WO2011006493A2

WO2011006493A2 - Current bar having a compensation section

Info

Publication number: WO2011006493A2
Application number: PCT/DE2010/050045
Authority: WO
Inventors: Roland Trattner; Andreas Minkenberg; Jürgen Ertel; Peter Füssl; Robert Bachhofer; Kai Hüning
Original assignee: Taller Gmbh
Priority date: 2009-07-16
Filing date: 2010-07-14
Publication date: 2011-01-20
Also published as: WO2011006493A3; DE102009033370B4; DE102009033370A1

Abstract

The invention relates to a current bar for establishing an electrical connection, the current bar being composed of an electrically conductive material having a high current carrying capability, extending in a longitudinal direction x, and being constructed of several sections (1, 3) adjacent to each other, it being possible to fix the current bar to a carrier surface by means of at least two fastening sections (1), the current bar having at least one compensation section (3), which is arranged between two fastening sections (1) and is geometrically designed in such a way that the compensation section has a higher heat output capability than the adjacent sections of the current bar due to increased convection and/or heat radiation and that a local evasion of the material of the compensation section (3) perpendicular to the x direction due to local deformation of the compensation section (3) is enabled in the event of thermal expansion of the current bar in the fixed state, and the compensation section (3) comprising at least one connecting web (4, 4'), which connects the two sections of the current bar adjacent to the compensation section (3) to each other, the current bar being characterized in that the compensation section (3) comprises bent connecting webs (4, 4') without passage slits lying therebetween, adjacent connecting webs (4, 4') being bent in alternation in a y direction or a -y direction perpendicular to the x direction, and that the connecting webs (4, 4') are produced by means of through-cutting without waste and subsequent molding.

Description

Busbar with compensation section

Background of the Invention The invention relates to a bus bar for producing an electrical

Connection, wherein the bus bar consists of an electrically conductive material with high current carrying capacity, extending in a longitudinal direction x, and is composed of a plurality of adjacent sections, wherein the

Busbar can be fixed to at least two mounting portions on a support surface, wherein the busbar at least one

Compensation section, which between two

Fastening portions arranged and geometrically designed so that it on the one hand has a higher heat dissipation ability due to increased convection and / or heat radiation than the adjacent sections of the busbar, and on the other hand, upon thermal expansion of the busbar in the fixed state, a local evasion of the material of

Compensation section transverse to the x-direction is made possible by local deformation of the compensation section, and wherein the compensation section comprises at least one connecting web, which connects the two to the

Compensation section adjacent sections of the busbar interconnects.

Such a busbar is known for example from AT 344 812 B. Busbars are used to quickly and safely electrical

Make connections between two live components. For this purpose, the busbar is fastened to a plurality of sections in or on a housing, as presented for example in DE 196 46 264 A1. Such busbars are used in particular in power supply boxes in the automotive industry. Since in such power supply boxes high currents flow (about 200A), the busbar is heated during operation and it comes to a Thermal expansion, which in turn leads to mechanical stresses between the busbar and the housing. Due to this mechanical loading of the housing during thermal expansion, the housing, which is generally made of plastic, is deformed. This can lead to the formation of cracks and moisture can enter the housing.

Various solutions to this problem have been disclosed in the past. For example, US Pat. No. 3,544,706 proposes a metallic strip with superconducting wires embedded therein, which is bent in a U-shape to compensate for the mechanical stress and into which some longitudinal slots have been punched for cooling. However, this solution can not be readily transferred to non-superconducting applications.

In DE 698 35 023 T2 a transition element is used in a switching device, which is bent in a U-shape and by heat

can compensate for the resulting mechanical stresses by bending.

DE 198 39 423 A1 and US Pat. No. 1,157,603 disclose multi-piece, flexible

Elements that are used for the conductive connection between two current-carrying elements.

The AT 344 812 B introduces a curved ladder element with cooling ducts, which not only compensates for mechanical stresses caused by heat generation by further bending, but also permits heat exchange via the cooling ducts.

However, all solutions presented so far have the disadvantage that with the introduction of the transition elements or busbars, the cross section of the current-carrying conductor is reduced and it thereby already to a

Reduction of current carrying capacity comes. In addition fall with all known busbars with cooling

Production-related large amounts of waste material, such as by punching.

Object of the invention

It is therefore an object of the invention to provide a busbar, with which it is possible, even when loaded with high currents mechanical

To minimize voltages between the busbar and a busbar fixedly connected to this busbar, wherein the cross section of the conductor is not to be reduced by the busbar and wherein the busbar should be produced as waste-free.

Brief description of the invention

This object is achieved in that the

Compensating portion bent connecting webs without intermediate passage slots, wherein adjacent connecting webs are each bent alternately in a y-direction and a -y - direction transverse to the x direction, and that the connecting webs are prepared by truncate cutting and subsequent molding.

That the connecting webs extend at least partially in a direction deviating from the x-direction. As a result, an enlarged surface is realized and thus achieved an improved cooling effect.

The compensation section according to the invention thus serves as additional

Cooling surface. Due to the increased heat release capacity of the

Compensation section, the heat generation and thus the expansion of the material of the busbar is reduced.

The possibility of local evasion of the material of the busbar, causes the forces generated by thermal expansion of the material of the busbar the attachment points of the busbar to the support surface act, are kept so small that the support surface, eg. A housing is not destroyed even at high currents. The forces acting on the expansion are concentrated on the area of the compensation section which is designed to be more easily deformable than the fixing sections.

The deformation of the busbar is therefore reduced on the one hand by a lower heat development and on the other hand by means of a relative to the mounting portions flexible compensation range in a defined area.

It is particularly advantageous if the connecting webs are made by waste-free cutting and subsequent molding. As a result, an increased heat dissipation without cross-sectional loss of the material is possible. The compensation section can therefore have the same line cross section as the adjacent sections, as a result of which a constant current carrying capacity can be realized across the various sections of the busbar.

It is also advantageous if the connecting webs are bent transversely to the x-direction. The connecting webs then extend in sections along a direction which is a component perpendicular to the longitudinal direction of

Bus bar, for example. In the form of an arc. Thus, it is caused that by a deformation of the compensation section no significant forces acting on the fixing points of the busbar, since the. By the

Extension of the forces acting on the compensation section areas occurring forces in a direction perpendicular to the longitudinal direction of the

Busbar be deflected (alternative possibility of

Busbar material). Preferred embodiments of the invention

Preferably, at least three connecting webs are provided. It is particularly advantageous if the busbar including

Compensation section is constructed in one piece. The busbar can then be manufactured in a single operation and thus cost.

Further advantages of the invention will become apparent from the description and the drawings. Likewise, the features mentioned above and those listed further can be used individually or in any combination. The embodiments shown and described are not to be understood as exhaustive enumeration, but rather have exemplary character for the description of the invention.

Drawing and detailed description of the invention

It shows:

Fig. 1 is a perspective view of an embodiment of the

inventive busbar with alternately curved

Connecting webs. The busbars shown in the figures extend in the x-direction, which in operation is the current flow direction and each have two

Attachment sections 1, on which the busbar to a support surface (not shown) can be attached. Such a fastening can

for example, by screwing o.a. will be realized. These are in the embodiments shown in the attachment sections. 1

Attachment points provided in the form of recesses 2 through which

Fastener can be passed through. However, it is also possible To glue the busbar to the support surface or otherwise mechanically secure. Between the attachment portions 1 is a

Compensation section 3 is arranged, the one or more

Connecting webs 4, 4 'which extend at least partially transverse to the x-direction, whereby a local evasion of the material of the busbar is made possible transversely to the x-direction. Due to the design of the

Compensation section in the form of connecting webs results in addition to the adjacent sections (here:

Attachment sections 1) an increased surface per section area. This allows for improved heat dissipation, whereby the expansion of the

Busbar can be reduced.

Fig. 1 shows an embodiment of the bus bar according to the invention, in which the connecting webs 4, 4 'are designed arcuate. There are no through-slots here between adjacent connecting webs 4 and 4 ', but adjacent connecting webs 4, 4' are in opposite directions

Directions y or -y bent. This has the consequence that between each two connecting webs 4, which are bent in the y direction, a free space exists;

also between two connecting webs 4 ', which are bent in -y direction.

This has the advantage that on the one hand air between the individual

Connecting webs 4, 4 'circulate and on the other hand, the cross-section of the adjacent sections and thus the current carrying capacity can be maintained. The embodiment shown in Fig. 1 can by waste

Cutting through and subsequent molding are made.

The busbars according to the invention consist mainly of a

Material with high current carrying capacity and can be produced by punching (from sheet metal, especially copper) or by die casting (eg. From aluminum). In addition to the compensation of the expansion of the busbar in the x direction, due to the flexibility of the connecting webs 4, 4 '.auch

Torsionsbewegungen be compensated. The bus bar according to the invention is particularly suitable for high-current applications, eg for power supply boxes in the automotive sector or for connecting battery modules in electric cars.

LIST OF REFERENCE NUMBERS

1 attachment section

2 recess at attachment point

3 compensation section

4, 4 'connecting web

Claims

claims

1. busbar for establishing an electrical connection,

wherein the bus bar consists of an electrically conductive material with high current carrying capacity, extends in a longitudinal direction x, and is constructed of a plurality of adjoining sections (1, 3), wherein the bus bar with at least two mounting portions (1) can be fixed to a support surface , wherein the bus bar has at least one compensation section (3), which between two

Fastening portions (1) arranged and geometrically designed so that it on the one hand a higher heat release capacity due to increased

Convection and / or heat radiation than the adjacent sections of the busbar, and on the other hand at

Thermal expansion of the busbar in the fixed state, a local evasion of the material of the compensation section (3) is made possible transversely to the x-direction by local deformation of the compensation section (3), and wherein the compensation section (3) comprises at least one connecting web (4, 4 '), which the two to the

Compensation section (3) connects adjacent sections of the busbar,

characterized,

in that the compensating section (3) comprises curved connecting webs (4, 4 ') without intermediate through slots, wherein adjacent connecting webs (4, 4') are respectively bent alternately in a y-direction and a -y-direction transverse to the x-direction .

and that the connecting webs (4, 4 ') are produced by waste-free cutting and subsequent molding.

2. Busbar according to claim 1, characterized in that at least three connecting webs (4, 4 ') are provided.

3. busbar according to one of the preceding claims, characterized

characterized in that the busbar including

Compensation section (3) is constructed in one piece.