FR3127074A1 - Battery cell and method of charging a cell and its application - Google Patents

Abstract

TITLE: Battery cell and method of charging a cell and its application Battery cell comprising an electrode unit (10, 20), having a positive electrode (102), a negative electrode (104) and therebetween a separator (103). A heating element (108, 208) is applied to the electrode unit (10, 20) to heat one of the electrodes (102, 104, 204). Figure 1

Description

Battery cell and method of charging a cell and its application

FIELD OF THE INVENTION

The present invention relates to a battery cell comprising at least one electrode unit, having a positive electrode, a negative electrode and between these, a separator.

The invention also applies to a method for charging such a battery cell and to its application.

STATE OF THE ART

To implement electromobility, rechargeable batteries are again used to convert chemical energy into electrical energy several times over. Lithium-ion batteries are particularly suitable because of their relatively high energy density, their good thermal stability and their low self-discharge.

A lithium-ion battery generally comprises several battery modules. A battery module itself consists of several battery cells. A battery cell typically has a battery cell housing which receives at least one electrode unit in the form of an electrode coil or an electrode stack. The battery cell also contains an ion-conductive electrolyte. The electrolyte can be liquid or solid. Compared to a liquid electrolyte, a solid electrolyte has lower flammability and a lower risk of explosion. This safety feature allows a particularly suitable use of such battery cells with a solid electrolyte for electromobility.

Document DE 102018218646 A1 describes a battery cell whose housing contains a stack of electrodes; this electrode stack includes two separators that each have a solid electrolyte.

DESCRIPTION AND ADVANTAGES OF THE INVENTION

The present invention relates to a battery cell comprising at least one electrode unit, having a positive electrode, a negative electrode and a separator between them, this battery cell being characterized in that at least one heating element is applied to the electrode unit to heat one of the electrodes.

If one of the electrodes of this electrode unit comprises lithium metal (also called metallic lithium), there will be during the charging or discharging phase of the battery cell according to the invention, possibly an undesirable growth of dendrites at the boundary surface between this electrode and the neighboring separator; this can lead to a short circuit in the battery cell according to the invention. The cause is the needle-like structure of the lithium dendrites which thus can go from the lithium-metal electrode through the separator until reaching the other electrode of this electrode unit. Thus, the two electrodes of this electrode unit, which are generally of opposite polarity, come into contact with each other and cause a short circuit in the battery cell according to the invention. But as one of the electrodes is heated by a heating element according to the present invention, there will be a homogeneous deposit of metallic lithium. In this way, dendrites in the electrode unit and thus the short circuit in the battery cell according to the invention are avoided. The lifetime of the battery cell according to the invention is thus lengthened.

According to another characteristic, it is advantageous for the heating element to be of stratified form. Such an embodiment offers the advantage that this heating element occupies as little space as possible in the battery cell according to the invention and for this reason it does not deteriorate the volumetric energy density of the battery cell concerned by the existence of this heating element.

According to another advantageous characteristic, this heating element has a maximum thickness of 20 μm.

This characteristic guarantees that the volume energy density of the battery cell according to the invention is only slightly affected by the presence of the heating element.

According to another advantageous characteristic, at least one heating element comprises an electrically conductive material. A particularly suitable material is nickel.

Such a material is characterized by excellent thermal conductivity which means that one of the electrodes of this electrode unit of the battery cell according to the invention will be at the desired temperature in a relatively short time thanks to this heating element.

Alternatively, it is advantageous for the heating element to comprise an electrically insulating material. For this, a polymer is particularly suitable.

Such a material not only has good mechanical deformability, but also self-regulated heating properties. Thus, any additional control component for adjusting the temperature of the heating element and of the electrode to be heated of this electrode unit is avoided.

According to another advantageous characteristic, the heating element is applied to an electrically insulating element. Thus, the electrically insulating element is itself installed on the current conductor of one of the electrodes of at least one electrode unit.

In this way, the heating element is electrically isolated from the current conductor of one of the electrodes of this electrode unit in the event that the two components are made of an electrically conductive material.

Alternatively, it is advantageous if a heating element is applied to the negative electrode of this electrode unit. The negative electrode is thus, for example, made of lithium-metal and the heating element is made of a corrosion-resistant material such as, for example, nickel.

Thus, any intermediate layer between the negative electrode and the heating element is avoided. Thus, the electrode will be heated relatively quickly to the desired temperature.

It is particularly advantageous if the negative electrode of this electrode unit comprises lithium metal.

Since lithium metal has a very high specific capacity, this improves the gravimetric and at the same time volumetric energy density of the battery cell according to the invention.

According to another advantageous characteristic, the negative electrode of this electrode unit has a porous structure. The pores of this porous structure are at least partially filled with an inorganic ion-conducting material. The inorganic ion conductor includes, for example, a ceramic-based solid electrolyte.

Such a solution offers the advantage that the negative electrode has sufficient ionic conductivity. This ensures the continuous transport of ions from the negative electrode through the separator to the other electrode of this electrode unit. This prevents the growth of lithium dendrites in the battery cell according to the invention.

Particularly advantageously, the separator of the electrode unit has a solid electrolyte.

The separator is advantageously combined with a lithium-metal negative electrode. This results in a battery cell with reduced flammability and which, at the same time, guarantees better energy density both gravimetric and volumetric.

The invention also relates to the method of charging a battery cell.

Thus, an electrode of the electrode unit of the battery cell is heated by a heating element until a first predefined temperature is reached. The heating element is therefore applied to an electrode unit. Next, the battery cell is charged to pass an electric current through the battery cell. The battery cell is maintained at a second predefined temperature during this charging operation.

As the electrode of this electrode unit, for example, the negative electrode is made of lithium metal, it is heated before the actual charging operation of the battery cell and thus the charging capacity of the battery is improved. battery cell. For this, the battery cell is connected to a load unit and the heating element is first supplied with a load current and once the first predefined temperature has been reached, the same load current or a comparable load current passes through the electrode unit.

Advantageously, the first and second predefined temperatures are located in a range between 50°C and 80°C. The two temperatures are preferably equal to 60°C. This range of values represents an optimum window of operating temperatures for a battery cell according to the invention.

The battery cell according to the invention advantageously applies to an electric vehicle EV, to a hybrid vehicle HEV or to a rechargeable hybrid vehicle PHEV.

The present invention will be described below in more detail using a battery cell and its method of operation according to the invention shown in the accompanying drawings in which:

sectional view of an electrode unit comprising a heating element according to a first embodiment of the invention, and

sectional view of an electrode unit with a heating element according to a second embodiment of the invention.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

There shows a first embodiment of an electrode unit 10 comprising a heating element 108 of a battery cell according to the invention represented schematically.

The electrode unit 10 is, for example, in the form of a stack of electrodes and comprises a positive electrode 102 also called cathode, a separator 103 and a negative electrode 104 also called anode. The positive electrode 102 consists of an electrode active material 122 and a positive current conductor 112. The electrode active material 122 comprises, for example, lithium-cobalt oxide applied to the conductor. positive current 102 itself, for example, in the form of an aluminum film.

The negative electrode 104 comprises, for example, a negative electrode material 124 applied to a negative current conductor 114. The active negative electrode material 124 is, for example, graphite, amorphous carbon or their mixture, the copper is, for example, a suitable material for the negative current conductor 114.

To separate the positive electrode 102 from the negative electrode 104, there is a separator 103 between the two electrodes 102, 104. The separator 103 comprises, for example, an inorganic ion conductor, sintered, such as, such as, garnet or a sintered inorganic ion conductor such as, for example, sulfuric glass (or sulphide glass).

Between the negative current conductor 114 and the heating element 108 there is an intermediate layer 106, for example, in PTE (polyethylene terephthalate). The intermediate layer 106 is provided to electrically insulate the negative current conductor 114 with respect to the heating element 108. The heating element 108 is made of a metallic material such as nickel, steel or a nickel alloy. -chromium.

The electrode unit 10 and the heating element 108 are placed, for example, in a prismatic or film-like casing to form a battery cell.

There shows a second embodiment of an electrode unit 20 with a heating element 208 of a battery cell according to the invention represented schematically. The same references will be used to designate the same components as in .

The electrode unit 20 is, for example, formed of an electrode stack comprising a positive electrode 102 with a positive current conductor 112 and a positive electrode active material 122. The electrode unit 20 also includes a negative electrode 204, for example, lithium metal. It is not necessary to have a negative current conductor for the negative electrode 204. A separator 103 comprising a solid electrolyte is provided between the positive electrode 102 and the negative electrode 204.

Heating element 208 is applied directly to negative electrode 204. Heating element 208 comprises a rubber-based polymer having a positive temperature coefficient. Such a material is characterized by very good thermal conductivity.

The electrode unit 20 and the heating element 208 are placed in a prismatic case or a film-like case to form a battery cell. Several such battery cells can themselves be connected to form a battery module. When charging such a battery module, it is not necessary to supply charging current to all the heating elements; it suffices that only a few heating elements are brought to temperature and they thus heat the battery cells neighboring the electrodes.

The electrode units 10, 20 equipped with a respective heating element 108, 208 are advantageously used in lithium-ion batteries. These are used for e-bikes or motor vehicles as well as for stationary electrical energy storage.

NOMENCLATURE OF THE MAIN ELEMENTS

10 Electrode unit

20 Electrode unit

102 Positive electrode

103 Separator

104 Negative electrode

106 Intermediate layer

108 Heating element

112 Positive current conductor

114 Negative current conductor

122 Positive electrode active material

124 Negative electrode active material

204 Negative electrode

208 Heating element

Claims (12)

Battery cell comprising at least one electrode unit (10, 20),
this electrode unit (10, 20) having a positive electrode (102), a negative electrode (104) and between them a separator (103),
battery cell characterized in that
at least one heating element (108, 208) is applied to the electrode unit (10, 20) to heat one of the electrodes (102, 104, 204). Battery cell according to claim 1,
characterized in that
the heating element (108, 208) is of laminated type. Battery cell according to claim 2,
characterized in that
the heating element (108, 208) has a maximum thickness of 20 µm. Battery cell according to one of the preceding claims,
characterized in that
the heating element (108) has an electrically conductive material, preferably nickel or an electrically insulating material, preferably a polymer. Battery cell according to one of the preceding claims,
characterized in that
the heating element (108) is applied (106) to an electrically insulating element itself provided on a current conductor (114) of an electrode (102, 104) of this electrode unit (10). Battery cell according to one of Claims 1 to 4,
characterized in that
the heating element (208) is applied to the negative electrode (204) of the electrode unit (20). Battery cell according to claim 6,
characterized in that
the negative electrode of the electrode unit (20) comprises lithium metal. Battery cell according to one of the preceding claims,
characterized in that
the negative electrode (104, 204) of the electrode unit (10, 20) has a porous structure, the pores of which are at least partially filled with an inorganic ionic conductor. Battery cell according to one of the preceding claims,
characterized in that
the separator (103) of the electrode unit (10, 20) comprises a solid electrolyte. Method for charging a battery cell according to one of the preceding claims,
characterized in that
- an electrode (102, 104, 204) of at least one electrode unit (10, 20) of the battery cell is heated by means of a heating element (108, 208) to a first preset temperature,
* this heating element (108, 110) being applied to the electrode unit (10, 20), and
- the battery cell is charged so as to pass an electric current through the battery cell,
* the battery cell being maintained at a second predefined temperature during the charging operation. Method according to claim 10,
characterized in that
the first and second predefined temperatures are within a range of 50 to 80°C, preferably they are equal to 60°C. Application of a battery cell according to one of Claims 1 to 9 to an electric vehicle (EV), a hybrid vehicle (HEV) or a rechargeable hybrid vehicle (PHEV).