• Title/Summary/Keyword: Air-Oxidation Curing

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Development of Polymer-derived Silicon Carbide Fiber with Low Oxygen Content Using a Cyclohexene Vapor Process (싸이클로헥센 증기 공정에 의한 산소량이 적은 실리콘카바이드 섬유의 개발)

  • Yoon, Byungil;Choi, Woo Chul;Kim, Myeong Ju;Kim, Jae Sung;Kim, Jung il;Kang, Hong Gu
    • Journal of the Korea Institute of Military Science and Technology
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    • v.20 no.5
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    • pp.620-632
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    • 2017
  • A chemical vapor curing method(CVC) was developed to cure polycarbosilane(PCS) fibers by using cyclohexene vapour as a non-oxygen active reactant, instead of air in oder to prepare the silicon carbide(SiC) fiber with low oxygen content. A cross-linked PCS fibers by cyclohexene vapor showed a completely different variation in IR spectra in comparison to the air-cured PCS fiber. CVC method resulted in less than 3 wt% in oxygen content. In this experiment conditions, The average tensile strength and modulus of SiC fiber obtained by CVC had 1995 MPa and 183 GPa respectively, which is higher than that of SiC fiber prepared by air-curing process.

Densification of Cf/SiC Composite Using PIP with Adding of Cyclohexene (Cyclohexene을 첨가한 PIP 공정 사용 Cf/SiC 복합재의 고밀도화)

  • Bae, Jin-Cheol;Cho, Kwang-Youn;Kim, Jun-Il;Im, Dong-Won;Park, Jong-Kyu;Lee, Man-Young;Lee, Jae-Yeol
    • Composites Research
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    • v.26 no.5
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    • pp.322-327
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    • 2013
  • Carbon fiber-reinforced SiC matrix composites have good oxidation resistance and thermal shock resistance. These properties have allowed the composites to be applied to high-temperature structures. In this study, $C_f/SiC$ composites were fabricated via precursor infiltration and pyrolysis (PIP) process, including liquid phase infiltration and chemical vapor curing using cyclohexene. The final $C_f/SiC$ composites, which have gone through the PIP process five times, showed a density of $1.79g/cm^3$, as compared to a density of $0.43g/cm^3$ for pre-densified bare carbon fiber preform. As for the oxidation resistance characteristics, the weight of $C_f/SiC$ composite was maintained at 81% at $1400^{\circ}C$ in air for 6 hours. Chemical vapor curing (CVC) using cyclohexene has shown to be an effective method to achieve high densification, leading to increased oxidation resistance.

Fabrication and Characterization of C/SiC Composite by Electron Beam Curing (전자선 가교 방법을 이용한 탄소/탄화규소 복합재 제조 및 특성)

  • Shin, Jin-Wook;Jeun, Joon-Pyo;Kang, Phil-Hyun
    • Polymer(Korea)
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    • v.33 no.6
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    • pp.575-580
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    • 2009
  • Carbon fabric-reinforced silicon carbide composites (C/SiC) have attracted a considerable attention for high temperature structural application because of their outstanding oxidation resistance property and thermal shock resistance. In this study, we reported on the preparation of C/SiC composites by the polymer impregnation and pyrolysis (PIP) method. For this, polycarbosilane solution was impregnated into the carbon fabric and then cured by electron beam irradiation under argon atmosphere. Afterwards, the cured composite was pyrolyzed at $1300^{\circ}C$ for 1 h under argon atmosphere to produce the C/SiC composite. The porosity and density of the C/SiC composite were 13.5% and $2.44\;g/cm^3$, respectively, when the impregnation of the carbon fabric with the 30 wt% polycarbosilane solution conducted four times. In addition, in the isothermal experiment at $1500\;^{\circ}C$ in air for 5 h, the 95.9 wt% of the C/SiC composite was remained, indicating that the prepared C/SiC composite has a outstanding oxidation resistance.

Development of Pilot-Scale Manufacturing Process of SiC Fiber from Polycarbosilane Precursor with Excellent Mechanical Property at Highly Oxidation Condition and High Temperature (폴리카보실란 전구체로부터 고온 산화성분위기서 기계적물성이 우수한 파이롯-규모의 탄화규소섬유 제조공정 개발)

  • Yoon, B.I.;Choi, W.C.;Kim, J.I.;Kim, J.S.;Kang, H.G.;Kim, M.J.
    • Composites Research
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    • v.30 no.2
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    • pp.116-125
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    • 2017
  • The purpose of this study is to develop silicon carbide fiber showing an excellent mechanical properties under highly oxidative conditions at high temperature. Polycarbosilane(PCS) as a preceramic precursor was used for making the SiC fiber. PCS fiber was taken by melt spinning method followed by melting the PCS at $300{\sim}350^{\circ}C$ in N2 gas. The Curing of PCS fiber was carried out in air oxygen chamber, prior to high temperature pyrolysis. Degree of cure was calculated by characteristic peak's ratio of Si-H to $Si-CH_3$ in FT-IR spectra before and after curing of PCS fiber. The properties of SiC fiber was affected greatly by the degree of cure. The SiC fiber produced by controlling fiber tension during heat treatment showed good properties. The SiC fiber exposed to $1000^{\circ}C$ at air from 1 min. up to maximum 50 hrs showed around 60% reduction in tensile strength. We found that large amount of carbon content on the fiber surface after long-term exposure has resulted in lower tensile strength.

Effects of Storage Conditions on Rancidity of Perilla and Sesame Seed Oils (저장조건(貯藏條件)이 들깨유(油) 및 참깨유(油)의 산패도(酸敗度)에 미치는 영향(影響))

  • Kim, Hye-Kyung;Lee, Yang-Cha;Lee, Ki-Yull
    • Journal of Nutrition and Health
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    • v.12 no.1
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    • pp.51-58
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    • 1979
  • It is a general trend everywhere that the uses of vegetable oils are increasing due to the fact that they are effective in curing and preventing symptoms of high blood pressure and various heart failure conditions. At the same time the concept that oxidative rancidity is caused by the oxidation of unsaturated fatty acid moieties whose subsequent decomposition gives rise to various undesirable, sometimes toxic compounds is now well accepted. Linolenic acid (C, 18:3) is one of highly unsaturated and readily oxidizable fatty acid. The content of this essential polyunsaturated fatty acid in perilla seed oil (PSO) was found to be as high as 48% while only 1.5% in sesame seed oil (SSO). In this experiment the oxidative stability of PSO was compared with that of SSO. The experimental test group were as follows: A) Stored at different temperatures, namely $4^{\circ}C,\;30^{\circ}C,$ and $60^{\circ}C,$ B) Stored at room temperature $(20{\pm}5^{\circ}C)$ ; a. protected from sunlight and air, b. exposed to air without sunlight c. exposed to sunlight but protected front air, d. completely exposed to both air and sunlight. The following results were obtained; 1) It was found to be most stable against oxidation to store both PSO and SSO under the low temperature $(4^{\circ}C)$ condition. According to P.V. measurements it was found to be safe to keep both oils up to $30^{\circ}C$ for at least 8 weeks. When exposed to air, sunlight and high temperature $(60^{\circ}C)$, P.V. of PSO reached there peak values, which were much higher than those of SSO. This explains much of its instability as compared to SSO against oxidation. 2) The effect of high temperature $(60^{\circ}C)$ on A.V. was found to be more striking than those of all the other storage conditions. The condition of refrigeration was most effective in keeping A.V. low for both oils as was the case in P.V. 3) For both oils, I.V. decreased throughout the experimental period (8 weeks). The range of decrement was larger for PSO than SSO. 4) There was no significant change in the compositions of fatty acids of SSO caused by various experimental storage conditions. But for PSO the compositions of stearic, oleic and linoleic acid were decreased, whereas linolenic acid was increased proportionally.

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