Influence of the Carbon Black Dispersing Process on the Microstructure and Performance of Li‐Ion Battery Cathodes

Mayer, Julian K.; Almar, Laura; Asylbekov, Ermek; Haselrieder, Wolfgang; Kwade, Arno; Weber, André; Nirschl, Hermann

doi:10.1002/ente.201900161

Cited by 82 publications

(93 citation statements)

References 51 publications

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“…The work of cohesion/adhesion between the dry particles results in a special microstructure to allow more access surface on AM particles to contact with electrolyte. The cross-linked-like network formed by the binder and conductive carbon has been proved to increase the conductivity, lower the overall resistance, and improve the electrochemistry performance (Mayer et al, 2019). Liu et al further developed the dry printed anode with a discontinuous PVDF interlayer to enhance the bonding strength between the electrode and collector (Liu et al, 2019)…”

Section: Coating Drying and Solvent Recoverymentioning

confidence: 99%

Current and future lithium-ion battery manufacturing

et al. 2021

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Summary Lithium-ion batteries (LIBs) have become one of the main energy storage solutions in modern society. The application fields and market share of LIBs have increased rapidly and continue to show a steady rising trend. The research on LIB materials has scored tremendous achievements. Many innovative materials have been adopted and commercialized by the industry. However, the research on LIB manufacturing falls behind. Many battery researchers may not know exactly how LIBs are being manufactured and how different steps impact the cost, energy consumption, and throughput, which prevents innovations in battery manufacturing. Here in this perspective paper, we introduce state-of-the-art manufacturing technology and analyze the cost, throughput, and energy consumption based on the production processes. We then review the research progress focusing on the high-cost, energy, and time-demand steps of LIB manufacturing. Finally, we share our views of challenges in LIB manufacturing and propose future development directions for manufacturing research in LIBs.

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Section: Coating Drying and Solvent Recoverymentioning

confidence: 99%

Current and future lithium-ion battery manufacturing

et al. 2021

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“…Indeed, the changes in the volume fraction of the constituting phases were taken here as a metric to evaluate the effect of the applied calender pressure. Nonetheless, it is known that the electrode compression does not only impact the former but also causes particle deformation (or even breakage of the bigger AM particles), 53,54 without overlooking the fact that mesostructural changes are expected to depend on how the CBD phase is distributed throughout the electrode (tuned by the mixing and drying stages [55][56][57] ). Further research to implement results coming from physics-based modelling, together with the experimental data, into the electrode mesostructure generating algorithm are ongoing and will be the core of further reports by our group.…”

Section: Resultsmentioning

confidence: 99%

Accelerating Battery Manufacturing Optimization by Combining Experiments, In Silico Electrodes Generation and Machine Learning

Duquesnoy¹,

Lombardo²,

Chouchane³

et al. 2020

Preprint

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Both the society and the market calls for safer, high-performing and cheap Li-ion batteries (LIBs) in order to speed up the transition from oil-based to electric-based economy. One critical aspect to be taken into account in this modern challenge is LIBs manufacturing process, whose optimization is time and resources consuming due to the several interdependent physicochemical mechanisms involved. In order to tackle rapidly this challenge, digital tools able to accelerate LIBs manufacturing optimization are crucially needed for both well assessed and recently discovered chemistries. The methodology presented here encompasses experimental characterizations, in silico generation of electrode mesostructures and machine learning algorithms to track the effect of manufacturing over a wide array of mesoscale electrode properties critically linked to the electrochemical performance. Particularly, features as the interconnectivity of the particles network, the electrolyte tortuosity and effective ionic conductivity, the percentage of current collector surface covered by either active material or carbon-binder domain particles and the active material surface in contact with electrolyte were analysed and discussed in detail. This approach was tested and validated for the case of LiNi1/3Mn1/3Co1/3O2-based cathodes calendering, proving its capability to ease the process parameters-electrode properties interdependencies analysis, paving the way to deeper understanding and then faster optimization of LIBs manufacturing.

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“…These correlations were used to model the aggregates of different size and fractal dimension using a self‐written algorithm; the application of which was previously described by Mayer et al [ 23 ] The algorithm uses the tunable dimension method (TDM) which allows adding primary particles to an existing aggregate without significantly changing its fractal dimension. In this work, the numerical approach for the TDM is shown in Figure 2 .…”

Section: Simulation Modelmentioning

confidence: 99%

“…The solid content within the cell varies slightly between 45% and 65% depending on aggregate size and fractal dimension. The applied shear stress varies between 3 and 40 kPa according to occurring conditions in a planetary mixer with cathode slurries with high solid contents as used by Mayer et al [ 23 ] The aggregate size range is between 400 nm and 1 μm and with the fractal dimension preset to different values between 1.8 and 2.5. Also the domain is filled with CB aggregates only to isolate the disintegration due to fluid shear forces.…”

Section: Simulation Modelmentioning

confidence: 99%

Microscale Discrete Element Method Simulation of the Carbon Black Aggregate Fracture Behavior in a Simple Shear Flow

et al. 2021

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The shear stress induced breaking behavior of carbon black (CB) aggregates during the manufacturing process of Li‐ion batteries is investigated via microscale discrete element method (DEM) simulations. The relevant range of shear stress is chosen according to a planetary mixer and cathode slurries with high solid content. Aggregates of different sizes and shapes are modeled using a self‐written algorithm based on the tunable dimension method. Then, suitable models are chosen for representing the solid bridges between the primary particles of the CB aggregates and relevant fluid forces. The results show a correlation between aggregate size and critical shear stress which is required to initiate aggregate fracturing. Furthermore, a change in aggregate shape is linked to applied stress and initial aggregate size and shape. Hence, a recommendation for an efficient disintegration of CB aggregates during the mixing process is made.

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Influence of the Carbon Black Dispersing Process on the Microstructure and Performance of Li‐Ion Battery Cathodes

Cited by 82 publications

References 51 publications

Current and future lithium-ion battery manufacturing

Current and future lithium-ion battery manufacturing

Accelerating Battery Manufacturing Optimization by Combining Experiments, In Silico Electrodes Generation and Machine Learning

Microscale Discrete Element Method Simulation of the Carbon Black Aggregate Fracture Behavior in a Simple Shear Flow

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