BUSBAR FOR A BATTERY

Abstract

A busbar (10) for an electric battery (20) for electrically connecting a plurality of individual cells (21) of the battery (20) comprises at least two conductor layers (Lu, Lo) stacked one on top of the other. The conductor layers (Lu, Lo) are electrically insulated from each other except at specific contact points (P1. P2). A bottom conductor layer (Lu) comprises, at a first end, a main terminal (T) for connecting a power supply. A top conductor layer (Lo) is electrically connected to the bottom conductor layer (Lu) via at least a first contact point (P1) and a second contact point (P2). The electrical resistance along a first current path between the main terminal (T) and the first contact point (P1) is the same as the electrical resistance along a second current path between the main terminal (T) and the second contact point (P2).

Claims

1. A busbar (10) for an electric battery (20) for electrically connecting a plurality of individual cells (21) of said battery (20), wherein said busbar (10) comprises at least two conductor layers (Lu, Lo) stacked one on top of the other; said conductor layers (Lu, Lo) are electrically insulated from each other except at specific contact points (P1. P2); a bottom conductor layer (Lu) comprises, at a first end, a main terminal (T) for connecting a power supply; a top conductor layer (Lo) is electrically connected to said bottom conductor layer (Lu) via at least a first contact point (P1) and a second contact point (P2); and the electrical resistance along a first current path between said main terminal (T) and said first contact point (P1) is the same as the electrical resistance along a second current path between said main terminal (T) and said second contact point (P2).

2. The busbar (10) according to claim 1, wherein said first contact point (P1) is arranged in a first third in a longitudinal direction of said busbar (10); and said second contact point (P2) is arranged in a third third in a longitudinal direction of said busbar (10).

3. The busbar (10) according to claim 1, wherein a current from said main terminal (T) to said first contact point (P1) may flow in the longitudinal direction only with a reversal of direction; and a current from said main terminal (T) to said second contact point (P2) may flow in the longitudinal direction without a reversal of direction.

4. The busbar (10) according to claim 1, wherein said at least two conductor layers (Lu, Lo) stacked one on top of the other are electrically connected at said contact points (P1, P2) through at least one welding spot, respectively.

5. The busbar (10) according to claim 1, said busbar (10) comprising exactly two conductor layers (Lu, Lo).

6. The busbar (10) according to claim 4, the at least one welding spot of said first contact point (P1) arranged on a peninsular cutout (S1) of said bottom conductor layer (Lu).

7. The busbar (10) according to claim 6, said peninsular cutout (S1) electrically connected to an area of said bottom conductor layer (Lu) between said first contact point (P1) and said second contact point (P2).

8. The busbar (10) according to claim 6, said peninsular cutout (S1) extending in a longitudinal direction of said busbar (10).

9. The busbar (10) according to claim 1, said busbar (10) comprising a lateral cantilever (K) across the longitudinal direction on at least one of said contact points (P1, P2), thereby locally enlarging the width of said busbar (10).

10. The busbar (10) according to claim 1, wherein said busbar (10) comprises three conductor layers (Lu, Lm, Lo); said top conductor layer (Lo) is electrically connected by welding spots at said first contact point (P1) and said second contact point (P2) to said middle conductor layer (Lm); said bottom conductor layer (Lu) is electrically connected by welding spots at a third contact point (P3) to said middle conductor layer (Lm); and said third contact point (P3) is arranged centered between said first contact point (P1) and said second contact point (P2).

11. The busbar (10) according to claim 1, wherein said busbar (10) is made integrally from a metal sheet and comprises three conductor layers (Lu, Lm, Lo); said three conductor layers (Lu, Lm, Lo) are stacked one on top of the other by folding said metal sheet at connectors; and said contact points (P1, P2, P3) are provided as connectors at said folds.

12. An electric battery (20) with a plurality of individual cells (21), wherein said battery (20) comprises at least one busbar (10) according to claim 1; said top conductor layer (Lo) of said busbar (10) comprises a plurality of cell connectors (22) for electrically connecting said individual cells (21) to said busbar (10); and said cell connectors (22) are arranged in equal intervals along a longitudinal direction of said busbar (10).

Description

BRIEF DESCRIPTION OF THE FIGURES

[0027] In the following, further advantageous configurations are described in detail based on an embodiment depicted in the drawings, to which the invention is, however, not limited.

[0028] Schematically depicted are:

[0029] FIG. 1 shows a first embodiment of a busbar of the invention with three conductor layers (folded or welded).

[0030] FIG. 2 shows a second embodiment of a busbar of the invention with two conductor layers.

[0031] FIG. 3 shows a third embodiment of a busbar of the invention with two conductor layers.

[0032] FIG. 4 shows a sectional view of an exemplary electric battery of the invention with busbars.

DETAILED DESCRIPTION OF THE INVENTION BASED ON EMBODIMENTS

[0033] In the following description of a preferable embodiment of the present invention, identical reference numerals denote identical or comparable components.

[0034] FIG. 1 shows a first embodiment of a busbar 10 for an electric battery 20 for electrically connecting a plurality of individual cells 21 of the battery 20. The busbar 10 is made integrally from a metal sheet and comprises three conductor layers Lu, Lm, Lo: a bottom conductor layer Lu, a middle conductor layer Lm, and a top conductor layer Lo.

[0035] FIG. 1a shows a state of the metal sheet after the shape of the conductor layers was cutout and before the busbar 10 has been brought to its finished shape by folding the metal sheet at the dash-marked folding points A1, A2, A3. At another folding point A4 of the bottom conductor layer Lu, the main terminal T of the busbar may be arranged rectangularly to the longitudinal direction of the busbar 10.

[0036] The three conductor layers Lu, Lm, Lo are stacked one on top of the other by folding the metal sheet at the three folding points A1, A2, A3. The folding points A1, A2, A3 are provided at connectors between the individual conductor layers Lu, Lm, Lo. The finished state of the busbar 10 is depicted in FIG. 1b as a side view. The connectors form the contact points P1, P2, P3 between the conductor layers Lu, Lm, Lo.

[0037] The main terminal T provided at a first end of the bottom conductor layer Lu comprises two bores B for mounting a line. A first current path I1 from the main terminal T to the first contact point P1 is marked in FIG. 1a as a dotted arrow. A second current path I2 from the main terminal T to the second contact point P2 is marked in FIG. 1n as a dashed arrow. Both arrows are about equal in length. In other words, both current paths are equally long.

[0038] As is well recognizable based on the marked current paths I1, I2, a current I1 flows from the main terminal T to the first contact point P1 with a reversal of direction in the longitudinal direction. The change of direction occurs at the third contact point P3. A current I2 from the main terminal T to the second contact point P2 may flow in the longitudinal direction without a reversal of direction. From both contact points P1, P2 in the top conductor layer Lo, the current may spread along the length of the top conductor layer Lo. Through the arrangement of the contact points, a homogenous current distribution may be achieved in the top conductor layer Lo.

[0039] As illustrated by FIG. 1, the first contact point P1 is arranged in a first third in a longitudinal direction of the busbar 10. The second contact point P2 is arranged in a third third in a longitudinal direction of the busbar 10.

[0040] The length of the busbar 10 may for instance be about 30 cm. The width of the busbar 10 may for instance be 10 to 15 mm. The thickness of the conductor layers Lu, Lm, Lo is for instance about 1 to 2 mm. These values are only exemplary specifications and depend on the dimension and the structure of the battery, for which the busbar 10 is provided.

[0041] The three conductor layers Lu, Lm, Lo are electrically insulated from each other except at specific contact points P1, P2, P3, for instance by the metal sheet being coated with an insulating paint.

[0042] The busbar 10 according to the first embodiment may achieve a uniform current distribution on the top conductor layer Lo and is, in this course, particularly easy and cost-effectively to manufacture from an integral metal sheet by folding the metal sheet. At the top conductor layer Lo, cell connectors may be contacted for connecting the individual cells of a battery, for example by welding together the cell connector with the top conductor layer Lo.

[0043] The busbar 10 according to the first embodiment may alternatively also be manufactured by spot welding, so that no folds are necessary. Such a busbar 10 is manufactured from three separate conductor layers. The top conductor layer Lo is electrically and mechanically connected to the middle conductor layer Lm by welding spots at the first contact point P1 and the second contact point P2. The bottom conductor layer Lu is electrically and mechanically connected to the middle conductor layer Lm by welding spots at a third contact point P3. Here, the third contact point P3 is arranged centered between the first contact point P1 and the second contact point P2, so that two equally long current paths arise from the main terminal T to the first contact point P1 and the second contact point P2, respectively. The finished busbar 10 functionally corresponds to the busbar 10 of the first embodiment. Instead of the connectors, the welding spots create an electrical and mechanical connection.

[0044] FIG. 2 shows a second example of a busbar of the invention 10 with two conductor layers Lo and Lu. FIG. 2a shows both not yet connected conductor layers Lo and Lu in a top view. FIG. 2b shows a side view of the finished busbar 10 with the welded conductor layers Lo and Lu.

[0045] The top conductor layer Lo is electrically connected through a first contact point P1 and a second contact point P2 to the bottom conductor layer Lu with a welding spot, respectively. The welding spot of the first contact point P1 is arranged at a peninsular cutout S1 the bottom conductor layer Lu. This cutout S1 may for instance be made by laser cutting. By cutting it out, the peninsular cutout S1 is electrically insulated from its direct environment in the bottom conductor layer Lu. The peninsular cutout S1 is electrically connected to the centered area of the bottom conductor layer Lu between the first contact point P1 and the second contact point P2 close to the center M. As depicted in FIG. 2a, the peninsular cutout S1 extends in a longitudinal direction of the busbar 10.

[0046] The peninsular cutout S1 causes, as in the first embodiment, that a current from the main terminal T to the first contact point P1 may only flow in the direction of the longitudinal axis of the busbar 10 with a reversal of direction. A current from the main terminal T to the second contact point P2 may, in contrast, flow in a longitudinal direction without a reversal of direction. Thus, as in the busbar 10 according to the first embodiment, it is achieved that the electrical resistance along a first current path between the main terminal T and the first contact point P1 is equal to the electrical resistance along a second current path between the main terminal T and the second contact point P2. Thus, a homogenous current distribution may be provided on the top conductor layer Lo of the busbar 10 according to the second embodiment.

[0047] The busbar 10 comprises, at the first contact point P1, a lateral cantilever K across the longitudinal direction. Hereby, the width of the busbar 10 is locally enlarged. This cantilever K serves on one hand for mechanical stability and provides on the other hand an anchoring when mounting the busbar 10 in an electric battery 20.

[0048] Another embodiment of the busbar 10 is depicted in FIG. 3. This embodiment differs from the embodiment shown in FIG. 2 in that the top conductor layer Lo of the busbar 10 is connected through four welding spots P1a, P1b, P2a, P2b to the bottom conductor layer Lu of the busbar 10. The welding spots are arranged in pairs, respectively, with an identical interval to the marked center M. Further, each welding spot is arranged on its own cutout S1a, S1b, S2a, S2b. The cutouts S1a, S1b, S2a, S2b may, for instance, be made by laser cutting. By the cutouts, the welding spots P1a, P1b, P2a, P2b, respectively, are insulated from the environment on the conductor layer Lu.

[0049] Functionally, the third embodiment of the busbar 10 achieves the same effect as the first and second embodiments. The current path from the main terminal T to the four contact points and welding spots P1a, P1b, P2a, P2b, respectively, is equally large, respectively, so that a homogenous current distribution on the top conductor layer Lo may be achieved.

[0050] The structure in layers of the shown busbars 10 according to the embodiments with the described contacting causes a branching of the current path namely in two places. A first Y-shaped subdivision of the current is achieved in the second and third embodiments by the cutouts, especially by the first cutout S1, in the bottom conductor layer Lu. In the first embodiment, the Y-shaped subdivision of the current is achieved at the transition from the bottom conductor layer Lu to the middle conductor layer.

[0051] A second Y-shaped subdivision of the current is caused at the contact points P1, P2 to the top conductor layer. In the first embodiment, the second branching of the current paths is generated at both transitions from the middle conductor layer Lm to the top conductor layer Lo. In the second and third embodiments, the welding spots P1, P2 cause the second Y-shaped subdivision of the current. All embodiments have in common that, through the position of the contact points P1, P2 in the top conductor layer, a homogenous current distribution may be achieved.

[0052] FIG. 4 shows a schematic sectional view of an exemplary electric battery of the invention 20 with a plurality of individual cells 21. The sectional view of FIG. 4 shows a row with sixteen individual cells 21. The individual cells 21 are held by cell carriers 23. For the sake of clarity, only both outer cell carriers 23 are provided with a reference numeral 23 in FIG. 4, respectively.

[0053] Each row of the battery 20 comprises two busbars 10 of the invention for electrically connecting the individual cells 21. A first busbar 10 serves for connecting the positive poles of the individual cells 21 and a second busbar 10 serves for connecting the negative poles of the individual cells 21. The busbar 10 is mounted at a support structure of the battery 20. This mounting is not explicitly depicted in FIG. 4. The main terminals T+ and T− of both busbars 10 are located at the left side of the image. A power line for charging or discharging the individual cells 21 may be connected to the main terminals T+ and T−, respectively.

[0054] The top conductor layers Lo of the busbars 10 are connected to the positive poles and negative poles of the individual cells 21 of the battery 20 through a plurality of cell connectors 22, respectively. The cell connectors 22 may, for instance, be electrically connected to the top conductor layer Lo through welding spots 24, respectively. For the sake of clarity, in FIG. 4, only both welding spots of the cell connector 22 on the top left are provided with reference numerals 24. The cell connectors 22 are arranged in equal intervals along a longitudinal direction of the busbar 10. For the sake of clarity, in FIG. 4, only one cell connector 22 per busbar 10 is provided with a reference numeral 22, respectively.

[0055] The busbars 10 may be connected through the main terminal T to a current supply, respectively, for charging and discharging the individual cells 21, respectively. As described above in the embodiments of the busbar 10, a homogenous current distribution is provided on the top conductor layer Lo of the busbar 10, so that the same current flows through each cell connector 22 to the respective individual cell 21.

[0056] When charging the battery 20, a current Icharging flows from the first main terminal T+ through the individual cells 21 to the second main terminal T−. As indicated in FIG. 4 by means of arrows, the current I.sub.charging is divided at the contact points P1, P2, P3. At the contact point P3 between the bottom conductor layer Lu and the middle conductor layer Lm, the charging current I.sub.charging branches, so that in the middle conductor layer Lm, half of a charging current I/2 continues to flow to the contact points P1, P2 between the middle conductor layer Lm and the top conductor layer Lo, respectively. At the contact points P1, P2 between the middle conductor layer Lm and the top conductor layer Lo, the charging current I.sub.charging branches again, so that a quarter of the charging current I/4 continues to flow in the top conductor layer Lo to the cell connectors 22, respectively. Then, a charging current I/Zn (indicated by an arrow at the first cell connector 22) flows through each cell connector 22, wherein Zn is the number of individual cells 21 per busbar 10. Therefore, in the example shown, a current I/16 flows to each individual cell 21, respectively.

[0057] From the negative poles of the individual cells 21, a current I/Zn (indicated by an arrow at the last cell connector 22) flows into the top conductor layer Lo of the second busbar 10, respectively. The currents I/Zn flow together at the contact points P1 and P2 between the top conductor layer Lo and the middle conductor layer Lm, so that in the middle conductor layer Lm, half of a charging current I/2 flows to the contact point P3 between the middle conductor layer Lm and the bottom conductor layer Lu, respectively.

[0058] The depiction of the current flow is to be understood purely schematically and serves only the purpose of Illustration. Current losses by the charging operation and the electrical resistance of the conductor, respectively, and other losses were not considered here.

[0059] The features disclosed in the above description, the claims, and the drawings may be of significance for realizing the invention in its different configurations both, individually as well as in arbitrary combinations.