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http://dx.doi.org/10.12772/TSE.2021.58.245

3D Finite Element Model on the Density Difference of Plain Fabrics Manufactured with PBO/m-aramid/SiC Fibers and Thermal Protection Performance Simulation  

Sim, Jee-Hyun (Department of Textile System Engineering, Kyungpook National University)
Lee, Jong-hyuck (Computer Aided Engineering Team, DYETEC)
Jee, Yeong-Joo (SamSung Textile)
Yu, Seong-Hun (Computer Aided Engineering Team, DYETEC)
Bae, Jin-Seok (Department of Textile System Engineering, Kyungpook National University)
Publication Information
Textile Science and Engineering / v.58, no.5, 2021 , pp. 245-251 More about this Journal
Abstract
In this study, a 3D model of a PBO/m-aramid and SiC fabric was created in a virtual space to evaluate the thermal protection performance of each material used in firefighting suits, and a thermal protection performance simulation study was conducted with an aim to reduce the material development lead time and development cost. To compare the thermal protection performance of the PBO/m-aramid fiber woven fabric, which is the material used for the outer fabric of the existing fire-fighting clothing, and the SiC fiber woven fabric with different fabric densities (high, medium, and low density), a thermal protection performance analysis was conducted for each yarn model after creating the geometry of the fabric model and the finite element model using virtual engineering software. To analyze the thermal protection performance according to the density difference of the SiC fiber woven fabrics, three-dimensional (3D) models of the three types of fabrics with low, medium, and high densities were created. The thermal protection performance analysis compared the thermal protection performance against the radiation heat source exposure of the PBO/m-aramid woven fabrics and the SiC woven fabrics according to density as stated by the KS K ISO 6942 radiant heat protection test method, which is the concrete test standard. A comparison revealed that the thermal protection performance of the SiC material was superior to that of the PBO/m-aramid material, and the high-density woven SiC fabric exhibited the best thermal protection performance.
Keywords
thermal protection performance; PBO/m-aramid woven fabirc; SiC woven fabric; finite element analysis; virtual engineering;
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