Browse > Article
http://dx.doi.org/10.4191/KCERS.2009.46.6.648

Properties of the Electrolyte Separators for Thermal Batteries Using SiOC Mat  

Lim, Kyoung-Hoon (Division of Nano materials Application, KICET)
Cho, Kwang-Youn (Division of Nano materials Application, KICET)
Riu, Doh-Hyung (Division of Nano materials Application, KICET)
Shin, Dong-Geun (Division of Nano materials Application, KICET)
Jin, Eun-Ju (Division of Nano materials Application, KICET)
Kim, Hyoun-Ee (Department of Materials Science and Engineering, Seoul National University)
Cheong, Hae-Won (Agency for Defense Development)
Lee, Hong-Lim (Department of Materials Engineering, Yonsei University)
Publication Information
Journal of the Korean Ceramic Society / v.46, no.6, 2009 , pp. 648-652 More about this Journal
Abstract
Ceramic fiber separator is the promising material for thermal battery system because it reduces the production cost and offers the potential to a new application compared to a pellet type electrolyte. The electrolyte separator for thermal battery should be easily handled and loaded a large amount of the molten lithium salt. Ceramic fibers were used as an electrolyte separator and the lithium based molten salts were infiltrated into the ceramic filters. Leakage of molten salt (several lithium salts) leads to short-circuit during the thermal battery operation. In this study, a uniform and fine SiOC mat with fibers ranging from 1 to 3 ${\mu}m$ was obtained by electrospinning of polycarbosilane and pyrolysis. The optimum spinning conditions for obtaining fine diameters of SiOC fiber were controlled by the solution composition and concentration, applied voltage and spinning rate, release rate by porosity. The pore structures of the ceramic filter and the melting properties of the lithium salts affected to the electrolyte loading and leakage. The importance of the fiber size and porosity and their control was discussed and the mechanical properties were also discussed.
Keywords
Thermal battery; Molten salt; Ceramic filter; Electrolyte separator; Infiltration;
Citations & Related Records

Times Cited By SCOPUS : 0
연도 인용수 순위
  • Reference
1 R. Ponnappan, “Contact Thermal Resistance of Li-Ion Cell Electrode Stack,” J. Pow. Sour., 129 7-13 (2004)   DOI   ScienceOn
2 B. Culpin, “Thermal Runaway in Valve-Regulated Lead- Acid Cells and the Effect of Separator Structure,” J. Pow. Sour., 133 79-86 (2004)   DOI   ScienceOn
3 J. M. Deitzel, “The Effect of Processing Variables on the Morphology of Electrospun Nanofibers and Textiles,” J. Pol., 42 261-67 (2001)   DOI   ScienceOn
4 S. H. Tan and R. Inai, “Systematic Parameter Study for Ultra-Fine Fiber Fabrication via Electrospinning Process,” J. Pol., 5 68-71 (2005)
5 J. Saunier, “Plasticized Microporous Poly(Vinylidene Fluoride) Separators for Lithium-Ion Batteries. III. Gel Properties and Irreversible Modifications of Poly(Viny lidene Fluoride) Membranes under Swelling in Liquid Electrolytes,” J. Pow. Sour., 42 2308-17 (2004)
6 P. Masset, “Thermal Activated (Thermal) Battery Technology, Part II. Molten Salt Electrolytes,” J. Pow. Sour., 164 397-414 (2007)   DOI   ScienceOn
7 R. A. Guidotti, “Thermally Activated (“Thermal”) Battery Technology Part I: An Overview,” J. Pow. Sour., 161 1443-49 (2006)   DOI   ScienceOn
8 P. Butler, “Long-Life, Multi-Tap Thermal Battery Development,” J. Pow. Sour., 136 240-45 (2004)   DOI   ScienceOn
9 S. S. Zhang, “A Review on the Separators of Liquid Electrolyte Li-Ion Batteries,” J. Pow. Sour., 164 351-64 (2007)   DOI   ScienceOn
10 P. Masset, “Retained Molten Salt Electrolytes in Thermal Batteries,” J. Pow. Sour., 139 356-65 (2005)   DOI   ScienceOn
11 P. Masset, “Iodide-Based Electrolytes: A Promising Alternative for Thermal Batteries,” J. Pow. Sour., 160 688-97 (2006)   DOI   ScienceOn
12 D. G. Shin, “Web-Type Silicon Carbide Fibers Prepared by the Electrospinning of Polycarbosilanes,” J. Ceram. Proces. Res., 2 85-91 (2008)