The invention relates to a supply rail for supplying current phases of a low-voltage network to a busbar system or for tapping current phases from a busbar system.
In conventional busbar systems, terminals have mostly been used up to now for supplying current phases of a low-voltage network to the busbar system. This is disadvantageous firstly in that connecting the low-voltage network to the busbar system requires a relatively high amount of assembly work and incorrect connections can also occur. In addition, using conventional terminals does not provide reliable protection against accidental contact, and so extra contact-prevention measures have to be taken.
The object of the present invention is therefore to provide a supply rail for supplying current phases of a low-voltage network to a busbar system, by which the electrical connection between the low-voltage network and the busbar system can be established in a simple and safe manner.
This object is achieved according to the invention by a supply rail having the features set out in claim 1.
Accordingly, the invention provides a supply rail for supplying current phases of a low-voltage network to a busbar system or for tapping current phases from the busbar system, comprising an elongate main body that can be mounted transversely on a plurality of busbars arranged in parallel and incudes contact bars that contact the busbars when the supply rail is mounted in order to supply or to tap the current phases carried on the busbars, wherein each contact bar is directly connected to an associated terminal bus, each of which comprises a terminal at an end face of the elongate main body for electrically connecting to the low-voltage network.
Alternatively, the contact bars can also be connected to the busbars by means of an intermediate contact piece, such as a comb contact.
The supply rail is advantageous in that the power loss occurring thereon owing to the direct connection between the busbar system and the low-voltage network is low.
In one possible embodiment of the supply rail according to the invention, each contact bar is connected to an associated terminal bus by means of a corresponding connector plate.
In one possible embodiment of the supply rail according to the invention, the contact bars, the terminal buses and, if provided, the connector plates are covered by contact guard covers.
This has the advantage that users cannot touch the voltage-carrying or current-carrying bars, increasing safety for users.
In another possible embodiment of the supply rail according to the invention, the contact guard covers are formed by a plastics part.
This simplifies or speeds up replacement of the contact guard covers.
In an alternative embodiment of the supply rail according to the invention, the contact guard covers are formed by a plurality of separate plastics parts.
This embodiment is advantageous in that users can separately inspect the supply rail regions intended for the various current phases by removing the relevant contact guard cover.
In another possible embodiment of the supply rail according to the invention, the elongate main body of the supply rail comprises releasable connecting elements for mechanically connecting the contact guard covers to the elongate main body.
In another possible embodiment of the supply rail according to the invention, the connector plates each comprise an opening in the centre thereof for mounting the supply rail on the busbar system.
This provides the advantage of being able to mount the supply rail on the busbar system in a particularly simple manner since the screws and nuts for establishing the contact can be accessed using a tool.
In another possible embodiment of the supply rail according to the invention, the contact bars, the terminal buses and the connector plates consist of a conductive material having low electrical power loss.
In another possible embodiment of the supply rail according to the invention, the terminals for the low-voltage network that are located on the end face of the elongate main body each comprise terminal lugs.
In another possible embodiment of the supply rail according to the invention, the elongate main body of the supply rail is shaped such that it comprises separate receiving channels, which extend in the longitudinal direction, for the terminal buses, inserted into the main body, for the various current phases.
In one possible embodiment of the supply rail according to the invention, said rail comprises three contact bars for three current phases of the busbar system, which bars are connected to three associated terminal buses either directly or by means of three connector plates.
In another possible embodiment of the supply rail according to the invention, the supply rail can be mounted transversely on the busbars arranged in parallel, wherein the end face of the elongate main body that has the terminal buses for electrically connecting to the low-voltage network points downwards.
In an alternative embodiment of the supply rail according to the invention, the supply rail can be mounted transversely on the busbars arranged in parallel, wherein the end face of the elongate main body that has the terminals for electrically connecting to the low-voltage network points upwards in a manner rotated by 180°.
In another possible embodiment of the supply rail according to the invention, the terminals for electrically connecting to the low-voltage network each comprise at least one option for fastening cable shoes, in particular stay bolts or nuts.
In another possible embodiment of the supply rail according to the invention, the terminal lugs of the terminals each comprise a clamp for electrically connecting to a round conductor or a segmental conductor, or a clamp for electrically connecting to a flat conductor.
In another possible embodiment of the supply rail according to the invention, the electrical current supplied via the supply rail has a high nominal amperage of more than 1000 A.
In another possible embodiment of the supply rail according to the invention, the elongate main body of the supply rail consists of an electrically insulating plastics part.
In another possible embodiment of the supply rail according to the invention, the contact bars comprise holes or semi-circular or slot-like notches for fastening to the associated busbar of the busbar system.
In another possible embodiment of the supply rail according to the invention, a support bracket for supporting a contact guard cover plate of a switch cabinet is attached to or integrated in one or both end faces of the elongate main body of the supply rail. This bracket can also be attached to or integrated in the side or on the contact guard covers.
In the following, possible embodiments of the supply rail according to the invention will be explained in more detail with reference to the accompanying drawings, in which:
The supply rail 1 shown in perspective in
In the embodiment shown in
Alternatively, the contact guard covers can also be designed such that they form a bearing surface or bearing edge for the cover system of the associated switch cabinet.
In an alternative variant, there is a direct connection between the contact bars 5-i and the terminal buses 11-i. This variant is shown in
The terminal buses or output buses used within the main body 2 of the supply rail 1 can consist of a plurality of interconnected parts. It is thus also possible to bend the terminal buses or output buses out of a metal part. The supply rail 1 according to the invention can also be used as an output rail for tapping current phases from the busbar system.
In one possible embodiment of the supply rail according to the invention, it comprises terminals 4-1, 4-2, 4-3 in the form of terminal lugs, as shown in
As shown in
The supply rail 1 according to the invention can be mounted transversely on the busbars arranged in parallel. In a possible mounting variant, the end face of the elongate main body 2 that has the connections for electrically connecting to the low-voltage network can point downwards. Alternatively, the supply rail can also be mounted on the parallel busbars in a manner rotated by 180°, wherein in this mounting variant the end face that has the connections for electrically connecting to the low-voltage network points upwards.
The main body 2 of the supply rail 1 preferably consists of a light, fire-resistant and electrically insulating plastics material. The elongate main body 2 of the supply rail 1 is preferably shaped such that it comprises separate receiving channels, which extend in the longitudinal direction, for the terminal buses 11-i, inserted in the main body, for the various current phases L. The contact bars 5-i, connector plates 10-i and terminal buses 11-i preferably consist of an electrically conductive metal having low power loss, for example copper. In a possible variant, an electrical converter can also be mounted over the contact bars. In one possible embodiment, a plurality of separate supply rails 1 can be coupled together to increase the supply current. The busbars can be tapped by means of a clamping contact or a screw contact. The busbars can be contacted by the contact bars 5-i directly, as shown in
Number | Date | Country | Kind |
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14179581.5 | Aug 2014 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/067631 | 7/31/2015 | WO | 00 |