DE29811018U1 - Contact arrangement for an electrical control cabinet - Google Patents

Description

PALGEN, SCHUMACHER & KLÜIN : * : ::'*: · *·*· :*\·

¹ UUSS-EL-B ORF ESSEN

PATENT ATTORNEYS

OUR SIGN: 98 426 R/JC ESSEN, 17 June 1998

AEG high-voltage systems Magdeburg GmbH Walmbergsweg 9

D - 39112 Magdeburg Contact arrangement for an electrical control cabinet

The invention relates to a contact arrangement for an electrical switch cabinet and in particular to a contact arrangement for the current output of a plug-in unit which is arranged in an electrical switch cabinet, as well as to an electrical switch cabinet with such a contact arrangement.

Electrical switch cabinets are used to accommodate switching devices and switching elements, such as contactors, fuse elements or the like, or also display instruments that characterize the operating status of downstream consumers, for example. In this case, this refers in particular to switch cabinets that have plug-in units that include complete switching units and are used to control individual units, for example on a production line. Such switch cabinets are also called "motor control centers", or "MCCs" for short. Generally speaking, connections from switching devices to

D-40239 DÜSSELDORF ■ MULVANYSTRASSE 2 TELEPHONE 49 / 211 / 96 145 - 0 FAX 49 / 211 / 96 145 - 20 D45133 ESSEN FRÜHLINGSTRASSE 43 A TELEPHONE 49 / 201/ 84 230 - 0 ■ FAX 49 /201/84 230 - 20

POSTBANK COLOGNE (bank code 370 100 50) 115 211 - 504

The plug-in unit is connected to other cabinet systems or other consumers.

The MCC switch cabinets usually include a main busbar system with several copper bars, which serve to supply power to all electrical components in a switch cabinet, the so-called "field". The power is distributed to the individual switchgear by means of a distribution bar system, which is usually arranged perpendicular to the main busbar system and which also has a plurality of parallel copper bars arranged at a certain distance from each other, the so-called phase distance. The spatial arrangement of the copper bars in the switch cabinet is adapted to the spatial arrangement of contact means of switchgear inserts, which are usually mounted from the front, so that electrical contact is made automatically when the switchgear insert is inserted without the need for adapters or similar.

For this purpose, the switching devices usually have a plurality of contact means designed as plug contacts on the back, which, after assembly, partially enclose two opposite sides - usually the wide sides - of the respective associated power distribution rail, one of whose narrow sides faces the switching device. The busbars of the power distribution rail system are usually attached to at least two points in the switch cabinet that are spaced apart from one another in the longitudinal direction.

Just like the power supply to the individual switchgear units, the power output is also implemented using appropriately designed contact means. The output contacts are dimensioned depending on the power of the current being discharged and are either cables leading out of the unit for low output powers or

Plug contacts with a counter contact element fixed in the control cabinet are designed for larger power outputs.

In the current state of the art, point contact devices, so-called Lyra contacts, are used for higher output powers. These consist of a flat busbar onto which a contact element is pushed in a bracket-like manner. The flat busbar is usually made of copper and has a thickness of around 5 mm. The thickness of the flat busbar is limited because the flat busbar is bent at 90° in the area where it is held. The limited thickness of the flat busbar material also limits the maximum power dissipated. The contact element has two brackets, each on one side of the flat busbar, which rest against the sides under mechanical tension. The mechanical tension must be sufficient to ensure the point contact required for the current output.

The disadvantage of using the point contact means explained above is the limitation of the maximum current that can be discharged. Therefore, when high currents have to be discharged, it is necessary to use several bracket-like contact elements so that the required power can be transferred to the flat busbar by the several contact elements. This initially results in a higher design effort. Furthermore, the assembly and disassembly force required to insert and remove a plug-in unit that is connected to the control cabinet via the point contact means also increases. This can lead to the plug-in unit being difficult for an operator to handle.

The invention is therefore based on the object of improving the contact arrangement known from the prior art for the current output of a plug-in unit which is used in an electrical switchgear

cabinet is arranged, in such a way that a simpler structure of the contact means and a lower necessary assembly/dismantling force are achieved, while at the same time a current with a higher output power can be discharged.

The above-mentioned object is achieved according to the invention by a contact arrangement with the features of claim 1. According to the invention, it has been recognized that the current output of a plug-in unit within an electrical switch cabinet is established via surface contacts, which results in a number of advantages.

Firstly, the design is simpler, in which only one contact needs to be made between the plug-in element arranged on the back of the module and the current discharge element for each phase of the discharged current, even at high power levels. The design effort is therefore low compared to the state of the art, which requires a number of Lyra contacts.

Another advantage is that, due to the mechanical structure of the contact arrangement, only a small amount of assembly or disassembly force is required to establish or break the contact. This is because, in the case of a surface contact, less pressure is required between the clamping contacts and the side surfaces of the current-dissipating leg of the current-dissipating element than with a point contact. Therefore, despite the increased output power of the discharged current, a lower assembly or disassembly force is achieved with the contact arrangement according to the invention.

Preferably, the current-dissipating leg of the current-dissipating element is designed with a thickness of greater than 5 mm, in particular greater than 10 mm. This ensures that, despite the existing manufacturing tolerances,

zen sufficient electrical contact is created between the plug element and the current discharge element.

Since the thickness of the current-dissipation leg prevents a part of the current-dissipation leg from being bent in order to form an integrated holder, the current-dissipation leg is connected to a busbar. The current-dissipation leg is preferably designed in such a way that at least one contact surface is provided that runs transversely to the longitudinal direction of the current-dissipation leg and that clamping means can be brought into operative connection with the at least one contact surface and connect the current-dissipation leg to the busbar.

Finally, a significant advantage is that with the help of the contact arrangement according to the invention, an outgoing current with a higher power can be discharged from the plug-in unit. This results in possibilities for the design of the circuits inside and underneath electrical switch cabinets that were previously not possible with such simplicity. One of these possibilities is that a switching arrangement is arranged in the plug-in unit, via which the power is fed in for at least one arrangement of further switching devices. The power feed for an entire electrical switch cabinet can even take place via the contact arrangement according to the invention.

In the following, the invention is explained in more detail using an embodiment, with reference to the drawing. In the drawing,

Fig. 1 is a perspective view of a switch cabinet equipped with a plurality of fuse switch disconnectors and plug-in units,

• * I

Fig. 2 is a perspective view of a frame of a control cabinet with a power distribution rail arrangement comprising four busbars and
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Fig. 3 is a perspective view of a contact arrangement according to the invention for the power output of a plug-in unit which is arranged in the electrical switch cabinet shown in Figs. 1 and 2.

The control cabinet shown as an example in Fig. 1 and designated as a whole by 100 serves to accommodate electrical switching elements, fuse elements, display devices, etc., which can have different functions and different dimensions. The control cabinet 100 has the shape of an upright cuboid, the edges of which are formed by a frame 1, which consists of frame profiles 2 formed from sheet metal. In the embodiment shown in Fig. 1, the front side facing the viewer is the assembly side 4, from which access is made to the inserts 3, 5, which are mounted on rails not shown in the drawing and are inserted from the assembly side 4. The assembly side 4 is surrounded by a rectangular frame formed by the frame profiles 2 and represents part of the frame 1. The assembly side 4 of the control cabinet, which is delimited by the frame, is divided into three functional spaces 8, 8', 8'' by a horizontally running dividing profile 6 and a vertical dividing profile 7 adjacent to this from below.

The upper functional space 8 can be used to accommodate a main busbar arrangement comprising a plurality of power supply rails running parallel to one another. However, the control cabinet can be further subdivided in its "depth" as shown in Fig. 2 in order to

according to Fig. 2 in the rear area a functional space 8
to accommodate the main busbar arrangement 9.

The main busbar arrangement serves to supply power to all electrical components in the fully assembled control cabinet, which together form a so-called field.

The functional space 8' shown on the right in Fig. 1 is usually used to accommodate electrical connecting cables that connect the outputs of the switching devices to the associated consumers. The functional space 8' is followed by the functional space 8'', which is used to accommodate the switching devices 3, 5.

In the embodiment shown in Fig. 2, a busbar arrangement 12, which in the embodiment shown has four busbars 13, is provided in the rear area of the functional space 8''. The narrow sides of the busbars 13 face the mounting side 4 of the control cabinet 100. The busbars 13 are fastened by a holding element 11 fastened to a cross profile 10, which consists of an electrically insulating material and holds the busbars 13 at a well-defined distance from one another and fixes them in their longitudinal direction. The inserts 3, 5 are connected to the busbars 13 via a connection contact, so that they are supplied with electrical current via this contact.

In Fig. 3, a contact arrangement 15 according to the invention is shown for the power outlet of a plug-in unit that is arranged in an electrical switch cabinet 100. The contact arrangement 15 has a plug element 16 arranged on the rear of the plug-in unit 3, 5, which has clamping contacts 18 with contact surfaces 17. The contact arrangement 15 also has a power connector 18 fastened in the switch cabinet 100.

discharge element 19 which has a current discharge leg 22 projecting in the direction of the insert 3, 5 and having two side surfaces 20, 21 and a busbar 23 connected to the current discharge leg 22.
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When the insert 3, 5 is inserted, the contact surfaces 17 of the clamping contacts 18 rest on both side surfaces 20, 21 of the current discharge leg 22 and thus form a flat contact between the plug element 16 and the current discharge element 19.

The ends of the clamping contacts 18 protruding in the direction of the current discharge element 19 are each bent outwards in order to form a guide when the plug element 16 and the current discharge element 19 are plugged together.

Two contact surfaces 24, 25 running transversely to the longitudinal direction of the current discharge leg 22 are provided for fastening the current discharge leg 22 to the busbar 23. In addition, in the perspective view, concealed clamping means are provided which can be brought into operative connection with the contact surfaces 24, 25 and connect the current discharge leg 2 2 to the busbar 2 3. It is therefore not necessary to form a retaining web on the current discharge leg 23 by bending it. The clamping means and the wide contact surface of the side of the current discharge leg 22 facing away from the plug element 16 on the busbar 23 ensure reliable contact for conducting an outgoing current with a high current intensity.

Furthermore, the busbar 23 is fastened with a bracket 26 within the control cabinet 100. Thus, the power can be discharged from the insert 3, 5 at a predetermined position within the control cabinet 100.

List of reference symbols

1 Frame 2 Frame profile 3 Insert 4 Mounting side 5 Insert 6, 7 Subdivision profile 8, 8' , 8'' Functional space 9 Main busbar arrangement 10 Cross section 11 Holding element 12 Busbar arrangement 13 Busbars 15 Contact arrangement 16 Plug-in element 17 Contact surface 18 Terminal contact 19 Current dissipation element 20, 21 Side surface 22 Current discharge leg 23 Busbar 24, 25 Contact surface 26 bracket

Claims (5)

1. Contact arrangement for the power output of a plug-in unit ( 3 , 5 ) arranged in an electrical switch cabinet ( 100 ), 1. with a plug-in element ( 16 ) arranged on the rear side of the insert ( 3 , 5 ) which has clamping contacts ( 18 ) having contact surfaces ( 17 ), and 2. with a current-discharge element ( 19 ) fastened in the switch cabinet, which has a current-discharge leg ( 22 ) projecting in the direction of the insert ( 3 , 5 ) and having two side surfaces ( 20 , 21 ) and a busbar ( 23 ) connected to the current-discharge leg ( 22 ), 3. wherein in the inserted state of the insert ( 3 , 5 ), the contact surfaces ( 17 ) of the clamping contacts ( 18 ) rest on both side surfaces ( 20 , 21 ) of the current discharge leg ( 22 ) and each form a flat contact. 2. Contact arrangement according to claim 1, characterized in that the current discharge leg ( 22 ) has a thickness of more than 5 mm, preferably more than 10 mm. 3. Contact arrangement according to claim 1 or 2, characterized in that the current discharge leg ( 22 ) has at least one contact surface ( 24 , 25 ) running transversely to the longitudinal direction of the current discharge leg ( 22 ) and that clamping means can be brought into operative connection with the at least one contact surface ( 24 , 25 ) and connect the current discharge leg ( 22 ) to the busbar ( 23 ). 4. Contact arrangement according to one of claims 1 to 3, characterized in that the busbar ( 23 ) is fastened with a holder ( 26 ) within the switch cabinet ( 100 ). 5. Electrical switch cabinet with a contact arrangement for the current output of a plug-in unit according to one of claims 1 to 4, characterized in that a switching arrangement is arranged in the plug-in unit ( 3 , 5 ), via which the current is fed in for an arrangement of further switching devices.