DE102012002355A1 - Electrical conductor for vehicle e.g. motor car, has connectors which in parallel to memory cell pack or memory cell, and cross section of electric conductor over entire extension is not constant while current density is constant - Google Patents

Abstract

The electrical conductor (7) has several connectors which are electrically connected in parallel to the memory cell pack (5) or switchable interconnected memory cells (6). The cross section of the electric conductor over the entire extension is not constant respectively, so that the current density as a measure of the electrical load of the conductor by the total extension is largely constant. The electric conductor is made of an aluminum copper composite material.

Description

The invention relates according to the preamble of claim 1 of the invention, an electrical conductor as a connector of a plurality of parallel in a circuit electrically connected to a memory cell pack or interconnected memory cell. The invention further relates to a memory cell pack with at least one such electrical conductor and a vehicle, in particular a motor vehicle, with such a memory cell pack.

Electrical conductors, also referred to as connectors or busbars, have long been known in the prior art for connecting or interconnecting a plurality of memory cells to form a memory cell pack. Said storage cells, which may be batteries or accumulators, are connected in parallel and / or in series or in series, in order to achieve a specific capacity, a higher current-carrying capacity and / or a higher total voltage for a particular application. So is out of the US Pat. No. 6,240,637 B1 a connection plate for a battery holder for connecting a plurality of batteries in series connection, wherein the connection plate comprises a synthetic resin plate, in which bus bars are integrally molded by injection molding. Each bus bar is formed as a rectangular section plate member through which a large current can flow. The bus bar has two ends each a hole for fixing the busbar by means of a fastening screw to a terminal contact of a battery to be connected. From the US 2010/0104932 A1 a so-called high-voltage battery is known, which consists of a number of arranged in rows of battery cells, a support structure and a cover plate, are attached to the high-current connector for the individual battery cells and a cell monitoring unit. The cover plate is formed by a multilayer printed circuit board with at least two conductive layers. The first layer is attached to the battery cell side facing the printed circuit board and to form the high current connector of considerable thickness. The second layer is of small thickness and forms the connection lines to the cell monitoring unit. At certain points, the layers are connected to one another by means of conductive holes passing through the printed circuit board. Next is from the DE 10 2008 039 412 A1 a connection arrangement for the mechanical and electrical connection of a plurality of memory cells is known in which for each pair of terminals of two memory cells to be interconnected a conductor bridge made of sheet metal is used as a single connector, which rests flat against a support plate and is pressed with this. In order to enable a high current carrying capacity, each conductor bridge is made correspondingly wide, thereby providing the required for said high current carrying capacity cross-section. Also the WO 2011/038908 A1 describes cell connectors in the form of single connectors for connecting battery cells arranged in series to a battery pack. The present particular multi-bow-shaped cell connectors are made of a sheet material with sufficient spring and power line properties, such as sheet steel, copper, copper alloy, aluminum or an aluminum alloy and are fixed to a mounting plate made of electrically insulating material. Finally, out of the US 2010/0255355 A1 a connector for electrically connecting a plurality of battery cells to a battery cell pack, which are connected in series and / or in parallel with each other. For this purpose, in particular, multiple connectors for connecting, for example, four batteries use. The connectors are integrally formed according to the batteries to be connected and formed by connecting parts to the battery and corresponding connecting parts. All the above-described electrical conductors or connectors or busbars have in common that they have a largely constant cross-section, which is designed as a function of the maximum current carrying capacity of said conductor. However, it is known in practice that the current load of such a conductor, in particular when more than two memory cells, such as batteries or accumulators, are interconnected, changes over the total extension (longitudinal extent) of the conductor. Thus, current input side, that is to say a lower current load in the contact section of the first memory cell than on the current output side, for example in the contact section of a next and further memory cell connected in parallel with the preceding memory cell (s).

On this basis, it is an object of the invention to provide an electrical conductor of the type specified, which is adapted for a currently intended application optimally to the resulting electrical load of the same.

According to the invention, the object is formed by an electrical conductor as a connector of a plurality of parallel electrically connected to a memory cell pack or interconnected memory cells with a cross section, which in turn over the total extension "l" of the electrical conductor seen is not constant or so different that the current density, which is known to characterize the distribution of electrical current in a conductor, as a measure of the electrical Resilience of the conductor over said total extension "l" of the same is largely constant.

As is known, said current density is defined as the ratio of the current intensity "I" to the cross-sectional area "A" of the electrical conductor through which the current flows. Accordingly, the cross section of the electrical conductor is an essential factor for its current carrying capacity or current carrying capacity. The larger the cross section of the conductor, the greater its current carrying capacity. In view of this, an electrical conductor of the generic type is created by the measure according to the invention, whose cross-section is optimally designed or designed to be in the respective contact portion with the memory cell current load. Thus, while ensuring the required current-carrying capacity of the electrical conductor over its entire extent, the cross-section of the electrical conductor in the current-input-side contact section can be selected to be lower than in the region of the memory cells contacting the electrical output side, resulting in material, weight and thus cost savings , A constant cross-section provided over the total extension "l" (longitudinal extension) of the electrical conductor, which in turn is designed according to the prior art as a function of the highest current load to be recorded, is advantageously avoided by the measure according to the invention. The cross-section of the electrical conductor according to the invention is thus chosen so different over the total extension "l" that he each coped with the locally occurring currents and over the total extension "l" of the electrical conductor ensures a largely constant current density.

The subclaims describe preferred developments or refinements of the invention.

According to a preferred embodiment variant of the electrical conductor is formed by a metal strip having a plurality of successively arranged contact portions for the interconnected or interconnected memory cells, wherein the cross section of the conductor or the metal strip of contact portion to contact portion changes discontinuously or continuously. This measure results from the recognition that the current carrying capacity of an electrical conductor is not proportional to the cross section, but is also determined by its shape, the ambient temperature, the conductor material and the type of laying of the conductor. Although very good results with regard to current carrying capacity and material reduction can already be achieved with a discontinuous, for example stepped, change in cross section, it may also be advantageous to further optimize these results by adapting the cross section to the local requirements by continuously changing it becomes. Thus, the change in cross section seen over the total extension "l" of the conductor can also be rectilinear or curved. The respectively locally required conductor cross-section can be determined by calculation and / or empirically or can be taken from corresponding standard specifications. With regard to the applicable parallel connection of memory cells, the electrical conductor therefore advantageously has a smaller cross-section on the line input side than on the line output side. In a further advantageous embodiment of the invention, a connection contour for connecting the electrical conductor to a connection element of the respective memory cell is provided in each contact section of the electrical conductor. This allows a simple and inexpensive assembly of the memory cell packs with said conductors or connectors are made possible. In a further advantageous embodiment of the invention, the connection contour is formed by a cup-shaped embossing in the electrical conductor with a Prägungsgrund whose material thickness is approximately equal for all imprints of the electrical conductor. By this measure, optimum joining conditions are created for the selected joining method, for example laser welding, and the joining technique required for joining the conductor / connector with corresponding contact terminals of the memory cells. According to a further advantageous embodiment of the invention, the electrical conductor is formed integrally such that the same two adjacent arranged and connected in series memory cell packs electrically connected to each other in parallel memory cells, whereby the assembly costs for the compilation of, for example, from a plurality of single memory cells -Packs resulting in total memory cell packs is reduced. The electrical conductor can be formed simply and inexpensively by cutting to length a TRB (TRB = Tailor Rolled Blank) which is known per se, wherein said TRB is produced by rolling a sheet metal strip having different sheet thicknesses. An inexpensive electrical conductor is achieved by the fact that it is formed by a composite material, in particular by an aluminum-copper composite, in which preferably a core of the conductor made of inexpensive aluminum and the surface of the conductor at least partially made of copper. Compared to conventional electrical conductors / connectors of the generic type of solid material, in particular solid copper, weight savings are also achieved while ensuring a very good heat dissipation, a low contact resistance and a thermal short-circuit strength. Such a conductor of aluminum-copper composite material can be passed through with high quality Cold rolling of one or more copper circuit boards on an aluminum circuit board, by electroplating an aluminum circuit board with a copper layer or by spraying a copper layer on an aluminum circuit board. According to a further preferred embodiment variant of the electrical conductor is formed by a laminated core of a plurality of stacked individual sheets having a plurality of successively arranged contact portions for the interconnected or interconnected memory cells, wherein the cross section of the conductor or the metal strip of contact section to contact section changes discontinuously or continuously. Such a laminated core can be easily and inexpensively manufactured in adaptation to the respective number of contact connections to be considered by selecting from a plurality of held different individual sheets and the same are assembled to form a laminated core.

The invention also relates to a memory cell pack with at least one electrical conductor of the type described above. In addition, the invention also relates to a vehicle, in particular motor vehicle, with such a memory cell pack.

The invention will be explained in more detail with reference to the embodiment schematically illustrated in the drawings. Show it:

1 very schematically a vehicle designed according to the invention, in the present motor vehicle, in longitudinal section with a plurality of interconnected electric storage cell packs,

2 the plurality of interconnected electrical memory cell packs 1 in a perspective single view,

3 a perspective detail view of a first advantageous embodiment variant of an electrical conductor or connector for connecting memory cells of a memory cell packs and memory cell packs with each other,

4 a perspective sectional view of the electrical conductor after 3 according to an advantageous development of the same (section "II" after 3 )

5 the side view of a second advantageous embodiment variant of an electrical conductor or connector for connecting memory cells of a memory cell packs and memory cell packs with each other, and

6 the top view of a third advantageous embodiment variant of an electrical conductor or connector for connecting memory cells of a memory cell packs and memory cell packs with each other.

1 shows very schematically a vehicle 1 , in the present case a motor vehicle in the form of a hybrid vehicle, with a known internal combustion engine arranged in the front region thereof 2 and a rear end of the same arranged per se known electric motor 3 , There is also a vehicle tunnel 4 in the present case, a center tunnel extending in the vehicle longitudinal direction, in which four electric storage cell packs 5 angeordet and combined or connected to a so-called high-voltage battery system.

According to 2 are the said memory cell packs 5 exemplarily each by three electrical storage cells 6 , For example, each formed by three Li-ion batteries, the non-illustrated, but per se known connection elements or terminal poles are arranged in a common plane. The electric storage cells 6 of each memory cell pack 5 are connected in parallel to each other by the plus poles or the negative poles of the same each immediately adjacent to each other and arranged by means of one electrical, conductor 7 , Also referred to as a connector, in this case multi-connector, are interconnected. The. each of three memory cells 6 formed four memory cell packs 5 are connected to each other in series, each by an electrical conductor 7 seen in the current flow direction in one piece from the negative pole of a memory cell packs 5 to the plus pole of the adjacent other memory cell pack 5 extends.

How the particular 2 can be further seen, is the cross section of the electrical conductor 7 seen over its total extension "l" (longitudinal extent) not constant respectively so different that the current density as a measure of the electrical load capacity of the conductor 7 over said total extension "l" of the same is largely constant.

Due to the parallel connection of the memory cells 6 of each memory cell pack 5 is known to be a summation of the currents I1, I2 and I3 of the individual memory cells 6 to a total flow (total) (see esp. 3 ). Due to the summation of the currents I1 to I3 are over the total extension "l" of the electrical conductor 7 Seen locally certain minimum Materlalquerschnitte the same required, so that a certain electrical load capacity of the electrical conductor 7 is guaranteed. Said minimum cross section goes with a certain current density in the material cross-section, ideally in the entire electrical conductor 7 should be constant. Due to the fact that current input side of the electrical conductor 7 only the current I1 of a memory cell 6 is applied, requires the electrical conductor 7 in this contact section 8a only the required material cross section. With each additional memory cell connected in parallel 6 and each further adjacent current I2, I3 is an increased material cross section in the respective contact section 8b . 8c required to keep said current density constant and the electrical capacity of the electrical conductor 7 without adverse heating of the conductor 7 to ensure. Accordingly, in the present case, the electrical conductor 7 line input side, where only the current I1 a memory cell 6 is applied, a smaller cross section than the line output side, where the current I1 to I3 three memory cells 6 is applied.

The electrical conductor 7 is presently formed by a metal strip with a rectangular cross-section, which in turn has a larger surface in terms of a circular cross-section and thus allows better heat dissipation. The different cross sections in the contact sections 8a . 8b . 8c is presently by a discontinuous, here stepped change in the cross section of contact section 8a to contact section 8b and on to contact section 8c Taken into account (Insbes. 3 ).

On the other hand, if necessary, it may also be advantageous to adapt the cross section to the local requirements exactly by continuously changing it, by changing the cross section in the longitudinal direction of the conductor 7 seen straight or curved (not shown in the drawing). The respectively locally required conductor cross-section can be determined by calculation and / or empirically or can be taken from corresponding standard specifications.

The use of a TRB known per se (TRB = Tailor Rolled Blank) allows a cost-effective shaping of said electrical conductors 7 or connectors, in particular multiple connectors, whose cross-section is not constant. The contour can be made as a cross section of a TRB in the coil. The required width "b" of the electrical conductors 7 or connector can be cut in the direct connection to the training of the TRB of the same and in the favored for each fastening technology for fastening the electrical conductor 7 at the connection elements or terminal poles of the memory cells 6 provided contact sections 8a . 8b . 8c each with a connection contour 9 be formed.

The electrical conductor 7 is present in the respective contact section 8a . 8b . 8c with a connection contour 9 formed in the shape of a cup-shaped embossment, which in turn into the plane surface of the electrical conductor 7 opposite surface of the same is introduced. The material thickness of the stamping ground 10 all embossing is chosen approximately equal, so that for all contacts with the connection elements or terminal poles of the memory cells 6 defined conditions for the attachment, for example by laser welding prevail. The electrical conductor 7 In this respect, its flat surface is placed on said connection elements or connecting poles and welded to the same. In contrast, it may also be appropriate to the electrical conductor 7 in such a way to put on said connection elements or connecting poles that they each form fit penetrate an embossing and thus allow a further improved joint connection. This measure, however, while retaining the described fastening measure, a correspondingly adapted shape and dimensioning of the connection elements or connection poles to said connection contours 9 or imprints ahead (not shown in the drawing).

Are, as in 2 by way of example, three memory cells each 6 parallel to a memory cell pack 5 interconnected and several such memory cell packs 5 connected in series or in series, the contacting of the above already mentioned and in the 2 and 3 Six-fold connector shown done. The electrical conductor 7 Thus, now a six-connector, it is thus formed integrally so that it simultaneously two adjacently arranged and connected in series memory cell packs 5 connects electrically. The unevenly loaded in relation to the current flow electrical conductor 7 Thus, starting from the two ends of the same optimized cross-sections in the form of converging cross-sectional changes from the lower to the higher, each with three contact sections 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' on.

The current input and current output side of the high-voltage battery system arranged contact terminal for connecting the electrical system of the vehicle 1 is by an extension 13 . 14 a trained as a triple connector electrical conductor 7 formed, wherein the cross section of each extension 13 . 14 suitably the largest cross-section of the relevant conductor 7 equivalent.

What the electrical conductor 7 As far as the connector itself is concerned, it may consist of an electrically conductive metal, for example a solid copper material ( 3 ). In contrast, it may also be appropriate and is by the invention to apply a composite material. Such a composite material may for example be an aluminum-copper composite material (Al-Cu), in which in particular the core 11 of the leader 7 made of aluminum and the surface 12 of the leader 7 consist at least in sections of copper ( 4 ). Compared to conventional electrical conductors 7 or connectors of the generic type of particular copper weight and cost savings are recorded while maintaining a very good heat dissipation, a low contact resistance and a thermal short-circuit strength. Said composite material can be advantageously formed by known cold rolling of one or more copper circuit boards on an aluminum circuit board, by electroplating an aluminum circuit board with a copper layer or by spraying a copper layer onto an aluminum circuit board (not shown in the drawing). Such a composite can also be formed very well as TRB.

By the manufacturers of memory cells 6 or accumulators are also memory cells for a variety of reasons 6 provided, the terminal poles are made of different materials. For example, the one pole of the memory cell 6 made of aluminum and the other pole made of copper. In view of this, the invention also provides an electrical conductor 7 of the generic type detected by way of example with reference to the above-described, made of solid material electrical conductor 7 ( 3 ) in the form of a six-way connector of an aluminum triple connector and a copper triple connector. Said triple connector can be manufactured separately and in a subsequent joining process, for example by friction welding or Platinierwalzen, interconnected (not shown in the drawing). Furthermore, with respect to the embodiment according to 4 also only a section of the electrical conductor 7 or connector coated by the six-way connector, the left or right section (three contact gates 8a . 8b . 8c or 8a ' . 8b ' . 8c ' ) thereof formed by solid aluminum material and the other portion having a surface 12 made of copper.

However, the invention is not limited to electrical conductors 7 or connector of the generic type, which consist at least predominantly of solid material, but also detects electrical conductors 7 passing through a laminated core 15 are formed ( 5 ). A plurality of prefabricated and optionally coated with other, especially electrically conductive materials individual sheets 16 are under the proviso constant current density over the total extension "l" (longitudinal extent) of the electrical conductor 7 seen stacked and preferably for better handling of the electrical conductor formed 7 cohesively, positively and / or non-positively by means of, for example, per se known and therefore not shown in detail mechanical fasteners, such as screws, rivets or the like., Firmly interconnected. In selected contact sections 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' can the above-mentioned connection contours 9 provided and already in the preparation of the individual sheets 16 incorporated into them (not shown in the drawing).

All electrical conductors described above 7 or connectors represent a cross-section that exceeds the total extension "l" (longitudinal extent) of each conductor 7 Seen in height "h" or thickness varies to ensure a constant current density. However, also covered by the invention is an electrical conductor 7 or connector whose cross-section over the total extension "l" (longitudinal extent) of the conductor 7 seen in width "b" varies. 6 shows such an electrical conductor 7 or multiple connector, in this case quadruple connector, with four connection contours 9 for memory cells to be connected 6 , wherein by means of this conductor 7 two memory cells each 6 to a memory cell pack 5 connectable and the same in turn are switchable in series.

A combination of measures described above, for example, such that for the realization of a constant current density in the conductor 7 or connector of the cross section of the conductor 7 is varied over its total extension "l" (longitudinal extension) seen in both the height "h" and in the width "b" is also covered by the invention (not shown in the drawing).

LIST OF REFERENCE NUMBERS

1

vehicle

2

internal combustion engine

3

electric motor

4

vehicle tunnel

5

Memory cell pack

6

memory cell

7

electrical conductor / connector

8a-8c

contact portions

8a'-8c '

contact portions

9

connecting contour

10

stamping ground

11

core

12

surface

13

extension

14

extension

15

laminated core

16

Single sheet

11-13

electric current coming from the respective memory cell 6 provided

"L"

Total extension (longitudinal extension) of the electrical conductor / connector 7

"B"

Width of the electrical conductor / connector 7

"H"

Height or thickness of the electrical conductor / connector 7

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6240637 B1 [0002]
• US 2010/0104932 A1 [0002]
• DE 102008039412 A1 [0002]
• WO 2011/038908 A1 [0002]
• US 2010/0255355 A1 [0002]

Claims (10)

Electrical conductor ( 7 ) as a connector of a plurality in parallel electrically to a memory cell pack ( 5 ) interconnected or interconnectable memory cells ( 6 ), characterized in that the cross-section of the electrical conductor ( 7 ) is not constant or is so different over its total extension "l" that the current density as a measure of the electrical load carrying capacity of the conductor ( 7 ) over said total extension "l" of the same is largely constant. Electrical conductor ( 7 ) according to claim 1, characterized in that the electrical conductor ( 7 ) by a metal strip having a plurality of successively arranged contact sections ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) for the interconnected or interconnectable memory cells ( 6 ) is formed, wherein the cross section of the conductor ( 7 ) respectively of the metal strip of contact section ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) to contact section ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) changes discontinuously or continuously. Electrical conductor ( 7 ) according to claim 1 or 2, characterized in that the electrical conductor ( 7 ) line input side has a smaller cross-section than the line output side. Electrical conductor ( 7 ) according to one of claims 1 to 3, characterized in that in each contact section ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) of the electrical conductor ( 7 ) a connection contour ( 9 ) for connecting the electrical conductor ( 7 ) with a connection element of the respective memory cell ( 6 ) is provided. Electrical conductor ( 7 ) according to claim 4, characterized in that the connection contour ( 9 ) by a pot-shaped embossing with a minting reason ( 10 ) is formed, the material thickness for all imprints of the electrical conductor ( 7 ) is approximately equal. Electrical conductor ( 7 ) according to one of claims 1 to 5, characterized in that the electrical conductor ( 7 ) is integrally formed so as to concurrently concatenate two adjacent and in-line memory cell packs (FIGS. 5 ) electrically connects. Electrical conductor ( 7 ) according to one of claims 1 to 6, characterized in that the electrical conductor ( 7 ) is formed by cutting to length a TRB (Tailor Rolled Blank), said TRB being produced by rolling a sheet metal strip having different sheet thicknesses. Electrical conductor ( 7 ) according to one of claims 1 to 7, characterized in that the electrical conductor ( 7 ) is formed by a composite material, in particular by an aluminum-copper composite material. Electrical conductor ( 7 ) according to claim 1, characterized in that the electrical conductor through a laminated core ( 15 ) of a plurality of stacked individual sheets ( 16 ) with a plurality of successively arranged contact sections ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) for the interconnected or interconnectable memory cells ( 6 ) is formed, wherein the cross section of the conductor ( 7 ) respectively of the metal strip of contact section ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) to contact section ( 8a . 8b . 8c ; 8a ' . 8b ' . 8c ' ) changes discontinuously or continuously. Memory cell pack ( 5 ) with at least one electrical conductor ( 7 ) according to one of claims 1 to 9, as well as vehicle ( 1 ), in particular motor vehicle, with such a memory cell pack ( 5 ).

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