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The risk of thermal runaway in lithium-ion battery systems remains a critical challenge, necessitating advanced thermal management solutions for improved safety and reliability. This study introduces a high-temperature resistant foam engineered to enhance battery pack protection through robust insulation and mechanical adaptability for pouch and prismatic cell form factors. The material demonstrates superior thermal resistance across both LFP and NMC chemistries, effectively mitigating heat propagation and maintaining structural integrity under extreme conditions. Designed for versatility, the foam can be integrated across battery components —cell-to-cell pads, vent covers, and gaskets. It provides thermal barrier protection, high-temperature sealing, and targeted venting at the cell, module, and pack levels.
This webinar will focus on the following key topics:
• Multi-functional material that provides mechanical support and thermal protection
• Mechanical properties’ tuning for pouch or prismatic form factors
• Robust thermal insulation properties for LFP or NMC
• Performance highlights from: i.) NMC811 testing, ii.) high temperature furnace & hot microscope study and iii.) preliminary benchmarking
• Application case studies based on thermal protection at cell, module and pack level
Presenters
Dr. Katherine Shinopoulos – Senior Research Engineer at Saint Gobain
Dr. Subhashini (Subha) Gunashekar – Business Development Manager at Saint Gobain
Saint Gobain is a proud sponsor of this event.
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FREE Webinar – Voltaiq is a proud sponsor of this event.
As automakers and utilities transition away from non-renewable energy sources, batteries have become essential for efficient energy storage and delivery. Companies are working intensely to deliver higher capacity and more robust batteries to power their products, but ad hoc development processes cannot keep pace with the volume of battery data being generated. In addition, understaffed battery development teams are unable to leverage their data to accelerate development or improve production and manufacturing.
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Dr. Tal Sholklapper – Co-Founder and CEO at VoltaiqDr. Tal Sholklapper is a co-founder of Voltaiq and serves as the company’s Chief Executive Officer. Before co-founding Voltaiq, Dr. Sholklapper was the lead engineer on a DOE ARPA-E funded project at the CUNY Energy Institute, developing an ultra-low-cost grid-scale battery. Prior to his work at CUNY, Tal co-founded Point Source Power, a low-cost fuel-cell startup based on technology he developed while at Lawrence Berkeley National Laboratory (LBNL) and UC Berkeley. Dr. Sholklapper has a BS in Physics and Applied Mathematics and an MS and PhD in Materials Science and Engineering from UC Berkeley.
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