DE29903813U1 - Cable routing channel - Google Patents

Description

DIPL.-ING. F. W. MOLL · DIPL.-ING. H.CH. BITTER

AUTHORIZED REPRESENTATIVES BEFORE THE EUROPEAN PATENT OFFICE LANDAU/PFALZ

02.03.1999 B/Co.

Tehalit GmbH, 67716 Heltersberg

Cable routing channel

CORRESPONDENCE OFFICE BANK DETAILS

P.O. BOX 20 80 WESTRING 17 DEUTSCHE BANK AG LANDAU

D-76810 LANDALVPFALZ D-76829 LANDAU/PFALZ 02 154 00 (BLZ 546 700 95)

TEL. 0 63 41 / 8 70 00; 2 00 35 POSTBANK LUDWIGSHAFEN

TELEGRAM INVENTION FAX 0 63 41 / 2 03 56 275 62-676 (bank code 545 100 67)

Description:

The invention relates to cable routing channels according to the preamble of claim 1.

Cable routing channels, which can be used to lay pipes, such as heating pipes, and/or electrical cables on the floor, wall and/or ceiling, have been known for over 100 years. Compare, for example, US 378 561 of February 21, 1888. They have been in widespread use ever since.

Cable routing ducts are available in sheet steel, aluminum and plastic. They usually consist of a lower part with a U- or C-shaped cross-section and a detachable cover. The sheet steel ducts are folded or rolled from sheet metal cuts, the aluminum ducts are extruded, the plastic ducts are extruded.

The individual electrical wires, lines or cables are placed in the lower part by the installer and secured by the cover. Creating branches or attaching electrical installation devices such as sockets and switches is done in the traditional way by cutting the cables, lines or wires, stripping the wire ends and creating the electrical and mechanical connection. This takes a considerable amount of time. It is annoying that the cables, lines and wires are laid out completely randomly in the lower part of the duct and are therefore difficult to identify.

In addition to the cable routing channels in which the electrical cables, lines and wires lie loosely, the so-called busbar channels have also been around for a long time. Compare, for example, US 2 675 434. In this type of channel, copper rails are attached to the channel floor. In order to be able to make electrical contacts, special connecting elements are required that are equipped with sliding or pressure contacts.

These busbar channels have several disadvantages and only a few advantages compared to the previously described cable routing channels. The advantage is the possibility to take power from any point on the copper bars and to release the contacts again.

The disadvantage is that the cross-section of the copper rails must be designed for the largest possible current strength, which means that the amount of copper is very high. Furthermore, copper has a relatively high coefficient of thermal expansion, so that compensators must be inserted at regular intervals to prevent deformation of the channels. Furthermore, the special contact elements are complex and expensive. The copper rails are not insulated on all sides. No other cables, for example for telecommunications connections, can be inserted into busbar channels. Busbar channels therefore only have a relatively small market share.

The present invention is based on the object of specifying a cable routing duct which combines the advantages of both duct types.

This object is achieved by a cable guide channel having the features of claim 1.

The present invention is based on the principle of using neither cables nor lines, but only insulated individual wires, which are then attached to the bottom of the duct in appropriately pre-formed longitudinal grooves. Insulated individual wires are inexpensive, commercially available for many current strengths and are easy to lay. Simple insulation displacement terminals, which have long been used in electrical engineering, are used to create electrical contacts.

The cable routing duct according to the invention also has the advantage that the electrical conductors are insulated on all sides, so that optimum safety is ensured, that additional electrical cables and lines can be inserted, that partitions can be installed which divide the interior of the duct into two or more compartments, and that the insulated individual wires can be individually selected according to the expected power requirement.

According to an advantageous development of the invention, the channel floor has holding openings that correspond to the insulation displacement terminals. The main task of these openings is to create enough space so that the insulation displacement terminals can be pressed in deep enough.

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If the holding openings on the one hand and the insulation displacement terminals on the other hand are designed appropriately, the insulation displacement terminals are fixed in the channel. In this way, the insulation displacement terminals also ensure that the insulated individual wires are held firmly in the channel.

According to a further embodiment of the invention, the channel base has molded-in retaining grooves that correspond to the insulation displacement clamps. These retaining grooves have the same functions as the retaining openings just described. Their advantage, however, is that they can be manufactured using an extrusion process, for example.

According to a preferred embodiment of the invention, the insulation displacement terminals have an insulating housing which corresponds to the holding openings or the holding grooves in the channel floor.

According to a further development of the invention, wire clamps are provided which fix the individual wires in the longitudinal grooves. According to a further development of the invention, the wire clamps correspond to the holding openings or the holding grooves in the channel floor.

According to a further development of the invention, at least one partition wall is provided, similar to the partition walls in the conventional cable routing channels. According to the invention, these partition walls are also provided with longitudinal grooves, holding openings and/or holding grooves for fastening insulated individual wires.

According to a preferred embodiment of the invention, the longitudinal grooves are part of an assembly unit which essentially comprises a base and a hinged lid with openings for the insulation displacement terminals and a snap closure.

The assembly of the individual wires can be simplified if they are combined into a web cable.

The invention will be explained in the form of two embodiments using the drawings. They each show purely schematically

Fig. 1 shows a cross section through a first cable guide channel,

Fig. 2 is a plan view of the cable duct of Fig. 1,

Fig. 3 a cross section through a second cable routing channel,

Fig. 4 is a plan view of the cable duct of Fig. 3,

Fig. 5 shows a perspective view of a cable duct with inserted web cable and

Fig. 6 a cross-section through a cable duct with inserted web cable and socket.

Fig. 1 and 2 show a first embodiment of a cable guide channel with insulated individual wires. A channel lower part with a C-shaped cross-section is shown, comprising a base 1 and two side walls 2. On the inside of the base 1, molded-in longitudinal grooves 3 can be seen, into which insulated individual wires 10, 11 are inserted. In the area of the longitudinal grooves 3, holding openings 5 are made at regular intervals in the channel base 1, for example by cutting, milling or punching. The production of such openings is a proven technique in the production of conventional cable guide channels.

Insulation clamps 20 are provided to create electrical contacts between the insulated individual wires 10, 11 laid in the channel floor 1 and branch lines 22, comprising an insulating housing 23 in which a conventional cutting contact 21 is housed. The insulation clamps 20 are pressed onto the insulated individual wires 10, 11 in the area of the holding openings 5, the cutting contacts 21 cutting through the insulation 11 and contacting the wire 10. The insulating housings 23 are provided with hooks that spread out on the back of the holding openings 5 so that the insulation clamps 20 are fixed in the holding openings 5.

In places where no electrical contacts are required, clamps 30 are used to fix the insulated individual wires 10, 11 in the longitudinal grooves 3.

Since in the present embodiment the holding openings 5 completely penetrate the duct floor 1, longitudinal ribs 4 are formed on the back of the duct floor 1, which create the required distance from the structure to which the cable routing duct is to be attached.

Fig. 3 and 4 show a second embodiment of a cable guide channel with insulated individual wires. Here too, the longitudinal grooves 3, which accommodate the insulated individual wires 10, 11, are formed in the inside of the channel base 1. In addition to the longitudinal grooves 3, retaining grooves 6 are formed, which correspond to the wire clamps 31 and the insulation displacement terminals 20 or the barbs on their insulating housing 23.

In this embodiment, openings 7 are again provided in the region of the longitudinal grooves 3, which, however, do not penetrate the channel bottom 1, but are only deep enough so that the cutting contacts 21 of the insulation displacement terminals 20 can be pressed deep enough into the insulated individual wires 10, 11.

Fig. 5 shows a perspective view of another cable guide channel 1, 2, in the base of which a complete assembly unit 40 is integrated. The assembly unit 40 comprises a base 41 with a series of grooves and a hinged lid 42, which is hinged by means of a film hinge 46 and can be closed by means of a closure 44, 45. A so-called web cable 12 can be seen inserted into the assembly unit 40. Slots 43 are incorporated at regular intervals in the hinged lid 42, through which the insulation displacement terminals for contacting the wires 10 of the web cable 12 can be inserted.

Fig. 6 shows a cross section through a third cable routing duct in which a socket 50 is installed as an example of an electrical installation device. The open front of the duct base is releasably closed by a cover 8.

The mounting unit 40 with the web cable 12 is integrated into the duct rear wall 1. Insulation clamps 21 establish the contact from the terminating cables 13 leading to the socket 50 to the web cable 12.

Claims (10)

1. Cable duct with an approximately U- or C-shaped cross-section, characterized by the following features: - longitudinal grooves ( 4 ) are formed in the inner sides of the base ( 1 ) and/or side walls ( 2 ), - insulated individual wires ( 10 , 11 ) are located in the longitudinal grooves ( 4 ), - Insulation displacement terminals ( 20 ) contact the individual wires ( 10 ). 2. Cable guide channel according to claim 1, characterized by the features: - bottom ( 1 ) and/or side walls ( 2 ) have openings ( 5 , 7 ), - the openings ( 5 , 7 ) correspond to the insulation displacement terminals ( 20 ). 3. Cable guide channel according to claim 1 or 2, characterized by the features: - The base ( 1 ) and/or side walls ( 2 ) have molded retaining grooves ( 6 ), - the retaining grooves ( 6 ) correspond with the insulation displacement terminals ( 20 ). 4. Cable guide channel according to claim 2 or 3, characterized by the features: - the insulation displacement terminals ( 20 ) have an insulating housing ( 23 ), - the insulating housing ( 23 ) corresponds to the openings ( 5 , 7 ) or the retaining grooves ( 6 ) in the base ( 1 ) and/or side walls ( 2 ). 5. Cable guide channel according to one of claims 1 to 4, characterized by the feature: - Wire clamps ( 30 , 31 ) fix the individual wires ( 10 , 11 ) in the longitudinal grooves ( 4 ). 6. Cable guide channel according to claim 5, characterized by the feature: - the wire clamps ( 30 , 31 ) correspond to the openings ( 5 , 7 ) or the retaining grooves ( 6 ) in the base ( 1 ) and/or side walls ( 2 ). 7. Cable guide channel according to one of claims 1 to 6, characterized by the features: - at least one partition wall is provided, - longitudinal grooves ( 3 ), openings ( 5 , 7 ) and/or retaining grooves ( 6 ) for fastening insulated individual wires ( 10 , 11 ) are also formed in the partition wall. 8. Cable guide channel according to one of claims 1 to 7, characterized by the features: - the longitudinal grooves ( 3 ) are part of an assembly unit ( 40 ) which essentially comprises - a base ( 41 ) and - a hinged cover ( 42 ) with openings ( 43 ) for the insulation displacement terminals and a snap closure ( 44 , 45 ). 9. Cable guide channel according to claim 8, characterized by the feature: - the individual wires ( 10 ) are combined to form a web cable ( 12 ).