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http://dx.doi.org/10.5764/TCF.2021.33.4.309

Research of the Composite Spun Yarn Manufacturing Process using Silicon Carbide and Para Aramid Fiber  

Kim, Booksung (Korea Textile Development Institute)
Ryu, Huijun (Daewon ENG)
Publication Information
Textile Coloration and Finishing / v.33, no.4, 2021 , pp. 309-316 More about this Journal
Abstract
Due to the rigid nature of the silicon carbide fiber(SiC), fiber damage occurs from the friction during the carding process. This damage not only lowers the spun yarn yield, but also lowers the heat resistance of the spun yarn, so that ultra-high heat resistant yarn cannot be manufactured. Therefore, in the carding process where the most friction between fiber and machine(wire, etc.) occurs, some factors were modified and tested, and as a result of measuring the change in physical properties, fiber damage decreased due to the wire angle or wire density, resulting in improved yield. The test method used to measure the yield of SiC fiber was the carbonization method, and the content of SiC fibers was calculated using the remaining amount after carbonization. Carbonization test was performed at air condition, 700℃, and for 2 hours. Analysis by SEM-EDX showed that the carbide was consistent with the composition of the SiC fiber.
Keywords
ceramic fiber; silicon carbide; SiC fiber; ceramic spun yarn; organic and inorganic composite yarn;
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