How do you develop thermal models for lithium-ion batteries?

Developing thermal models for lithium-ion batteries involves creating mathematical or computational representations of the battery’s thermal performance in different operating conditions. Here is an overview of the algorithm design for crafting thermal models for lithium-ion batteries:

Why do we need thermal models for lithium-ion batteries?

To enhance our understanding of the thermal characteristics of lithium-ion batteries and gain valuable insights into the thermal impacts of battery thermal management systems (BTMSs), it is crucial to develop precise thermal models for lithium-ion batteries that enable numerical simulations.

What are the thermal characteristics of lithium ion battery?

The thermal characteristics of lithium-ion battery are determined by the complex electrochemical reaction and electric-thermal conversion. The heat generation consists of four components: reaction heat, ohmic heat, polarization heat and secondary reaction heat.

How is heat generated within a lithium-ion battery cell measured?

The quantity of heat generated within the lithium-ion battery cell, which is influenced by temperature and current rate, was quantified using IBC measurements and used as input for the thermal model.

Do lithium-ion batteries need thermal management?

As lithium-ion batteries are now capable of handling higher charging and discharging power, ensuring their safety and implementing effective thermal management for the entire battery system has become crucial. Temperature significantly impacts the short-term and long-term performance of lithium-ion batteries.

How can thermal and electrochemical modeling improve lithium-ion battery performance?

The integration of thermal and electrochemical modeling provides valuable insights for optimizing battery design and thermal management, ultimately improving the performance and safety of lithium-ion batteries in various applications. Figure 1. Lithium-ion battery heat-generation (HG) model .