Application Gallery

Due to its high capacity, silicon (Si) is often added to graphite in the negative electrode of lithium-ion batteries. Silicon–graphite blended electrodes may exhibit significant thermodynamic voltage hysteresis (“path dependence”) because the equilibrium potential of the lithium–silicon ... Mehr lesen

This application performs parameter estimation (fitting) of the active lithiation windows of the negative and positive electrode materials of a lithium-ion battery, based on a experimental open-circuit voltage (OCV) curve measured as a function of the cell state of charge (SOC). Once a ... Mehr lesen

Lithium iron phosphate (LFP) is a common positive electrode material in lithium-ion batteries. Specific for the LFP electrode material is that its equilibrium (open circuit) potential, when defined as a function of the lithiation state, features a large flat plateau with a more or less ... Mehr lesen

Some positive electrode materials are known to deteriorate in overcharged lithium-ion battery cells. Predominantly, manganese containing electrode materials such as LMO and NMC can loose capacity due to manganese dissolving from the materials at overcharge. This decomposition is a ... Mehr lesen

The copper current collector on negative graphite electrodes in lithium-ion batteries have been seen to dissolve at over discharge. This can be a safety concern as the dissolution damages the current collector irreversibly and dissolved copper ions can redeposit and form dendrites. ... Mehr lesen

Prismatic lithium cells are widely used in electric vehicles and battery energy storage systems. This example demonstrates the use of the Lithium-Ion Battery interface for a full 3D prismatic battery equipped with two jelly rolls. The model defines a full so-called Newman model but ... Mehr lesen

In einem Lithiummetall-Akku lagert sich während des Ladens Lithiummetall an der negativen Elektrode ab. Massentransport und Ohmsche Effekte im Elektrolyten führen zu einem beschleunigten Wachstum kleiner Vorsprünge auf der Metalloberfläche während des Ladevorgangs. Im schlimmsten Fall ... Mehr lesen

Battery electrodes featuring large heterogeneities in terms of particle sizes may sometimes not be adequately described by homogenized models using one single particle size only. As an alternative to adding multiple instances of the Additional Porous Electrode material node, this ... Mehr lesen

Diese App demonstriert die Verwendung eines Ersatzmodells zur Vorhersage der Zellspannung, der Leerlaufspannung und des Innenwiderstands einer NMC111/Graphit-Batteriezelle, die einem Batterietestzyklus unterzogen wird. Das Ersatzmodell, ein Deep Neural Network, wurde an einen Teil der ... Mehr lesen

Diese App demonstriert die Verwendung einer Ersatzmodellfunktion zur Vorhersage der Ratenfähigkeit einer NMC111/Graphit-Akkuzelle. Die Ratenfähigkeit wird in einem Ragone-Diagramm dargestellt. Die Ersatzfunktion, ein Deep Neural Network, wurde an eine Teilmenge der möglichen ... Mehr lesen