Increased Moisture Uptake of NCM622 Cathodes after Calendering due to Particle Breakage

Huttner, Fabienne; Diener, Alexander C.; Heckmann, Thilo; Eser, Jochen C.; Abali, Tugay; Mayer, Julian K.; Scharfer, Philip; Schabel, Wilhelm; Kwade, Arno

doi:10.1149/1945-7111/ac24bb

Cited by 32 publications

(64 citation statements)

References 54 publications

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“…However, particle breakage or fractioning in the cause of calendering is reported in the literature and may also be an origin for plastic deformation besides particle rearrangement. [ 12,15,31 ] As Figure 5a shows for higher mass loadings, higher maximum densities are reached, starting from ρ C = 3.18 g cm −3 for 200 g m −2 up to 3.41 g cm −3 for 350 g m −2 .…”

Section: Resultsmentioning

confidence: 86%

“…However, applying high load during compaction may lead to the appearance of particle cracks, causing accelerated cell aging, as reported for LMO [12] and NMC. [13,14] Huttner et al [15] observed an increased moisture uptake for NMC622-based cathodes with higher electrode density and addressed this behavior to a rising surface area caused by particle breakage through higher calendering forces. Bockholt et al [13] also examined the correlation between the mixing and calendering process, showing improved capacity retention for electrodes with an intensive dry-mixing process route.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of Deformation Behavior and Fast Elastic Recovery of Lithium‐Ion Battery Cathodes via Direct Roll‐Gap Detection During Calendering

et al. 2022

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Calendering is the state‐of‐the‐art process for electrode compaction in lithium‐ion battery manufacturing through which the final electrode structure is defined. As the electrode structure determines the electrical und electrochemical transport properties, it is essential to develop a deep understanding of the interdependence between the calendering process and the deformation behavior of the electrodes. Therefore, a novel method for the investigation of the deformation behavior of electrodes, especially the springback (SB) effect, through direct‐gap detection within the calendering machine, is developed. With this installation, it is possible to directly access the maximum compression of the electrodes during calendering. With this approach, two different variations of cathodes, a variation of mass loading and a variation of binder weight content, based on lithium nickel manganese cobalt oxide (NMC622), are manufactured and investigated. Moreover, an empirical model is introduced, allowing the estimation of the SB for NMC622 cathodes considering different mass loadings and cathode compositions. Due to more space for particle rearrangement, cathodes with higher mass loading show a lower SB effect. Adding binder leads to higher plastic deformation and thus lowers also the SB effect of the electrodes.

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Section: Resultsmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Evaluation of Deformation Behavior and Fast Elastic Recovery of Lithium‐Ion Battery Cathodes via Direct Roll‐Gap Detection During Calendering

et al. 2022

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“…One aspect may be the fact that the SE cannot fill the pores of the primary particles within the polycrystalline active material. Moreover, high pressures during compaction can cause a breakage of the polycrystalline material [93,104] . As mentioned before, the higher surface of the single crystalline material can result in a higher degradation because of the larger contact area to the electrolyte.…”

Section: Processing At Laboratory Scalementioning

confidence: 98%

Current Status of Formulations and Scalable Processes for Producing Sulfidic Solid‐State Batteries

Batzer

Heck

Michalowski

et al. 2022

Batteries & Supercaps

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Solid-state batteries possess the potential to combine increased energy densities, high voltages, as well as safe operation and therefore are considered the future technology for electrical energy storage. In particular, sulfides as solid electrolyte are promising candidates due to their high ionic conductivities and the possibility of a scalable production. This review aims to demonstrate ways to manufacture suspension-based sulfidic solid-state batteries both on a laboratory scale and on an industrial level, focusing on the assessment of current knowl-edge and its discussion from a process engineering point of view. In addition to the influence of process parameters during mechanochemical synthesis of the solid electrolyte, formulation strategies for electrodes and separators are presented. The process chain from dispersion to cell assembly is evaluated. Scale-up technologies are considered in comparison to established techniques in the field of conventional lithium-ion batteries with liquid electrolyte summarizing the current status of sulfidic solid-state battery production.

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“…[ 116 ] The moisture content as an additional product parameter in combination with the coating density has been studied in the literature. [ 126 ] Figure 6 summarizes the parameters in the calendering process. It should be mentioned that, based on the defined reference process, the slitting process is followed after calendering and is not considered here.…”

Section: Literature‐based Prioritization Of the Parameters Based On T...mentioning

confidence: 99%

“…The surface finish is another property influenced by the calendering process. [118,125] Product parameters such as coating width, [118] mass loading, [119] coating density, [117] and the pore size distribution [126] are additional aspects that are considered in setting up the process parameters. Similar to the drying process, the quality of the electrode concerning common electrode defects, such as the camber effect, is another product parameter to be considered in the calendering process.…”

Section: Calendering Processmentioning

confidence: 99%

Tailored Digitalization in Electrode Manufacturing: The Backbone of Smart Lithium‐Ion Battery Cell Production

et al. 2022

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Following the introduction of Industry 4.0 and the development of information technologies, manufacturing companies have been undergoing a profound transformation. This transformation envisions the realization of the smart factory as a fully connected, flexible production system regulated by data. Digitalization and collection of the critical parameters are the vital prerequisites for this vision. Electrode manufacturing is regarded as the core phase in the battery cell production, having most of the properties determining the electrochemical performance of the battery cell established in this phase. There are a high number of parameters involved in electrode manufacturing. The digitalization of these parameters is associated with a considerable amount of effort and costs. Introducing a tailored digitalization concept provides the first step toward smart battery cell production. The tailored digitalization concept is based on the importance of the parameters from the quality management perspective and their complexity with regard to digitalization. The prioritization of parameters enables a successive quality‐oriented digitalization strategy. The concept is built on a two‐step literature‐based and expert‐based approach. The results include a comprehensive list of parameters and their prioritization for digitalization and integration in a tracking and tracing concept.

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Increased Moisture Uptake of NCM622 Cathodes after Calendering due to Particle Breakage

Cited by 32 publications

References 54 publications

Evaluation of Deformation Behavior and Fast Elastic Recovery of Lithium‐Ion Battery Cathodes via Direct Roll‐Gap Detection During Calendering

Evaluation of Deformation Behavior and Fast Elastic Recovery of Lithium‐Ion Battery Cathodes via Direct Roll‐Gap Detection During Calendering

Current Status of Formulations and Scalable Processes for Producing Sulfidic Solid‐State Batteries

Tailored Digitalization in Electrode Manufacturing: The Backbone of Smart Lithium‐Ion Battery Cell Production

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