WO2024046830A1 - Monocell stack for a battery cell - Google Patents

Abstract

The invention relates to a monocell stack for a battery cell, having a number of monocells (M) stacked one above the other in the stacking direction, each of which monocells (MS) is assembled from, in alternation in the stacking direction, an electrode sheet (K), a separator sheet (S1), a mating electrode sheet (A) and a further separator sheet (S2). According to the invention, the two separator sheets (S1, S2) are components of a double sheet layer (D), which are folded around the electrode sheet (K) in a U-fold along a folding edge (11). The mating electrode sheet (A) is arranged on the outer side of one of the separator sheets (S1, S2).

Description

Description

Mono cell stack for a battery cell

The invention relates to a mono-cell stack for a battery cell according to the preamble of claim 1 and a method or a process arrangement for producing such a mono-cell stack according to claim 10.

An electrode/separator stack for a battery cell can, for example, be manufactured in a Z-fold, in which an endless separator web is folded in a Z-fold around electrode sheets arranged one above the other. Alternatively, the electrode/separator stack can be manufactured as a generic mono-cell stack. This has a number of monocells stacked one above the other in the stacking direction. Each of the monocells is alternately assembled in the stacking direction from an electrode sheet, a separator sheet, a counter-electrode sheet and a further separator sheet, for example in a laminating station, to form a one-piece structural unit. The series production of such a mono-cell stack can be carried out at a significantly higher process speed than with an electrode/separator stack manufactured in Z-folding.

An electrode arrangement is known from US 2019/0189976 A1. A rechargeable battery is known from EP 3 246 979 A1. An electrode arrangement and a method for producing such an electrode arrangement are known from WO 2020/121044 A1. An electrode/separator stack for a battery cell is known from US 2010/0190081 A1. Another electrode arrangement for a battery cell is known from EP 3242 346 A1.

The object of the invention is to provide a mono-cell stack for a battery cell that allows large-scale production, with greater process speed and/or reduced manufacturing effort compared to the prior art.

The task is solved by the features of claim 1 or claim 10. Preferred developments of the invention are disclosed in the subclaims. The invention is based on a mono-cell stack for a battery cell, which has a number of mono-cells stacked one above the other in the stacking direction. Each of these monocells is assembled alternately in the stacking direction from an electrode sheet, a separator sheet, a counter-electrode sheet and a further separator sheet. According to the characterizing part of claim 1, the two separator sheets are components of a double sheet layer. The double sheet layer is folded around the electrode sheet in a U-fold along a fold edge. The counter electrode sheet is arranged on the outside of one of the separator sheets.

A process arrangement for producing such a mono-cell stack has the following process steps: First, the electrode sheet, the counter-electrode sheet and the double sheet layer are cut from an endless web in a cutting device. The electrode sheet is then placed on the double sheet layer in a first laying device. In the further process, the double sheet layer is folded around the electrode sheet along the folded edge using a folding device. The counterelectrode sheet is then arranged on the outside of one of the separator sheets using a second laying device. The still loose sheet structure is then fed to a laminating device in which the electrode and separator sheets are laminated to form a monocell. The completed monocell is transferred to a stacking device in which the monocells are stacked to form a monocell stack.

In a preferred embodiment variant, the mono-cell stack can end in the stacking direction at its two stack ends with a counter-electrode sheet each. The counter electrode sheet can preferably be an anode sheet, while the electrode sheets can be implemented as cathode sheets.

According to a first embodiment variant, the monocells can be stacked in the monocell stack with an identically repeating electrode-separator sheet sequence in the stacking direction, starting from a first stack end to a second stack end. At the first end of the stack, an end monocell with an external counterelectrode sheet (preferably anode sheet) can be arranged. In contrast, an end monocell with an external separator sheet can be arranged at the second end of the stack. A single counterelectrode sheet (that is, in particular an anode sheet) can preferably be stacked on the external separator sheet of the second stack end. The individual counter-electrode sheet is manufactured in an upstream process step as a separate structural unit, i.e. independently of the monocells. In a further embodiment variant, a single electrode sheet (preferably a single anode sheet) can be stacked on the outer counter electrode sheet of the first stack end, with a separator sheet in between. The individual electrode sheet and the separator sheet can be joined together to form a layer composite before the stacking process. This can be stacked onto the external counter electrode sheet during the stacking process.

In a further embodiment variant, the mono-cell stack can be divided into at least two sub-stacks in the stacking direction. In the first partial stack, the monocells can be stacked with an electrode-separator sheet sequence that repeats itself identically in the stacking direction. The second partial stack can be turned over by 180° compared to the first partial stack. In this case, the monocells are stacked in the second sub-stack with a reversed electrode-separator sheet sequence that repeats itself identically in the stacking direction.

The two partial stacks lie opposite each other in the stacking direction, each with a separator sheet of the double sheet layer, with the interposition of a single counterelectrode sheet (in particular an anode).

The electrode sheets and/or the counter-electrode sheets can each be formed in a conventional manner from a current conductor film with electrode coating on both sides. In addition, the electrode sheets and/or the counter-electrode sheets can each be extended with laterally projecting arrester lugs. In a first embodiment, the folded edges of the double sheet layers in the mono-cell stack, viewed in the stacking direction, can be arranged alternately on opposite mono-cell stack sides. Alternatively, the fold edges of the double sheet layers in the mono-cell stack can be arranged on the same mono-cell stack side.

The conductor tabs of the electrode sheets and/or the counter-electrode sheets can, for example, be aligned parallel to the folded edges. Alternatively, the arrester tabs of the electrode sheets can protrude on the side opposite the folded edge.

Exemplary embodiments of the invention are described below with reference to the attached figures. Show it:

Figures 1 to 3 show a mono-cell stack according to a first exemplary embodiment; Figures 4 to 6 each show views which illustrate a process sequence for producing the mono-cell stack;

Figures 7 to 11 further embodiment variants of the mono-cell stack.

1 shows a mono-cell stack for a battery cell, which is constructed from a number of mono-cells 1 stacked one above the other in the stacking direction. In Figure 3 one of the monocells M is shown alone. Accordingly, the monocell 1 is constructed (from top to bottom) of a cathode sheet K, a separator sheet S1, an anode sheet A and a further separator sheet S2, which are joined together in a lamination process. The cathode sheet K and the anode sheet A are each formed in a manner known per se from a current conductor film 3, which is coated on both sides with an electrode coating 5. The current arrester foil 3 is each extended with a cathode-side arrester lug 7 (Figures 8 to 11) or an anode-side arrester lug 9 (Figures 8 to 11).

As can be seen from Figures 2 or 3, the two separator sheets S1, S2 are components of a double sheet layer D. The double sheet layer D is folded around the cathode sheet K in a U-fold along a fold edge 11. The anode sheet A is arranged on the outside on the lower separator sheet S2 in FIG. 3.

According to Figures 1 or 2, the mono-cell stack ends in the stacking direction at its two stack ends with an anode sheet A each. In addition, the mono-cell stack in Figures 1 and 2 is divided into two sub-stacks 13, 15 in the stacking direction. In the upper first sub-stack 13, the monocells M are stacked with an identically repeating electrode-separator sheet sequence in the stacking direction, that is to say from bottom to top with the first separator sheet S1, the cathode sheet K, the second separator sheet S2 and the anode sheet A. In the same way The monocells M are also stacked in the lower second sub-stack 15 with an identically repeating electrode-separator sheet sequence in the stacking direction, that is to say from top to bottom with the first separator sheet S1, the cathode sheet K, the second separator sheet S2 and the anode sheet A. The lower one The second sub-stack 15 is therefore turned over by 180° compared to the upper first sub-stack 13. In the sheet sequence in the second partial stack 15, the anode sheet A of each monocell M is positioned at the bottom, followed by the second separator sheet S2, the cathode sheet K and the first separator sheet S. According to the exploded view in FIG with the first separator sheet S1 opposite the respective double sheet layer D, namely with an intermediate layer a single anode sheet AE, which is not part of a monocell M, but rather is manufactured separately from it.

In Figure 1 or 2, all folding edges 11 of the first sub-stack 13 are positioned on one side of the mono-cell stack, while the folding edges 11 of the second sub-stack 15 are positioned on the opposite side of the mono-cell stack.

Based on Figures 4 to 6, a process sequence for producing the mono-cell stack shown in Figure 1 is described: Accordingly, the cathode sheet K, the anode sheet A and the double sheet layer D are cut from endless web goods into individual sheets in a cutting device, as shown in Figure 4 . The cathode sheet K is then placed on the double sheet layer D in a first laying device (FIG. 4). With the help of a folding device, the double sheet layer D is folded around the cathode sheet K in a U-fold along the fold edge 11 (FIG. 5). In a further process step (Figure 6), the anode sheet A is positioned on the outside of the separator sheet S2. This is followed by lamination, which is not indicated, in which the individual sheets are put together in a laminating device in the still loose mono-cell sheet structure. The monocells M are then stacked in a stacking device to form a monocell stack.

Further exemplary embodiments of the mono-cell stack are shown in FIGS. 7 to 11. The mono-cell stack shown in FIG. 7 is constructed essentially identically to the mono-cell stack shown in FIG. 1. In contrast to FIGS. 1 or 2, in FIG. 7 all folding edges 11 are positioned on a common mono-cell stack side.

The mono-cell stack shown in FIG. 8 essentially corresponds to the mono-cell stack shown in FIG. 7. In contrast to FIG. 7, in FIG. 8 the arrester lugs 7, 9 each protrude outwards at right angles to the folded edges 11. Accordingly, the cathode-side arrester lugs 7 are extended to the left monocell stack side, while the anode-side arrester lugs 9 are extended to the right monocell stack side.

9 shows a further mono-cell stack which is not formed from two stacks 13, 15 with an intermediate central anode AE. Rather, in Figure 9, the monocells M are stacked with an identically repeating electrode-separator sheet sequence in the stacking direction S, from an upper first stack end to a lower second stack end. An end-side monocell M with an external anode sheet A is arranged at the upper first end of the stack. In contrast, at the bottom is the second end of the stack an end monocell M with an external separator sheet S1 is arranged. A single anode sheet AE is additionally stacked on the external separator sheet S1 of the lower second end of the stack.

In Figure 10, the monocells M are constructed differently in contrast to the previous figures: In the respective monocell M, the double sheet layer D is no longer folded around the cathode sheet K, but rather around the anode sheet A. The cathode sheet K is arranged on the outside of the separator sheet S2. 9, the monocells M are also stacked in the monocell stack with an identically repeating electrode-separator sheet sequence in the stacking direction, again from an upper first stack end to a lower second stack end. An end-side monocell M with an external first separator sheet S1 is arranged at the upper first end of the stack. An end-side monocell M with an external cathode sheet K is arranged at the lower second end of the stack. A layer composite 17 is stacked on the outer cathode sheet K of the lower first stack end, which is formed from a single anode sheet AE, around which a separator double sheet layer is folded. The individual anode sheet AE is therefore arranged on the lower cathode sheet K with a separator sheet S in between.

A mono-cell stack according to a further exemplary embodiment is shown in FIG. The mono-cell stack shown in FIG. 11 is constructed essentially identically to the mono-cell stack shown in FIG. 10. In contrast to FIG. 10, in FIG. 11 the anode-side and cathode-side arrester lugs 7, 9 protrude at right angles to the folded edges 11. The anode-side arrester lugs 9 protrude from the left side of the monocell stack, while the cathode-side arrester lugs 7 protrude from the right side of the monocell stack.

Reference symbol list

I mono cell

3 current conductor foil

5 electrode coating

7 Cathode-side arrester lug

9 Anode-side arrester lug

I I folded edge

13, 15 partial stacks

17 layer composite

M mono cell

A anode sheet

K cathode sheet

D Double sheet layer

S, S1, S2 separator sheets

Claims

Claims Mono cell stack for a battery cell, with a number of mono cells (M) stacked one above the other in the stacking direction, of which each mono cell (M) alternates in the stacking direction from an electrode sheet (K), a separator sheet (S1), a counter electrode sheet (A) and another Separator sheet (S2) is joined together, characterized in that the two separator sheets (S1, S2) are components of a double sheet layer (D) which is folded around the electrode sheet (K) in a U-fold along a fold edge (11), and that the counter electrode sheet (A) is arranged on the outside of one of the separator sheets (S1, S2). Mono-cell stack according to claim 1, characterized in that the mono-cell stack ends in the stacking direction at both stack ends with a counter-electrode sheet (A). Mono-cell stack according to claim 1 or 2, characterized in that the mono-cells (M) are stacked in the mono-cell stack with an identically repeating electrode-separator sheet sequence in the stacking direction, from a first stack end to the second stack end, and in particular at the first stack end end-side monocell (M) is arranged with an external counter-electrode sheet (A) and at the second end of the stack an end-side monocell (11) with an external separator sheet (S2) is arranged, and in particular that a single counter-electrode sheet (S2) is placed on the external separator sheet (S2) of the second stack end ( AE) is stacked. Mono-cell stack according to claim 3, characterized in that a single electrode sheet (AE) is stacked on the outer counter electrode sheet (K) of the first stack end, with the interposition of a separator sheet (S), and in particular the single electrode sheet (AE) and the separator sheet (S) is assembled before the stacking process to form a layer composite (17) which is stacked on the external counter electrode sheet (K). Mono-cell stack according to claim 1 or 2, characterized in that the mono-cell stack is divided into at least two sub-stacks (13, 15) in the stacking direction, that in the first sub-stack (13) and in the second sub-stack (15) the mono-cells (M) move in the stacking direction are stacked in an identically repeating electrode-separator sheet sequence, and the second sub-stack (15) is turned over by 180° relative to the first sub-stack (13), so that in the second sub-stack (15) the monocells (11) are stacked with the reverse electrode-separator sheet sequence that repeats itself identically in the stacking direction. Mono-cell stack according to claim 5, characterized in that the two sub-stacks (13, 15) lie opposite each other in the stacking direction, each with a separator sheet (S1) of the double sheet layer (D), with the interposition of a single counter electrode sheet (AE). Mono-cell stack according to one of the preceding claims, characterized in that the electrode sheets (K) and/or the counter-electrode sheets (A) are each formed from a current conductor film (3) with electrode coating (5) on both sides, and/or that the electrode sheets (K) and /or the counter electrode sheets (A) are each extended with laterally projecting arrester lugs (7, 9). Mono-cell stack according to one of the preceding claims, characterized in that the fold edges (11) of the double sheet layers (D) in the mono-cell stack, viewed in the stacking direction, are arranged alternately on opposite mono-cell stack sides, or are arranged on the same mono-cell stack side. Mono-cell stack according to claim 7 or 8, characterized in that the arrester lugs (7, 9) of the electrode sheets (K) and/or the counter-electrode sheets (A) protrude outwards parallel to the folded edges (11), or that the arrester lugs (7, 9 ) of the electrode sheets (A, K) protrude outwards on the side opposite the folded edge (11). Process arrangement or method for producing a mono-cell stack according to one of the preceding claims, with a cutting device in which the electrode sheet (K), the counter-electrode sheet (A) and the double sheet layer (D) are cut from web goods, a first laying device in which the electrode sheet ( K) is placed on the double sheet layer (D), a folding device in which the double sheet layer (D) is folded around the electrode sheet (K) along a fold edge (11) in a U-fold, a second laying device in which the counter electrode sheet ( A) is arranged on the outside on one of the separator sheets (S1, S2), a laminating device in which the electrode and separator sheets (S1, K, S2, A) form one Mono cell (M) are laminated, and a stacking device in which the mono cells (11) are stacked.