Seminar: Battery Modeling with COMSOL Multiphysics®

Learn the fundamental workflow of COMSOL Multiphysics^®. This introductory demonstration will show you all of the key modeling steps, including drawing the geometry, setting up the materials and physics models, meshing, solving, and evaluating and visualizing the results.

Get an overview of using the COMSOL^® software for modeling batteries. Learn how to incorporate porous electrodes and electrode reactions including transport of ions and current in your battery models. We will address the simulation of lithium-ion battery power and capacity using realistic vehicle drive cycles, modeling of thermal effects on both cell and pack levels, safety aspects, and modeling capacity fade.

The COMSOL^® software aids in different processes in the field of renewable energy. It offers unique modeling and simulation (M&S) capabilities as well as easy-to-use features for creating standalone simulation apps.

The Application Builder and COMSOL Compiler™ allow for bringing M&S to a larger group of scientists and engineers thanks to their capabilities for creating and deploying simulation apps. These apps can be incorporated into digital twins for use in equipment maintenance and process operation. The latest release of COMSOL Multiphysics^® contains functionality for creating surrogate models based on data from simulations and advanced function approximation such as DNN and Gaussian process, making simulation apps lightning-fast.

In this session, you’ll learn about the COMSOL^® software’s capabilities for creating simulation apps and digital twins.

Tech Socials are informal sessions that allow you to interact with COMSOL staff and other attendees. They can cover any modeling-related topic that you like and give you the opportunity to ask COMSOL technology product managers and applications engineers your questions. Join us!

Batteries are widely used to power equipment in the aerospace and defense industries. The most commonly used technology is lithium-ion, which boasts a high energy density, long cycle life, and low rate of self-discharge. However, lithium-ion batteries are sensitive to temperature conditions, which can impact their performance. To ensure optimal performance and efficient thermal management, the use of modeling and simulation in the design process is crucial. Modeling and simulation are powerful tools that can help us understand and predict the behavior of battery systems while also reducing development time and costs.

COMSOL Multiphysics^® and the Battery Design Module offer a range of capabilities for building detailed models of battery cells and packs, capturing phenomena such as electrochemistry, species transport, heat transfer, fluid flow, and structural mechanics. When combined with the Heat Transfer Module, users can access a unique environment for running thermal analyses of battery systems, accounting for heating due to activation losses, Joule heating, conjugate heat transfer, nonisothermal flow, and other coupled phenomena.

In this session, we will provide an overview of the functionality that COMSOL Multiphysics^® offers for battery design and thermal analysis. We will demonstrate these capabilities using models at both the battery cell and battery pack levels.

Participate in a discussion forum with colleagues and COMSOL engineers to discuss battery modeling. Engineers will be made available to answer questions about your applications and suggest the best techniques for modeling them.

Battery systems are often burdened by unwanted side reactions at the electrodes. The COMSOL Multiphysics^® software and its Battery Design Module add-on product can be used to simulate various aging and degradation mechanisms, resulting in capacity fade in batteries. The flexibility of the Battery Design Module also enables you to include any arbitrary by-reaction, such as hydrogen and oxygen evolution, solid electrolyte interface growth due to deposition, metal plating, metal corrosion, and graphite oxidation in your battery models.

In this session, we will present the capabilities of the Battery Design Module for modeling degradation in batteries and demonstrate the process of building and running a capacity fade model.

• Set up and solve your first COMSOL Multiphysics simulation on your own computer with step-by-step guidance
• Discuss your application area and get assistance from a COMSOL engineer
• Start your free two-week trial and work through your own simulations with help from our applications engineers