A research team, led by Professor Seok Ju Kang within the School of Energy and Chemical Engineering at UNIST, has unveiled a groundbreaking technique for mass-producing polymer solid electrolytes, crucial components in batteries.
Departing from the standard melt casting method, the team introduced a horizontal centrifugal casting method to beat existing limitations. This progressive approach has redefined the production process for high-quality polymer solid electrolytes, revolutionizing the industry.
Drawing inspiration from the horizontal centrifugal casting technique utilized in producing iron pipes, the research team successfully achieved a uniform polymer solid electrolyte by rotating the answer horizontally during manufacturing. This method ensures minimal raw material wastage and offers superior electrochemical performance, economic feasibility, and effectiveness compared to traditional methods.
Professor Kang commented, “By adapting the iron pipe manufacturing process, we’ve developed a way able to mass-producing uniform and high-performance solid electrolytes.”
The newly developed technology enables a remarkable 13-fold increase in production speed by eliminating the necessity for drying polymer solutions and vacuum heat treatment, thereby streamlining the manufacturing process significantly.
Furthermore, the production volume could be easily adjusted by various the scale of the horizontal centrifugal casting cylinder, ensuring consistent thickness and surface quality of polymer solid electrolytes, ideal for battery production.
Lead creator Hyunwoo Kim from the School of Energy and Chemical Engineering at UNIST stated, “Through this method, we’ve achieved enhanced battery stability and performance without altering the fabric composition.”
Professor Kim emphasized, “The elimination of the time-consuming and energy-intensive vacuum heat treatment process is a key aspect of this study, enabling efficient mass production of polymer solid electrolytes.”
The research findings have been published in the web version of Energy Storage Materials on February 13, 2024. This research has been supported by the National Research Foundation of Korea (NRF), the Korea Institute of Energy Technology Evaluation and Planning (KETEP), and the Ministry of Science and ICT (MSIT).
