

If electronic components are present in the underfloor container are, it is advantageous to use the heat loss a metal thermal bridge in the underfloor tank or too at least remove the base plate. An earth anchor can do this improve heat dissipation.

It is advisable to protect the underfloor container in a shaft with a mounting ring. The mounting ring also serves to hold the manhole cover. Due to its removal, quick access to the underfloor container and thus to the modules is possible at any time. An embodiment of the inven tion will be described with reference to FIGS . 1 to 7.

Show it:

Fig. 1 is a sectional view of a buried underfloor container,

Fig. 2 shows the underfloor container with pulled-out holder,

Fig. 3 is an underfloor container with a Abführmöglichkeit for heat losses,

Fig. 4 shows a first variant of the underfloor container,

Fig. 5 shows a second variant of the underfloor container,

Fig. 6 shows a second way of arranging splice cassettes and

Fig. 7 shows another way of arranging the splice cassettes.

In Fig. 1 a buried in the ground underfloor container 1 is shown, which is sealed at the top by a cover 4 . The upper part of the underfloor container 1 is located in a receiving ring 2 , which in turn is closed off at the ground level by a manhole cover 3 . By removing it, access to the underfloor container is possible at any time. The incoming and outgoing cables (copper and fiber optic cables) are routed through sealed cable entry sockets 5 . Their bundles of cores 6 (or copper strands) - with flexible cables also the cable ends themselves - are circular and torsion-free inserted in the lower part of the underfloor container. Their ends are guided on the bracket 8 . Here they are fixed by a strain relief and then passed on to the individual assemblies 9 , shown here as splice cassettes, if necessary as a single wire.

In Fig. 2 the manhole cover has been removed and the holder 8 has been pulled out vertically upwards from the underfloor container by means of a pull-out device 10 . Now a simple access to the individual modules 9 is possible. A distributor insert according to the published patent application DE-OS 41 06 170.5 can be used as a holder.

When the holder is pulled out to above the surface of the earth, the stored loose tubes 6 move upward in a spiral (like the cord of a telephone receiver). Due to the permanent deformation, the loose tubes lay helically and torsion-free on the bottom of the underfloor container when the holder 8 slides into the underfloor container.

In Fig. 3, a suitable for receiving active components ned underfloor container is shown. Its holder 20 stands on a thermal bridge 15 which emits the heat into the base plate 18 or through it into an earth anchor 16 made of a material which is a good conductor of heat. The ground anchor in connection with the thermal anchor is particularly necessary if plastic is selected as the material for the underfloor container. The ground anchor also serves as electrical grounding. With stronger Mon day plates 14 of the bracket, the thermal conductivity is improved ver.

In FIG. 3, further details are still visible in the execution of the underground tank. So the seal is made when mounting the cover 4 preferably by a Profildich device 17 made of rubber. The cover 4 and the base plate 18 are fastened to the circumference by screw connections 19 . In a plastic underfloor container, perforated washers made of sheet metal are placed under the screw connection.

In order to facilitate installation, through-flanges 12 are used, through which cables 7 are guided. Sealing and strain relief take place simultaneously in the feed-through flanges. In Fig. 3, the details of the bushing flanges have been omitted. They are then screwed to the flanges of the cable entry sockets.

The loose tubes 6 (or copper cores) are placed helically and torsion-free in this embodiment from the holder 20 with the assemblies 9 mounted thereon, in order then to be supplied to the assemblies. It must be taken into account here that the diameter of the helically inserted wires is slightly reduced when pulled out.

In Fig. 4 an underfloor container is shown, in which the cable entry 5 are arranged in the center. Make sure that the minimum bending radius of the loose tubes is not exceeded.

In Fig. 5, an underfloor container with attached to the circumference th cable entry 5 is shown. The cable routing is made easier since the connection cables are tan gential into the underfloor container without bending stress.

In Fig. 6 shows a variant 11 is shown of the holder for Spleißkasset th, can be accommodated in the four cartridges in a plane of an H-shaped bracket. Several cassette packages can be arranged one above the other.

FIG. 7 shows a further holder 13 in which the individual cassettes or cassette blocks are arranged in a star shape. With this arrangement, easy access to each splice cassette is possible.

However, these are just a few options from training the underfloor container and the bracket. The underfloor container ter can also be square and thereby accommodate a larger number of splice trays.

Claims (7)

1. underfloor container with removable holder, characterized in
that in its upper part a bracket ( 8 , 11 , 13 ) for construction groups ( 9 ) is removably arranged and
that in its lower part optical fiber connection cable ( 7 ) and / or the loose tubes ( 6 ) are inserted in a circle, the ends of which are guided to the modules ( 9 ). 2. Underfloor container with a pull-out bracket, characterized in that a removable bracket ( 21 ) for assemblies ( 9 ) is provided, which rests on a thermal bridge ( 15 ) of the base plate ( 18 ) and that the connecting cable ( 7 , 22 ) or / and Loose tubes ( 6 ) or cores are placed helically around the holder ( 21 ) and the ends of which are guided to the assemblies ( 9 ). 3. Underfloor container according to claim 1, characterized in
that is designed as a hollow cylinder and
that the connecting cables and / or the loose tubes ( 6 ) enter tangentially. 4. Underfloor container according to claim 1 or 2, characterized in that it has a removable lid ( 4 ) and a seal ( 17 ). 5. Underfloor container according to claim 3, characterized in that the holder ( 8 , 11 , 13 , 20 ) on a pull-out device ( 10 ) is fastened to be pulled out upwards, and this engages to be height. 6. underfloor container according to one of claims 2 to 5, characterized in that a thermal bridge ( 15 ) is provided via the heat loss from the inside of the underfloor container to the surrounding earth is richly removed. 7. Underfloor container according to one of the preceding claims, characterized in that it is surrounded in the upper part by a receiving ring ( 2 ) which can be closed by a manhole cover ( 3 ).