DE9202363U1 - Component for fiber optic cable - Google Patents

Description

Description

The invention relates to a component for connecting and branching off fiber optic cables with holding elements arranged in a generally waterproof sheath for the fiber optic wires to be connected and at least two cable inlets.

So-called clamp sleeves are already known for connecting and branching off fiber optic cables that are to be laid underground and serve as light guides for transmitting messages and data in telecommunications technology. The disadvantage here is the large number of individual parts that have to be assembled, which requires a correspondingly high level of assembly work. In addition, special drilling and clamping tools are required, for example, to create the cable entries in the front sealing caps of the sleeves or to close the longitudinally slotted sleeve body. A further disadvantage is the large number of seals on the sleeve that have to be created using a sealing compound and sealing tapes, which always represent an uncertainty factor with regard to the protection of the fiber optics against the ingress of moisture. The assembly of the sleeves is made even more difficult by the fact that the work has to be carried out in an assembly pit in the ground and the splicing of the fiber optics often has to be carried out in the pit due to the small supply of wires in the sleeve. It should be noted that the splicing devices, which are associated with high acquisition costs, are extremely sensitive to moisture and will be destroyed if they come into direct contact with water. Opening and re-closing the sleeve is just as time-consuming as closing it, for example if additional connections and branches of fiber optic cables are to be created. Closing and re-opening is also

This is necessary if the installation work cannot be completed in one day, so that the sleeve must be closed at the end of the working day in order to protect the glass fibres against moisture in the meantime. It must then be opened again on the next working day and closed again after the installation has been completed.

On this basis, the invention is based on the object of further developing a component of the type mentioned at the outset in such a way that, with a simple and robust construction, convenient and easy assembly and also easy opening and reclosing are possible and reliable protection against the penetration of moisture into the component is guaranteed.

To achieve the object, according to the invention, a two-part housing body is provided which accommodates the holding elements and has the cable inlets, with upper and lower parts which can be connected to one another in a sealing manner and which can be separated from one another by means of compressed air.

The invention enables the component to be opened and closed quickly. After the cables to be connected have been inserted through the cable inlets and the connection between the individual fibers has been established, all that remains is to place the upper part on the lower part, whereby the wires and glass fibers contained in the component are reliably protected against the ingress of moisture. Opening the component is also particularly easy, as the housing body is pressurized with compressed air, so that the upper part detaches from the lower part due to the internal pressure building up in the component and can be easily removed. Another advantage of the component according to the invention, which is primarily due to its design, is the

The considerable supply of wires that can be accommodated in the housing body means that the preparation of the wires to be connected and the subsequent splicing no longer has to be carried out in or on the assembly pit, but can be carried out in the assembly vehicle carried by the fitter, protected from wind and weather and above all from rain. The component according to the invention can be used to advantage not only for installation in the ground, but also for mast installation for overhead cables. Here too, the preparation and splicing of the wires can be carried out in the assembly vehicle due to the supply of wires that can be accommodated in the component.

According to a first special embodiment of the invention, the housing body with upper and lower parts has a cylindrical cross-section, which makes it significantly easier to seal the two housing parts against each other from a constructional point of view. The cylindrical shape of the component also enables the supply of wires to be laid easily without the risk of kinking or the cable bending below the smallest permissible radius .

According to one embodiment of the invention, the upper and lower parts are sealed against each other by means of a sealing element. In the case of a cylindrical housing cross-section, the sealing element is designed as a ring seal so that the cables housed within the component are safely and reliably protected against the ingress of moisture using simple and proven design elements.

Advantageously, the upper part can be clipped or pushed onto the lower part, which makes handling during assembly even easier.

Particularly favorable in terms of construction and assembly technology

This is done when, when the housing body is in the closed position, the upper part with its peripheral wall at least partially encloses the peripheral wall of the lower part. This prevents damage to the wire supply laid in the lower part or, if applicable, to the holding elements in the area of the bundle inlets when the upper part is pushed or pushed onto the lower part.

Assembly is also made easier if the upper and lower sections rest against each other in the closed position, so that the fitter can immediately see when the two housing parts are in the closed position.

According to the invention , it can be provided that at least the upper part is supported with the front side of its peripheral wall in the closed position on an outer extension of the bottom wall of the lower part, possibly in a sealing manner. The seal acting between the extension of the lower part and the peripheral wall of the upper part forms additional protection to prevent moisture from penetrating into the interior of the component.

In one embodiment of the invention, the sealing element is held on the peripheral wall of the upper or lower part. This also makes it easier to assemble the component, since the fitter can grasp the upper part with both hands when closing it and place or push it onto the lower part without having to hold the sealing element.

In a further embodiment of the invention, the sealing element has a leg with an inclined sealing surface that enters the sliding and sealing position with the respective peripheral wall. By forming a leg with an inclined sealing surface,

ensures that the sealing element does not become jammed or displaced relative to the peripheral wall to which it is held when sliding along it, as could possibly occur with a round seal.

From a structural point of view, it is particularly advantageous if the sealing element is held in a bulge in the peripheral wall of the upper part, so that the upper part can be designed with a wall thickness of the same size to save weight and material.

The upper and/or lower parts are provided with a connection, preferably for an air pump, for the compressed air to open the component. To remove the upper part from the lower part, all that is required is to connect an air pump that can be operated by foot or hand. The excess pressure in the component causes the upper part to lift off the lower part and the fitter can remove it without any effort. The excess pressure in the component generated by an air pump that can only be operated by muscle power is completely sufficient, so that the fitter does not have to carry any additional units that require external energy.

Advantageously, the connection is protected on the bottom wall of the lower part .

According to one embodiment of the invention, the connection of the air hose of the air pump is particularly easy if the connection has a coupling piece that protrudes laterally from the lower part and can preferably be closed with a protective cap. The use of a protective cap is recommended above all as protection against contamination and against the penetration of moisture into the component.

In order to facilitate closing the component, the upper and/or lower part can be provided with a preferably closable ventilation opening for discharging the air when closing the housing body.

From a design point of view, it is particularly advantageous if the connection for the compressed air supply also forms the vent opening.

It is also within the scope of the invention that at least one, preferably two cable ducts with cable entries are formed on the outside of the bottom wall of the lower part with openings in the area of the bottom wall. The arrangement of cable ducts with cable entries makes it much easier to insert and lay the cables to be connected. Because the cable ducts run below the bottom wall and the cables are led to the respective holding elements through corresponding openings in the bottom wall , damage to the wires as a result of kinking is ruled out. The cable ducts with cable entries that are already present on the component and are formed as a single piece also significantly reduce the assembly time compared to the known sleeves .

Advantageously, cable clamps are provided in the at least one cable duct to secure the cables that are introduced. This also makes installation much easier compared to the known sleeves , since the cable clamps are already integrated into the cable ducts and do not have to be installed separately and then secured to the sleeve using a perforated strip, for example .

It is particularly advantageous if the cable entries are designed to accommodate a shrink tube and, if necessary, a

The cable entries therefore do not have to be manufactured separately, and the entry sockets with shrink tubing enable simple and secure sealing in the area of the cable entry. The plugs that can be screwed onto the entry socket ensure reliable protection against moisture penetrating the component at the unused cable entries. If the cable network needs to be expanded at a later date, all that is required is to unscrew the plugs from the entry socket in order to insert another cable into the component and to seal the cable entry area against moisture using a shrink tubing on the entry socket.

The component according to the invention also makes it possible for the holding elements for connecting the glass fibers to be detachably held on the bottom wall of the lower part in at least two stacks, preferably arranged side by side with a lateral distance. The component according to the invention is thus characterized by a high holding capacity, whereby a capacity of over 400 fibers can be easily achieved for component diameters of around 50 to 60 cm. The arrangement of the stacked holding elements with a lateral distance next to one another enables an orderly cable laying within the component that is also easy to follow for any other fitter.

According to a proposal of the invention, a particularly favorable utilization of the space available within the component can be realized in that each stack of holding elements is assigned at least one cable duct running approximately in the middle of the respective stack and approximately parallel to the bundle introduction of the holding elements.

According to a special concept of the invention, it is provided that guide devices are provided which are offset inwards from the peripheral wall of the lower part and which form a circumferential holder for a supply of wires between themselves and the inside of the peripheral wall of the lower part. The supply of wires can thus be laid in a protected manner within the holder. Another significant advantage is the large supply of wires resulting from the holder according to the invention, which enables the wires to be assembled and spliced in the assembly vehicle. For example, with a component diameter of around 50 cm, wire lengths of up to 8 m can be achieved.

According to the invention, the guide devices can be designed as webs adapted to the shape of the peripheral wall, formed on the bottom wall of the lower part and extending upwards , which possibly simultaneously form a support for the stack with the holding elements .

Due to the inventive design of the component, it is now also possible to provide an inactive transmitter for locating the component in the ground inside the housing body, preferably on the cover of the upper part.

In some circumstances, it may be advisable to hold the upper and lower parts together using tensioning straps to ensure a particularly strong connection between the two-part component.

For manufacturing reasons as well as for reasons of strength and weight, it is recommended according to the invention that the upper and lower parts are made of plastic, e.g. polyamide.

Further objects, advantages, features and applications of the present invention will become apparent

from the following description of an embodiment based on the drawing. All described and/or illustrated features form the subject matter of the present invention, either individually or in any meaningful combination, regardless of their summary in the claims or their reference back to them.

Show it:

Figure 1 is a sectional view of a possible embodiment of a component according to the invention for connecting and branching fiber optic cables,

Figure 2 shows the component according to Figure 1 with the upper part removed in a top view and

Figure 3 is a side view of the component according to Figure 1, partially sectioned, with an air pump connected to open the component.

The component for connecting and branching fiber optic cables has a housing body with a cylindrical cross-section with a lower part 5 and an upper part 4 that can be pushed onto it. In the pushed-on position, the upper part 4 encloses the lower part 5 with its peripheral wall 7, with the front side of the peripheral wall 7 being supported on a radial extension 9 of the bottom wall 10 of the lower part 5.

The upper part 4 and the lower part 5 are sealed against each other on their peripheral walls 7, 8 by means of an annular seal 6 in order to prevent moisture from penetrating into the interior of the housing body. The annular seal 6 is located in a recess 12 of the

peripheral wall 7 of the upper part 4. As can be seen in particular from Figure 1, the ring seal 6 has a leg that comes into sealing position with the outside of the peripheral wall 8 of the lower part 5.

11 with a slanted sealing surface. This shape of the sealing ring 6 is intended to ensure that when the upper part 4 is pushed onto the lower part 5, the sealing element 6 does not tilt and remains in the bulge

12 of the peripheral wall 7 remains.

Two cable ducts 17 with cable inlets 21 are formed on the underside of the base wall 10 of the lower part 5 and are arranged laterally spaced from one another. Cable clamps 19 in the form of clamps are integrated into the cable ducts 17 and are used to secure the cables 1 introduced through the cable inlets 21. The cable inlets 3 are designed as inlet nozzles formed onto the cable ducts 17 or, if necessary, screwed into them , into which the fiber optic cables 1 coming from outside are introduced . A shrink tube 28 is slipped over the jacket of the fiber optic cable 1 and the inlet nozzle 21 , which is then heated and thus seals the connection and at the same time mechanically secures it. If the respective cable inlet 21 is unoccupied, a plug 20 is screwed onto the inlet nozzle 21, which also ensures that no moisture can penetrate into the interior of the component.

In the lower part 5, there are several holding elements 2 for connecting the respective wires 3, laid one above the other in two stacks 22. The holding elements 2 are fixed by means of a stud bolt 30 anchored to the base wall 10, onto which the plate-shaped holding elements 2 are placed one after the other after the corresponding wires 3 have been spliced. A cover plate 31 is then placed on the respective stack 22 and

the stack 22 is screwed tight with a knurled nut 29.

As can be seen from Figures 1 and 2, radially inwardly offset and upwardly extending webs 23 are formed on the base wall 10, which form a circumferential receptacle for a wire supply 24 between themselves and the inside of the peripheral wall 8 of the lower part 5. The wires 3 can be laid in the receptacle in several layers. With component diameters of 50 to 60 cm, cable lengths of approx. 8 m can be easily achieved, which allows the preparatory work and splicing of the fibers to be carried out not in the assembly pit, but in the assembly vehicle, protected from wind and weather.

As can be seen from Figure 3, the upper and lower parts 4, 5 can be additionally secured in the closed position by means of a tensioning strap 27 .

The component is opened by applying compressed air to the interior , in that a connection 13 is provided on the bottom wall 10 of the lower part 5 with a coupling piece 16 which projects outwards at the side and can be closed with a protective cap 15, to which the connection piece of an air pump 14 which can be operated with the foot can be connected. When the air pump 14 is operated, an excess pressure is created inside the component, whereby the upper part 4 with its peripheral wall 7 slides upwards on the peripheral wall 8 of the lower part 5 so that the fitter can remove the upper part 4 without great effort and thus access the interior of the component. The component is closed in the same simple way by simply pushing the egg-shaped upper part 4 onto the lower part 5. The connection 13 simultaneously forms the ventilation opening for the air to escape when the housing body is closed.

The design of the component now also allows for the provision of an inactive transmitter 26 for locating the housing body in the ground, which is arranged on the inside of the cover 25 of the upper part 4.

The upper part 4 and the lower part 5 with molded cable ducts 17, cable supports 19, and webs 23 are preferably made of polyamide as a robust plastic material.

List of reference symbols

1 Fiber optic cable 2 Holding element 3 Fiber optic core 4 - Top 5 Bottom part 6 Sealing element, sealing ring 7 Perimeter wall 8th Perimeter wall 9 Extension 10 Floor wall 11 leg 12 bulge 13 Connection 14 Air pump 15 protective cap 16 Coupling piece 17 Cabel Canal 18 Breakthrough 19 Cable clamp 20 Plug 21 Cable entry, entry nozzle 22 stack 23 Guide systems, footbridges 24 Wire stock 25 Lid 26 Channel 27 Tension strap 28 Shrink tubing 29 Knurled nut 30 Stud bolts 31 Cover plate

Claims (25)

Protection claims 1. Component for connecting and branching off fiber optic cables (1) with holding elements (2) arranged in a generally watertight sheath for the fiber optic wires (3) to be connected and at least two cable inlets (21), characterized by a two-part housing body receiving the holding elements (2) and having the cable inlets (21) with upper and lower parts (4, 5) that can be connected to one another in a sealing manner and can be detached from one another by means of compressed air. 2. Component according to claim 1, characterized in that the housing body with upper and lower parts (4, 5) has a cylindrical cross-section. 3. Component according to claim 1 or 2, characterized in that the upper and lower parts (4, 5) are sealed against one another by means of a sealing element (6). 4· Component according to one of claims 1 to 3, characterized in that the upper part (4) can be plugged or pushed onto the lower part (5). 5. Component according to one of claims 1 to 4, characterized in that in the closed position of the housing body, the upper part (4) with its peripheral wall (7) at least partially encloses the peripheral wall (8) of the lower part (5). 6. Component according to one of claims 1 to 5, characterized in that the upper part (4) and lower part (5) support each other in the closed position. 7. Component according to one of claims 1 to 6, characterized characterized in that at least the upper part (4) is supported with the front side of its peripheral wall (7) in the closed position on an outer extension (9) of the bottom wall (10) of the lower part (5), possibly in a sealing manner. 8. Component according to one of claims 1 to 7, characterized in that the sealing element (6) is held on the peripheral wall (7, 8) of the upper or lower part (4, 5). 9. Component according to one of claims 1 to 8, characterized in that the sealing element (6) has a leg (11) with an oblique sealing surface which comes into sliding and sealing position with the respective peripheral wall (7, 8) . 10. Component according to one of claims 1 to 9, characterized in that the sealing element (6) is held in a bulge (12) of the peripheral wall (7) of the upper part (4). 11. Component according to one of claims 1 to 10, characterized in that the upper and/or lower part (4, 5) are provided with a connection (13) for the supply of compressed air, preferably for an air pump (14) . 12. Component according to one of claims 1 to 11, characterized in that the connection (13) is formed on the bottom wall (10) of the lower part (5). 13. Component according to one of claims 1 to 12, characterized in that the connection (13) has a coupling piece (16) which projects laterally outwards relative to the lower part (5) and can preferably be closed with a protective cap (15). 14. Component according to one of claims 1 to 13, characterized in that the upper and/or lower part (4, 5) are provided with a preferably closable ventilation opening for air discharge when the housing body is closed. 15. Component according to one of claims 1 to 14, characterized in that the connection (13) for the air supply simultaneously forms the ventilation opening. 16. Component according to one of claims 1 to 15, characterized in that on the outside of the bottom wall (10) of the lower part (5) at least one, preferably two cable ducts (17) with cable inlets (21) are formed with openings (18) in the region of the bottom wall (10). 17. Component according to one of claims 1 to 16, characterized in that in the at least one cable duct (17) cable supports (19) are provided for securing the introduced cables (1). 18. Component according to one of claims 1 to 17, characterized in that the cable inlets (21) are designed as inlet nozzles (21) which can be closed by means of a screw-on plug (20) to accommodate a shrink tube and if necessary. 19. Component according to one of claims 1 to 18, characterized in that the holding elements (2) for connecting the glass fiber strands (3) are detachably held on the bottom wall (10) of the lower part (5) in at least two stacks (22) arranged next to one another, preferably with a lateral spacing. 20. Component according to one of claims 1 to 19, characterized in that each stack (22) with holding elements (2) is assigned at least one cable duct (17) running essentially in the middle of the respective stack (22) and approximately parallel to the bundle inlets of the holding elements (2). 21. Component according to one of claims 1 to 20, characterized in that guide devices (23) offset inwards relative to the peripheral wall (8) of the lower part (5) are provided, which form a circumferential receptacle for a wire supply (24) between themselves and the inside of the peripheral wall (8) of the lower part (5). 22. Component according to one of claims 1 to 21, characterized in that the guide devices are designed as webs (23) adapted to the shape of the peripheral wall (8), formed on the bottom wall (10) of the lower part (5) and extending upwards, which optionally simultaneously form a support for the respective stack (22) with the holding elements (2). 23. Component according to one of the preceding claims, characterized in that an inactive transmitter (26) for locating the component is provided in the interior of the housing body, preferably on the cover (25) of the upper part (4). 24. Component according to one of the preceding claims, characterized in that the upper and lower parts (4, 5) are held together by means of tensioning straps (27). 25. Component according to one of the preceding claims, characterized in that the upper and lower parts (4, 5) are made of plastic, for example polyamide.