EP4275240A1 - Computer-supported method for analyzing an electrode layer of a battery cell using a ki engine, method for training a ki engine, method for producing a battery storage device, and production unit - Google Patents

Abstract

The invention relates to a computer-supported method for analyzing an electrode paste and/or an electrode layer for a battery cell, said method having multiple steps. First, at least one measuring device is provided for measuring a property of the electrode layer paste and/or the electrode layer during a production method. A property of the electrode layer paste and/or the electrode layer is measured, and measurement data is generated by means of the measuring device. A KI engine is provided. A quality value of the electrode layer paste and/or the electrode layer is ascertained by means of the KI engine. In order to train a KI engine, the electrode layer is introduced into a battery cell after measuring the property, the battery cell is started up, and operating data of the battery cell is ascertained. The operating data is correlated with the property of the electrode layer paste and/or the electrode layer.

Description

description

Computer-assisted method for analyzing an electrode layer of a battery cell using an AI engine, method for training an AI engine, manufacturing method of a battery storage unit and manufacturing unit

The invention relates to a method for analyzing an electrode layer paste and/or an electrode layer, a method for training an AI engine, a manufacturing method for a battery storage device, a manufacturing unit and a computer program product.

Lithium-ion accumulators, also referred to below as lithium-ion batteries, are used as energy storage devices in mobile and stationary applications due to their high power density and energy density.

A lithium-ion battery typically includes multiple battery cells. A battery cell, in particular a lithium-ion battery cell, includes a large number of layers. Typically, these layers include anodes, cathodes, separators, and other elements. These layers can be designed as a stack or as windings.

The electrodes usually include metal foils, in particular including copper and/or aluminum, which are coated with an active material. A paste containing lithium compounds or carbon, known as a slurry, is typically applied as the active material. The films and the coating each have a thickness of a few microns. Even a few micrometer deviations in the thickness of the coating or in the material composition have negative effects on the quality of the electrode. In the case of irregular coating, the disadvantage is that battery cells of inferior quality are produced. Furthermore, safe operation of the battery cell is disadvantageously not ensured. In the current state of the art, defective coatings can often only be carried out after the entire production process of the battery cell has been completed as part of a so-called end-of-line test. In some cases, faulty coatings are only discovered after the battery cell has been in operation for several years.

The disadvantage is that a large proportion of defective battery cells are rejected during battery production. The production process therefore has a large material and energy requirement in order to produce a sufficient quantity of high-quality battery cells.

It is therefore an object of the present invention to provide a method for analysis during a manufacturing process, a manufacturing method for a battery storage device, a manufacturing unit and a computer program product which reduce a reject rate in battery manufacture.

The object is achieved according to the invention with a method for analyzing an electrode layer paste and/or an electrode layer according to claim 1, a method for training an AI engine according to claim 9, a manufacturing method for a battery storage unit according to claim 12, a manufacturing unit according to claim 13 and a computer program product according to claim 15 solved.

The computer-aided method according to the invention for analyzing an electrode layer paste and/or an electrode layer for a battery cell comprises several steps. First, at least one measuring device is provided for measuring a property of the electrode layer paste and/or the electrode layer during a manufacturing process. The property of the electrode layer paste and/or the electrode layer is measured by means of the measuring device and measurement data are generated. Further will provided an AI engine. Using the AI engine, a quality value of the electrode layer paste and/or the electrode layer is determined based on the measurement data.

In a method according to the invention for training the AI engine, the electrode layer is introduced into a battery cell after the property has been measured. The battery cell is put into operation. Operating data of the battery cell are determined. The operating data of the battery cell are correlated with the property of the electrode layer and/or the electrode layer paste. The quality value is determined based on this correlation.

The manufacturing method according to the invention for a battery storage comprises several steps. First, the analysis of an electrode layer paste and/or an electrode layer for a battery cell of the battery storage takes place according to the inventive method for analyzing the electrode layer. A manufacturing condition for manufacturing the electrode layer is adjusted based on at least one quality value.

The manufacturing method according to the invention for a battery storage comprises several steps. First, the analysis of an electrode layer for the battery storage takes place according to the inventive method for analyzing the electrode layer. The AI engine used in the computer-assisted method for analysis was trained in particular according to the method for training the AI engine according to the invention. A manufacturing condition for manufacturing the electrode layer is adapted based on at least one first quality value.

The production unit according to the invention for producing a battery store comprises an electrode layer production device with a measuring device and with an AI engine, which is set up to carry out the method for analysis according to the invention. The computer program product according to the invention can be loaded directly into a memory of a programmable computing unit, comprises program code means in order to carry out the method according to the invention for analysis when the computer program product is executed in the computing unit.

In connection with the patent application, an AI engine can be understood to mean a computer system that includes an "application", i.e. an executable file or a program library, which uses artificial intelligence (AI) to learn, in particular, how to correlate different input data.

The AI engine has an execution environment. In connection with the patent application, an execution environment can be understood as a virtual machine, for example a Java Virtual Machine, a processor or an operating system environment. The execution environment can be implemented on a physical computing unit (processor, microcontroller, CPU, CPU core). The application can be executed in a learning mode and in an execution mode on the same physical processing unit. It is also possible, for example, for the application to be executed in a learning mode in another physical computing unit. For example, the training can take place in a special training processing unit. Execution in an execution mode takes place, for example, in a second arithmetic unit, the validity information determined during training being used during execution in the execution arithmetic unit. The validity information ascertained, for example, by the training processing unit is preferably provided in a manipulation-protected manner.

Electrode layer paste (slurry) is understood as meaning the raw substance for producing the electrode layer. The method according to the invention for analyzing an electrode layer of a battery storage device records at least one property of the electrode layer paste and/or the electrode layer by means of the measuring device during production. In other words, the electrode layer paste and/or the electrode layer is analyzed online, ie without having to physically intervene directly in the electrode layer.

Advantageously, the quality value is not only determined based on individual limit values for individual production steps, in particular the application of the electrode layer to a substrate and/or the electrode layer properties, but operating values of the fully manufactured battery cells are advantageously included in the evaluation of the quality value . In other words, as an alternative or in addition to limit values, which individual production steps are specified, the quality value also includes whether the analyzed properties of the electrode layer paste and/or the electrode layer are related to high-quality operating data. In particular, during the training of the AI engine, not only a limit value for a named property is observed, but rather the interaction of the individual properties and the sequence on the operating data is analyzed.

In other words, the measurement data and an evaluation of the measurement data based on a correlation of the measurement data with the operating data go into the quality value.

Operating data is understood to mean, in particular, idle or operating voltage, current, internal resistance and/or capacity of the battery during operation. In other words, operating data can represent a second quality value.

These relationships can be surprising for the person skilled in the art. It is possible that limit values for individual production steps are exceeded, but the quality value is still good enough. It is also possible that the individual production steps are within specified limits, but the quality value is still assessed as insufficient, since small deviations from one production step add up to the next production step. This is advantageously possible by training the AI engine to determine the quality value early in the manufacturing process when the trained AI engine is used in a manufacturing process for analysis of the electrode layer paste and/or electrode layer. It is thus advantageously possible to identify at an early stage when the quality of the electrode layer is deteriorating.

It is also advantageously possible to determine information which goes beyond an output of "electrode layer is OK" or "electrode layer is defective". It is thus advantageously possible to assess whether the electrode layer is of sufficiently good quality to be installed in a battery cell. Furthermore, the deviating quality value can be used to determine which of the production conditions are advantageously to be adapted in order to improve the quality of the electrode layer.

In an advantageous embodiment and development of the invention, at least two measuring devices are used and a first property of the electrode layer paste and/or the electrode layer is determined with a first measuring device and a second property of the electrode layer paste and/or the electrode layer is determined with a second measuring device Electrode layer determined. A larger number of different measured values are thus advantageously included in the determination of the quality value. This advantageously enables a determination of the quality value that is more robust and reliable.

In a further advantageous refinement and development of the invention, location information is assigned to the first property and the second property during measurement. net. A comparative value is determined at one location. The comparison value is included in the AI engine's correlation determination during training. In this way, information about exactly one location on the electrode layer can be brought together. In particular, it is thus possible to draw conclusions about the shape of holes or cracks in the electrode layer. In turn, it is advantageously possible, on the basis of the shape of holes or cracks, to be able to deduce possible incorrectly set production devices, in particular devices for applying the electrode layer paste to a carrier substrate. Advantageously, these erroneously set production devices can then be corrected.

In a further advantageous embodiment and development of the invention, the AI engine is trained using deep learning methods to classify the first quality value into quality classes and to assign a location of the electrode layer to a quality class. It is thus advantageously possible to analyze the electrode layer in a spatially resolved manner. Advantageously, a qualitatively inferior section of the electrode layer can then be deliberately discarded. Advantageously, an inferior electrode layer is not built into one battery cell, which would then function unreliably and lead to rejects.

In a further advantageous embodiment and development of the invention, a laser scanning device is used as the measuring device for determining a topological property as a property of the electrode layer. An image of the electrode layer is thus recorded with a laser scanning device. Based on the image information, topological properties of the electrode layer are determined. Correlation of the topological properties of the electrode layers with the operating data of the battery cell advantageously enables the electrode layer to be evaluated during the manufacturing process. In a further advantageous embodiment and development of the invention, a porosity measuring device, in particular an ultrasonic measuring unit or a computer tomograph, is used as a measuring device for measuring a porosity value of the electrode layer.

By analyzing the topological properties of the electrode layer, analyzing the porosity of the electrode layer and/or using a combination of both measuring methods, with the measured values then being determined in a spatially resolved manner at the same location, it is possible to analyze whether cracks in the Electrode layer are present and if so, whether these cracks correlate with a particular low coating thickness and / or high porosity. It is therefore advantageously possible to determine information which goes beyond an output of "electrode layer is OK" or "electrode layer is defective". Advantageously, it can also be assessed in this way whether the electrode layer is of sufficiently good quality to be installed in a battery cell. Furthermore, on the basis of the first quality value, it is possible to draw advantageous conclusions about possible faulty production process steps.

In an advantageous embodiment and development of the invention, a relief value is determined for at least two locations in the electrode layer based on a comparison value and at least one property of the electrode layer paste and/or electrode layer. Based on this, at least one shape of at least one indentation and/or number of indentations is determined based on the at least one relief value. It is thus advantageously possible to analyze whether there are cracks, punctiform holes or fluctuations in the coating thickness in the electrode layer. The electrode layer can thus advantageously be analyzed in a very differentiated manner during the production process. Based on this information, it can be advantageously assessed at an early stage whether the electrode layer is of sufficiently high quality to be divided into one install battery cell. In other words, the first quality value also includes how the shape of the depressions is structured, with the different shapes being evaluated with regard to an influence on the quality of the electrode layer, in particular by means of tolerance limit values.

In a further advantageous embodiment and development of the invention, an ultrasound measuring unit or an X-ray-based measuring method, in particular a computer tomograph, is used as the porosity measuring device. Advantageously, the porosity can be determined without contact during the manufacturing process by means of this measuring method. It is also possible to use X-ray methods to determine a structure of the electrode layer after the production process in order to verify the structure that was measured using optical methods.

In a further advantageous embodiment and development of the invention, a hyperspectral camera and/or a dielectric spectroscopy unit are used as a measuring device. Using the hyperspectral camera, based on the image data, in particular a chemical composition of the electrode layer can be determined as a property, using the dielectric spectroscopy unit, dielectric properties in particular can be determined as a property.

In a further advantageous embodiment and development of the invention, a first quality value, in particular a degree of mixing, a relief value and/or a crack value of the electrode layer, is determined as the quality value. Before geous these sizes reflect a quality of the electrode layer.

In a further full embodiment and development of the invention, a second quality value is used as the quality value, in particular an aging behavior, a capacity, an open-circuit voltage, an operating voltage and/or an internal resistance of the battery cell and/or the battery store with the battery cell. In other words, the battery data, which are determined as operating data by means of measurements, are regarded as a second quality value.

In a further advantageous embodiment and development of the invention, a porosity and/or a pore density and/or a pore distribution and/or a pore volume is determined as the porosity value. It is thus possible to evaluate the porosity based on different methods and to combine these results if necessary.

In a further advantageous embodiment and further development of the invention, temperature of the solutions and/or temperatures of the surroundings, proportion of solvent in the raw electrode solution for the electrode layer and/or the degree of mixing of the raw electrode solution are adjusted as production conditions. An adaptation takes place in such a way that the first quality value and/or the second quality value is improved.

Further features, properties and advantages of the present invention result from the following description with reference to the enclosed figures. It shows schematically:

FIG. 1 shows a production unit with an electrode layer production device with a laser scanning device, a porosity measuring device and an AI engine;

FIG. 2 shows an electrode layer production device and two battery cells;

FIG. 3 shows a process diagram for analyzing an electrode layer for a battery cell. Figure 1 shows a production unit 1. The production unit 1 comprises an electrode layer production device 8. The electrode layer production device 8 comprises two measuring devices: a laser scanning device 5 as a first measuring device and a porosity measuring device 9 as a second measuring device. It also includes an AI Engine 111. 100. The AI engine 111 is connected to the laser scanning device 5 and the porosity measuring device 9 via a data cable. The electrode layer production device 8 comprises a carrier substrate 3 to which an electrode layer 4 made of an electrode layer paste 2 (slurry) is applied. The electrode layer paste 2 is homogenized in a container using an agitator 7 .

The agitator 7 and the substrate transport are also connected to the AI engine 111 via a data cable.

In this example, at least one image of the electrode layer 4 and location information E1 are recorded with the laser scanning device 5 as a property. Furthermore, the porosity measuring device 9 is used to determine a second property, namely a porosity and/or an electrode layer thickness of the electrode layer 4 . In this example, the analysis takes place at the same point on the electrode layer 4 after the substrate with the electrode layer 4 has been transported on, now labeled with the location information E1'. The porosity is analyzed during the production of the electrode layer 4. The porosity measuring device is then designed in particular as an ultrasonic measuring unit, as an X-ray absorption unit or as a computer tomograph.

In this example, the measurement data is transmitted to the AI engine 111 . The topological properties of the electrode layer 4 are then determined in the AI engine 111 based on at least one image as a function of the location information El. The topological properties, in other words a three-dimensional image of the electrode layer surface, are then compared with the porosity value and/or the electro- compared to the layer thickness at this location. Based on the comparison, a comparison value is determined in this example. However, it is also possible to consider the two properties separately.

A first quality value of the electrode layer is determined based on this comparison value. In particular, a degree of mixing of the electrode layer 4 or a roughness of the electrode layer 4 is determined as the first quality value.

The quality value is determined using the AI engine 111, as shown in FIG. An example is the AI engine 111, a computer system with a computing unit 100.

The AI engine 111 is trained using operating data from battery cells 50 into which the electrode layers 4 were introduced: the quality value is determined based on the operating data. The AI engine 111 is trained to correlate the operating data with the individual properties, in this example the porosity and the topological property, and/or with the comparison value and to determine a quality value.

This quality value can provide information about the production process in particular. In particular, it is possible to analyze how disturbances are distributed relative to one another and what their position is in relation to one another. In particular, it can be analyzed whether cracks are particularly common in the area of low coating thicknesses. Furthermore, it can be analyzed in particular whether the porosity is high when a large number of holes are limited to a local position of the electrode layer. In the latter case, the coating equipment may need to be readjusted.

To train the AI engine 111, an additional determination of the porosity can also be carried out. In particular, an external porosity determination, in particular by means of optical methods from sectional images or gas porosimetries, be performed. The results of this porosity determination can be compared with the results of the online method of porosity determination. Furthermore, additional information about the electrode layer 4, in particular conclusions about the internal structure, such as a grain size distribution or grain boundaries, can be determined.

By using the trained AI engine, it is possible to determine a quality value based on individual properties or based on the comparison value, which is determined based on the image data of the laser scanning device, the porosity and/or the electrode layer thickness. Advantageously, operating data from battery stores can also be incorporated without each electrode layer having to be built into a battery cell.

Furthermore, porosity values that were measured offline can advantageously be correlated with porosity values that were measured online in order to further optimize an evaluation of the electrode layer 4 using the AI engine. In other words, based on the comparison value, statements can also be made about the internal structure of the electrode layer 4, in particular about grain size distributions or grain boundaries, without having to carry out an offline determination of the porosity again.

Based on this quality value, production conditions of the production unit 1 can now be adapted, as already shown in the first exemplary embodiment. In this example, the agitator 7 of the electrode raw solution 2 is adjusted using a second control signal 102 and/or the running speed of the electrode substrate 3 is adjusted using a first control signal 101 .

Figure 3 schematically shows the method for analyzing an electrode layer paste 2 and/or an electrode layer 4 of a battery cell 50 in an electrode layer production device 1. In a first step S1, at least one measuring device for measuring a property of an electrode layer paste 2 and/or an electrode layer 4 is provided. In a second step S2, the property of the electrode layer paste 2 and/or the electrode layer is measured and measurement data are generated by means of the measurement device.

In a third step S3, an AI engine 111 is provided. In a fourth step S4, a first quality value of the electrode layer paste 2 and/or the electrode layer 4 is determined using the AI engine. The AI engine is trained in a fifth step S5. For this purpose, in a sixth step S6, the electrode layer is introduced into a battery cell after the property has been measured. The battery cell is put into operation and the operating data is determined. In a seventh step S7, the operating data are correlated with the property of the electrode layer paste 2 and/or the electrode layer 4.

The first quality value of the electrode layer 4 can then be determined by means of the trained AI engine 111 as a function of the comparison value, without the electrode layer 4 having to be installed in a battery cell 50 .

In another example, not shown in the figures, the manufacturing unit includes an electrode layer manufacturing device, a hyperspectral camera as a measurement sensor, and an AI engine. The electrode layer production device comprises a carrier substrate onto which an electrode layer made of an electrode layer paste (slurry) is applied. The electrode layer paste is homogenized in a container using an agitator.

The hyperspectral camera records an image with at least two pixels of the electrode layer. The two pixels lie at locations adjacent to one another. Based on the Pixels, a material property of the electrode layer can be determined using the AI engine. In this example, the material composition is evaluated as a material property based on the image data. The material compositions, which were determined at the two neighboring locations, are combined to form a comparative value. This comparison value can in particular be a concentration gradient of a defined material composition and/or a concentration gradient of a defined component of the electrode layer paste, also known as the raw electrode solution. A characteristic property can then be determined on the basis of this comparison value. A characteristic property in this example is a material composition gradient. In particular, a material homogeneity value can also be determined based on this material composition gradient.

In this example, too, the AI engine was trained using operating data from the battery cell into which the electrode layers were placed. A quality value can be determined based on the operating data, with the AI engine being trained to correlate the quality value with the characteristic property.

Thus, by using the trained AI engine, it is possible to determine a quality value based on the characteristic property, which is analyzed using the hyperspectral camera and the recorded image. Based on this quality value, crafting conditions of the crafting unit can now be adjusted. In this example, the agitator of the electrode layer paste is adjusted using a second control signal and/or the running speed of the electrode substrate is adjusted using a first control signal.

Furthermore, it is possible to determine material composition gradients and/or layer thicknesses by comparing the adjacent images. Advantageously can based This evaluation can be used to determine where defects, such as cracks and/or inclusions in particular, are present in the electrode layer.

In a further exemplary embodiment of the invention, which is not shown in the drawings, two dielectric spectroscopy units are arranged in the production unit as measuring devices. The manufacturing unit includes an electrode layer manufacturing facility and an AI engine. The electrode layer production device comprises a carrier substrate onto which an electrode layer made of an electrode layer paste (slurry) is applied. The electrode layer paste for the electrode layer is homogenized in a mixing container using an agitator.

A first dielectric spectroscopy unit is arranged in the mixing container. In this example, the first dielectric spectroscopy unit is located at the edge of the mixing vessel. Alternatively, it is also conceivable to arrange the dielectric spectroscopy unit centrally in the mixing container or in places such as the dead spaces in the corners of the mixing container.

The electrode layer paste is applied to the carrier substrate via a first line. In this example, a second dielectric spectroscopy unit is arranged in the first line. This ensures that the entire electrode layer paste is analyzed before it is applied to the carrier substrate.

The measurement data determined is transmitted to the AI engine via data lines. A first quality value, which in particular describes the conductivity or the homogeneity of the electrode layer paste, is determined in the AI engine.

The AI engine is trained using operating data from battery cells into which the electrode layers have been placed. ned. The quality value can be determined based on the operating data. For this purpose, the operating data are combined with the electrical properties of the electrode layer paste or the electrical properties over time to form a comparative value. The AI engine then assigns a quality value to the comparison value. In other words, the AI engine can make statements about the quality of the dielectric properties, such as conductivity or the homogeneity value of the electrode layer paste, after it has been trained with operating data from battery cells (or battery storage systems that include the battery cells).

It is thus advantageously possible, by using the AI engine, to be able to make statements about the quality of the electrode layer and/or the later quality of the battery cells at a very early stage, namely during the manufacturing process. As a result of the analysis, it is then possible to intervene in the manufacturing process. Alternatively or additionally, it is possible to discard electrode layers that were produced from the electrode layer paste and do not meet the requirements for the first and/or second quality value, in order to minimize battery cell rejects.

Advantageously, operating data from battery cells can also be included in the determination of the first quality value, without each electrode layer having to be built into a battery cell.

The selection of technical parameters of the dielectric spectroscopy unit, such as accommodating the sensor in electrically insulating protective elements, the use of different measuring frequencies, or the choice of the electrode shape, can enable measurement of different technical properties of the slurry to be examined. In particular, the electrical insulation of the electrodes of the spectroscopy unit allows the use of a conductive medium about Furthermore, the variation of the measurement frequency of the dielectric spectroscopy unit allows a measurement that is comparable to electroimpedance spectroscopy in certain frequency ranges. A response of the system to be measured to electrical vibration excitation at different frequencies is analyzed for both sensors. In electroimpedance spectroscopy, however, the complete impedance, ie including the electrical conductivity, of a finished battery cell is typically determined in the prior art.

Advantageously, when measuring the slurry with the electrical spectroscopy unit, as shown in this first example, a change in the dielectric properties of the electrode layer paste is already determined during the production process. Advantageously, the manufacturing conditions can still be changed in this case.

By using the dielectric spectroscopy unit, it can also be determined whether the materials in the raw suspension were not only mixed, but also mechanically damaged. Depending on the selected measuring frequency of the spectroscopy unit, this can result in a change in the excitation response, i.e. the electrical properties of the raw suspension.

The measurement units laser scan unit, porosimetry unit, hyperspectral camera and the electrical spectroscopy unit mentioned in the examples can also be used in a production unit and all of them provide measurement data for an AI engine. This advantageously increases the robustness of the evaluation of the first quality value of the electrode layer.

Although the invention has been illustrated and described in detail by way of the preferred embodiment, the invention is not limited by the disclosed examples. Variations hereof can be deduced by a person skilled in the art without departing from the scope of the invention as defined by the following claims.

5

Reference List

1 crafting unit

2 Electrode layer paste (slurry)

3 carrier substrate

4 electrode layer

5 Laser Scan Setup

7 agitator

8 Electrode layer manufacturing device

9 porosity measuring device

50 battery cell

100 units of account

101 first control signal

102 second control signal

103 operational data

111 AI engine

51 Providing at least one measuring device for measuring a property of an electrode layer paste and/or an electrode layer

52 measuring the property of the electrode layer paste and/or the electrode layer and generating measurement data by means of the measuring device

53 Deploying an AI engine

54 Determination of a first quality value of the electrode layer paste and/or the electrode layer using the AI engine

55 Training the AI Engine

56 Insertion of the electrode layer into a battery cell after the measurement, commissioning of the battery cell and determination of operating data

57 Correlating the operational data with the property of the electrode layer paste and/or the electrode layer

Claims

patent claims

1. Computer-assisted method for analyzing an electrode paste and/or an electrode layer (4) for a battery cell (50) with the following steps:

- Providing at least one measuring device for measuring a property of the electrode layer paste (2) and/or the electrode layer (4) during a manufacturing process,

- measuring the property of the electrode layer paste (2) and/or the electrode layer (4) and generating measurement data by means of the measuring device,

- providing an AI engine (111),

- Determining a quality value of the electrode layer paste (2) and/or the electrode layer (4) using the AI engine (111) based on the measurement data.

2. Computer-aided method according to claim 1, wherein at least two measuring devices are used and a first property of the electrode layer paste (2) and/or the electrode layer (4) is determined with a first measuring device and with a second measuring device second property of the electrode layer paste (2) and/or the electrode layer (4) is determined.

3. Computer-assisted method according to one of the preceding claims, wherein a first quality value is determined as a degree of mixing, a relief value, a porosity and/or a crack value of the electrode layer (4) as the quality value.

4. Computer-aided method according to claim 3, wherein a relief value is determined at at least two locations of the electrode layer (4) and based thereon a shape of at least one indentation and/or number of indentations in the electrode layer (4) is determined.

5. Computer-aided method according to one of the preceding claims, wherein a second quality value is determined as an aging behavior, a capacity, an operating voltage, an open-circuit voltage and/or an internal resistance of the battery cell (50) as the quality value.

6. Computer-aided method according to one of the preceding claims, wherein a laser scanning device (5) for determining a topological property as a property of the electrode layer (4) is used as the measuring device.

7. Computer-supported method according to one of the preceding claims, wherein a porosity measuring device (9), in particular an ultrasonic measuring unit, an X-ray method or a computer tomograph, is used as the measuring device for measuring a porosity value of the electrode layer (4).

8. Computer-aided method according to one of claims 3 to 7, wherein a porosity and/or a pore density and/or a pore distribution and/or a pore volume is determined as the porosity value.

9. Computer-aided method for training an AI engine for performing the method according to any one of claims 1 to 8, wherein for training the AI engine (111):

- the electrode layer (4) is introduced into a battery cell (50) after the property has been measured,

- the battery cell (50) is put into operation,

- Operating data of the battery cell (50) are determined, these operating data with the property of the electrode layer paste (2) and/or the electrode layer (4) are correlated to who.

10. The computer-aided method as claimed in claim 9, wherein two properties of the electrode layer are determined and location information and a comparison value are assigned to the first property and the second property during measurement is determined at a location (El), the comparison value being included in the correlation determination of the AI engine during training.

11. Computer-aided method according to one of claims 9 or 10, wherein the AI engine (111) is trained using deep learning methods, an evaluation of the electrode layer

(4) to carry out, the quality value being divided into quality classes and a quality class being assigned to a location on the electrode layer (4).

12. Manufacturing process of a battery storage with the following steps:

- Analyzing an electrode layer paste and/or an electrode layer (4) for a battery cell (50) of the battery storage device according to a computer-assisted method according to any one of claims 1 to 8, wherein an AI engine is trained in particular according to one of claims 9 to 11 became,

- Adapting at least one production condition for producing the electrode layer (4) based on at least one quality value.

13. The manufacturing method according to claim 12, wherein the manufacturing conditions are temperature, solvent content of the electrode layer paste, a degree of mixing of the electrode layer paste and/or an application speed of the electrode layer paste (2) onto a carrier substrate (3).

14. Production unit (1) for producing a battery storage (50) comprising:

- an electrode layer production device (8) with at least one measuring device, an AI engine (111) set up for carrying out the method according to one of claims 1 to 11.

15. Computer program product, which can be loaded directly into a memory of a programmable processing unit, with gram code means for executing a method according to any one of claims 1 to 11 when the computer program product is executed in the AI engine (111).