DE102016214337A1 - Solid battery - Google Patents

Abstract

A solid state battery (1) comprises at least one solid state cell (100) having an anode (110), a solid electrolyte layer (130) and a cathode (120) arranged in a stack. The solid electrolyte layer (130) is disposed as a separator between the anode (110) and the cathode (120). The solid state battery (1) further comprises a heatable layer (10) adapted to be heated at a current flow. The heatable layer (10) is arranged such that the heatable layer (10) delivers the heat generated during the current flow to the at least one solid state cell (100), so that the temperature of the solid electrolyte (130) increases.

Description

The invention relates to a solid-state battery, which can be used for example as a vehicle battery.

Batteries with a solid electrolyte, so-called solid-state batteries, or batteries with a liquid, organic electrolyte are used as drive batteries for vehicles. Lithium batteries containing a solid electrolyte offer an advantage over lithium batteries with conventional liquid organic electrolytes because it is non-flammable. Solid electrolytes have significantly improved safety characteristics as compared to conventional organic electrolytes, as they are not only non-flammable but also reduce lithium dentride growth. Furthermore, due to the selectivity of the carriers and the high stability of solid electrolytes in general, both the cycle stability and the calendar life of the battery are improved. In addition, a reduced self-discharge of the battery occurs.

The ionic conductivity of solid electrolytes almost reaches the conductivity of liquid electrolytes at room temperature. However, the ionic conductivity of most solid electrolytes is below that of liquid electrolytes. Due to the generally slightly lower conductivity of solid electrolytes and the increased interfacial resistances fixed-solid and the performance of the individual battery cells (solid state cells) of a solid state battery at room temperature is lower than, for example, the conductivity of lithium cells with liquid electrolytes.

Classic solid-state electrolytes have a linear dependence of the conductivity on the temperature. However, polymer solid electrolytes (polymer electrolytes) behave differently. They typically require temperatures greater than 35 ° C, and preferably greater than 45 ° C, to achieve the requisite lithium conductivity. Below its glass transition temperature, the lithium conductivity drops sharply, so that at room temperature and below no more suitable conductivity prevails.

A concern of the present invention is to provide a solid state battery in which the solid electrolyte has a high conductivity.

The object is achieved with a solid state battery according to claim 1. The solid state battery comprises at least one solid state cell having an anode, a solid electrolyte layer and a cathode. Anode, solid electrolyte layer and cathode are arranged in a stack. The solid electrolyte layer is disposed as a separator between the anode and the cathode. The solid-state battery according to the invention comprises a heatable layer, which is designed to heat at a current flow. The at least one heatable layer is arranged such that the heatable layer delivers the heat generated during the current flow to the at least one solid state cell, so that the temperature of the solid electrolyte increases.

By using a heatable layer within the solid-state battery, the ionic conductivity, in particular the lithium conductivity of the solid electrolyte even at low ambient temperature, for example at room temperature, below room temperature and / or below the glass transition temperature of the electrolyte, remain high or be maintained. As a heatable layer, for example, metal plates and / or (coated) films, which lead to a heating of the battery cell due to their resistance in a current transit to be used. The number and placement of these films or plates can be done depending on the cell type or type of material and application of the resulting cells.

For polymer batteries in which the solid electrolyte is a polymer, there are various possibilities for placing the heatable layer within the battery, since here the polymer forms a flexible unit in the cell. The heatable layer can be arranged, for example, as an arrester with increased resistance at the cathode or the anode. Furthermore, it is possible to embed the heatable layer, for example as a metal strip or as a metallic mesh, which heat at a current flow, in the polymer of the electrolyte. Another possibility is to arrange the heatable layer between the individual layers of a solid state cell of the solid state battery.

For solid-state batteries with classic solid-state electrolytes, however, the incorporation of the heatable layer into the cell is a challenge, since here the interfaces must be coordinated and there are no flexible parts in the cell. One possibility for introducing the heatable layer into the cell is to substitute the arresters arranged at the anode or the cathode for tapping a voltage, or to use these as a heatable layer.

The use of (at least) a heatable layer within a layer stack of the solid state battery or within a layer stack of a solid state cell of the battery allows the increase or Retention of the ionic conductivity of solid electrolytes, in particular of polymeric solid electrolyte, at low temperatures, for example temperatures below 40 ° C. In the case of polymer batteries, it is possible to increase or maintain the conductivity at an ambient temperature which is lower than the glass transition temperature (Tg) of the polymer electrolyte.

The invention will be explained in more detail below with reference to figures showing exemplary embodiments of the present invention. Show it:

1 a first embodiment of a solid state battery with high conductivity at low temperatures,

2A a second embodiment of a solid state battery with high conductivity at low temperatures,

2 B a third embodiment of a solid state battery with high conductivity at low temperatures.

3A and 3B a fourth embodiment of a high-conductivity solid-state battery at low temperatures with different interconnection of a heatable layer,

4A and 4B a fifth embodiment of a high-conductivity solid-state battery at low temperatures with different interconnection of a heatable layer,

5 a sixth embodiment of a high-conductivity solid-state battery at low temperatures,

6 Various embodiments of a stack arrangement of solid state cells of a solid state battery.

The 1 to 5 show various embodiments of a solid-state battery 1 with an increased ionic conductivity of the solid electrolyte at low temperatures, for example at temperatures below 40 ° C, or when using a polymeric solid electrolyte at temperatures below the glass transition temperature of the polymer electrolytes.

The in the 1 to 5 shown embodiments of a solid state battery 1 comprise at least one solid state cell 100 that is an anode 110 , a cathode 120 and a solid electrolyte 130 having. The anode 110 , the cathode 120 and the solid electrolyte layer 130 are arranged in a stack. The solid electrolyte layer 130 is as a separator between the anode 110 and the cathode 120 arranged.

An anode conductor layer 21 is in the stack electrically conductive to the anode layer 110 arranged. The anode conductor 21 is to the main surface of the anode layer 110 arranged adjacent, which of the solid electrolyte layer 130 and cathode layer 120 is averted. Further, in the stack is a cathode drainage layer 22 in an electrically conductive arrangement to the cathode layer 120 available. The cathode conductor 22 is to the main surface of the cathode layer 120 arranged adjacent, which of the solid electrolyte layer 130 and the anode layer 110 is averted.

Furthermore, the embodiments shown have the solid-state battery 1 (at least) a heatable layer 10 which is adapted to heat at a current flow. The heatable layer 10 is thermally coupled to the stack such that the heatable layer 10 the heat generated at the current flow to the solid state cell 100 gives off, so that the temperature of the electrolyte 130 the solid-state cell 100 elevated.

The in the 1 to 5 shown embodiments of the solid state battery have in addition to the solid state cell 100 at least one other solid-state cell 200 with an anode 210 , a cathode 220 and a solid electrolyte layer 230 between the anode 210 and the cathode 220 is arranged on. The cathode conductor 22 is between the cathode 120 the solid-state cell 100 and the cathode 220 the solid-state cell 200 arranged. The cathode conductor 22 the battery cell 100 is thus also used as a cathode conductor for the battery cell 200 used. The anode conductor 21 the solid-state cell 200 is on a the solid electrolyte 230 opposite side of the anode 210 arranged.

The 1 to 5 For the sake of simplicity, only the two solid-state cells are shown 100 and 200 which are arranged in the stack. The marked with a brace stack assembly from the solid state cell 100 and the other solid-state cell 200 However, as often as desired in the battery pack of the solid state battery 1 to be available.

1 shows a first embodiment of a solid-state battery 1 with at least one heatable layer 10 for heating the battery or the solid-state cell 100 , The heatable layer 10 can be used, for example, as an anode conductor 21 the cell 100 be educated. At the in 1 the embodiment shown is the anode conductor 21 on a first / upper side of the anode 110 and the Solid electrolyte layer 130 lies on a second / lower side of the anode 110 which is located opposite the first side. The heatable layer 10 can also be used as a cathode conductor 22 the solid-state cell 100 be educated. As in 1 is shown, the solid electrolyte layer 130 on a first / upper side of the cathode 120 and the cathode conductor 22 that is heatable layer 10 can act on a second / lower side of the cathode 120 which is disposed opposite to the first side of the cathode.

At the in 1 embodiment shown, the anode conductor 21 or the cathode conductor 22 an increased resistance. This means that the heatable layer 10 is formed as it were a consumer with an increased resistance, wherein the heatable layer / the consumer 10 at the same time is the arrester of the solid state cell. With a current flow, the anode conductor heats up 21 and / or the cathode conductor 22 and apply the heat generated at the current flow to the solid-state battery 1 or the solid-state cell 100 so that the temperature of the solid state battery / solid state cell and in particular the temperature of the solid electrolyte 130 the cell increases.

In the 1 shown embodiment of a solid-state battery is advantageously used in particular when the electrolyte is conventional solid electrolytes, for example, an electrolyte which has an ion-conducting, in particular lithium-ion-conducting, vitreous or ceramic material used. The solid electrolyte layer may comprise, for example, a solid electrolyte of the family of garnets or perovskites. The solid electrolyte layer may also comprise a material derived from the structure of LISICON (Lithium (LI) Super (S) Ionic (I) Conductor (CON)).

For such solid-state batteries with classic solid-state electrolyte, the incorporation of the heatable layer in the layer stack of the battery is a challenge, since here the interfaces must be coordinated and there are no flexible parts within the battery cell. This difficulty is determined according to the in 1 embodiment shown thereby solved by the arresters themselves are used wholly or at least partially as wärärmbare layers.

As discussed above, the stapled stack assembly can be made from the solid state cell 100 and the other solid-state cell 200 as often as desired in the layer stack of the solid-state battery 1 to be available. Each arrester can be considered a heatable layer 10 act or only every x-th arrester.

The 2A and 2 B each show a further embodiment of a solid-state battery 1 with the solid-state cell 100 and the other solid-state cell 200 , At the in 2A The embodiment shown is the heatable layer 10 as a consumer directly at the anode conductor 21 on one of the cells, for example 100 opposite side of the Anodenableiters 21 arranged. At the in 2 B shown embodiment of the solid state battery is the heatable layer 10 between the anode 110 and the anode conductor 21 arranged. The heatable layer 10 is designed to heat up at a current flow and heat to the solid state battery 1 / Solid cell 100 and in particular to the solid electrolyte 130 which increases the ionic conductivity of the solid electrolyte, especially at low ambient temperature. The heatable layer 10 is designed as a consumer with an increased resistance that heats up at a current flow.

The heatable layer 10 is in the two in the 2A and 2 B shown embodiments directly on the anode conductor 21 arranged. In the 2A and 2 B is the heatable layer 10 each one-sided, that is on an upper side or a lower side of the Anodenableiters 21 shown. However, other embodiments are possible in which the heatable layer 10 for example, on both sides to the anode conductor 21 or in the anode conductor 21 arranged itself.

The 3A and 3B show a further embodiment of a solid-state battery 1 with a high ionic conductivity of the solid electrolyte 130 the battery cell 100 especially at low ambient temperatures. The solid-state battery includes those already in the 1 and 2A respectively 2 B shown at least one solid state cell 100 and the at least one solid state cell 200 , In the in the 3A and 3B illustrated embodiment of the solid state battery is the heatable layer 10 between the anode 110 and the solid electrolyte layer 130 the solid-state cell 100 arranged. The heatable layer 10 represents a consumer who heats up at a current flow and the resulting heat to the Festelektrolytseparator 130 emits. The 3A and 3B show different possibilities of interconnection of the heatable layer 10 for heating the layer 10 , The heatable layer 10 may depend on the Festelektrolytart the solid electrolyte layer 130 be arranged on or in the solid electrolyte. Furthermore, the heatable layer can also be attached to the anode side of the anode facing the solid electrolyte 110 be arranged.

The 4A and 4B show another embodiment of the solid-state battery 1 Here, too, for the sake of simplicity, only the two solid-state cells 100 and 200 are shown. In the in the 4A and 4B shown embodiment of the solid state battery is the heatable layer 10 between the cathode 120 and the solid electrolyte layer 130 arranged. Similar to the one in the 3A and 3B In the embodiment shown, the heatable layer 10 depending on the type of solid electrolyte 130 be arranged on or in the solid electrolyte itself. In another embodiment, the heatable layer may be on the cathode side of the cathode facing the solid electrolyte 120 be arranged.

At a current flow, the heatable layer is heated 10 and gives the resulting heat to the solid state battery 1 or the solid-state cell 100 from. As a result, the solid electrolyte heats up 130 and thus maintains its conductivity even at low ambient temperatures. In the 4A and 4B are different ways of interconnecting the heatable layer 10 for generating a current flow through the layer 10 shown.

5 shows another possible embodiment of the solid state battery 1 comprising the at least one solid-state cell 100 and the at least one solid state cell 200 , At the in 5 shown embodiment of the solid state battery is the heatable layer 10 between the cathode 120 and the cathode conductor 22 arranged. The heatable layer 10 is designed to heat at a current flow and the resulting heat to the solid electrolyte 130 so that even at the in 5 shown embodiment of the solid state battery, the conductivity of the solid electrolyte 130 maintained at low temperatures.

The heatable layer used in 5 only on one side of the cathode arrester 22 is shown, according to further embodiments also on both sides of the Kathodenableiters 22 or in the cathode conductor 22 be arranged.

The use of in the 2A to 5 shown embodiments of a solid state battery are particularly useful when a polymeric solid electrolyte is used and the solid state battery is thus formed as a polymer battery. For example, polyethylene oxide, polyacrylonitrile and silicone based polymer electrolytes are suitable. Since the polymer is a flexible unit, resulting in the 2A to 5 shown various possibilities of placement of the heatable layer 10 within a solid state cell.

For polymer batteries as well as solid state batteries with classic solid state electrolytes it is also possible to use the heatable layer 10 to arrange between the individual solid-state cells. Since the cells have intrinsically increased safety, pouch bags can be used, which can have improved heat transfer compared to hard-case cells, provide increased specific energy or energy density and also have a more flexible form factor.

In the 2A to 5 are different ways of interconnecting the heatable layer 10 for generating a current flow through the heatable layer 10 shown. By a leifähige connection between the anode conductor 21 and the cathode conductor 22 the solid-state cell 100 becomes a current flow through the heatable layer 10 generated by that of the battery 1 self-generated voltage is caused. In the 2A to 5 is shown in broken lines or an alternative current guidance in the heating phase, in which the current from the cell is passed through the heatable layer with the defined resistance. To generate the current flow is the heatable layer 10 according to the in 2A . 2 B . 3A . 4A and 5 shown embodiments of an external power / voltage source 30 connected. The 3B and 4B show an interconnection of the heatable layer 10 in which the flow of current through the layer 10 from the solid state cell 100 provided voltage itself is caused.

6 shows various embodiments, such as the individual solid state cells within the layer stack of the solid state battery 1 can be interconnected with each other. The layer stack of the at least one solid-state cell 100 and the at least one solid state cell 200 can as in the left picture of the 6 is shown in parallel or, as in the right image of the 6 is shown to be serially constructed. In the serial structure of the layer stack of the battery is between the anode 110 the solid-state cell 100 and the cathode 220 the solid-state cell 200 an electrically insulating separating layer 40 arranged. The use of a heatable layer 10 for heating the solid state battery, as in the 1 to 5 is shown by way of example, is independent of a parallel or serial structure of the layer stack of the battery.

LIST OF REFERENCE NUMBERS

1

Solid battery

10

heatable layer

21

anode conductor

22

cathode conductor

30

Current / voltage source

40

electrically insulating separating layer

100

 Solid-state cell

110

Anode of the solid-state cell 100

120

Cathode of the solid-state cell 100

130

Solid electrolyte of the solid-state cell 100

200

 Solid-state cell

210

Anode of the solid-state cell 200

220

Cathode of the solid-state cell 200

230

Solid electrolyte layer of the solid-state cell 200

Claims (13)

A solid-state battery, comprising: - at least one solid-state cell ( 100 ), which is an anode ( 110 ), a solid electrolyte layer ( 130 ), and a cathode ( 120 ), which are arranged in a stack, wherein the solid electrolyte layer ( 130 ) as a separator between the anode ( 110 ) and the cathode ( 120 ), - a heatable layer ( 10 ), which is adapted to heat at a current flow, - wherein the heatable layer ( 10 ) is arranged such that the heatable layer ( 10 ) the heat generated at the current flow to the at least one solid state cell ( 100 ), so that the temperature of the solid electrolyte ( 130 ) elevated. Solid state battery according to claim 1, - wherein the heatable layer ( 130 ) as an anode conductor ( 21 ), - wherein the anode conductor ( 21 ) on a first side of the anode ( 110 ) and the solid electrolyte layer ( 130 ) on a second side of the anode opposite the first side ( 110 ) is arranged. Solid state battery according to claim 1, - wherein the heatable layer ( 10 ) as a cathode conductor ( 22 ), - wherein the solid electrolyte layer ( 130 ) on a first side of the cathode ( 120 ) and the cathode conductor ( 22 ) on a second side of the cathode opposite the first side ( 120 ) is arranged. A solid-state battery according to claim 1, comprising: - an anode conductor ( 21 ), - wherein the anode conductor ( 21 ) on a first side of the anode and the solid electrolyte layer ( 130 ) on a second side of the anode opposite the first side ( 110 ), wherein the heatable layer ( 10 ) between the anode ( 110 ) and the anode conductor ( 21 ) is arranged. Solid state battery according to claim 1, comprising: - a cathode arrester ( 22 ), - wherein the solid electrolyte layer ( 130 ) on a first side of the cathode ( 120 ) and the cathode conductor ( 22 ) on a second side of the cathode opposite the first side ( 120 ), wherein the heatable layer ( 10 ) between the cathode ( 120 ) and the cathode conductor ( 22 ) is arranged. A solid-state battery according to claim 1, wherein the heatable layer ( 10 ) between the anode ( 110 ) and the solid electrolyte layer ( 130 ) is arranged. A solid-state battery according to claim 1, wherein the heatable layer ( 10 ) between the cathode ( 120 ) and the solid electrolyte layer ( 130 ) is arranged. A solid-state battery according to claim 1, wherein the heatable layer ( 10 ) in the solid electrolyte layer ( 130 ) is arranged. Solid state battery according to one of claims 1 to 8, wherein the solid electrolyte layer ( 130 ) is formed as a polymer electrolyte. A solid-state battery according to any one of claims 4 to 9, wherein the heatable layer ( 10 ) is formed as a metallic plate or as a foil with a conductive coating. A solid-state battery according to any one of claims 1 to 10, wherein the heatable layer ( 10 ) is connected such that the current flow through the heatable layer ( 10 ) from that of the battery ( 1 ) generated voltage. A solid-state battery according to any one of claims 1 to 11, wherein the heatable layer ( 10 ) to an external power source ( 30 ) for generating the current flow through the heatable layer ( 10 ) connected. Solid state battery according to one of claims 1 to 12, comprising: - at least one further solid state cell ( 200 ), which is an anode ( 210 ), a solid electrolyte layer ( 230 ), and a cathode ( 220 ), which are arranged in a stack, wherein the solid electrolyte layer ( 230 ) as a separator between the anode ( 210 ) and the cathode ( 220 ), wherein the at least one solid-state cell ( 100 ) and the at least one further solid-state cell ( 200 ) are stacked such that the solid state cell ( 100 ) and the further solid-state cell ( 200 ) are connected in parallel or in series with each other.

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