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ScienceONSilicon carbide (SiC), known for its excellent mechanical and chemical properties, is widely used in key industries such as aerospace, defense, and nuclear power generation. Due to its rapid heating characteristics when exposed to microwaves, SiC i...
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RISS 인기검색어
기계화학적 아이오딘 불융화 공정 조건에 따른 마이크로파 탄화규소 발열체의 발열 특성 연구 = Investigation of the heating characteristics of microwave silicon carbide heaters under mechanochemical iodine curing process conditions
한글로보기https://www.riss.kr/link?id=A109320933
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2024
-
작성언어
Korean
- 주제어
-
등재정보
KCI등재,ESCI
-
자료형태
학술저널
- 발행기관 URL
-
수록면
156-162(7쪽)
- DOI식별코드
- 제공처
-
0
상세조회 -
0
다운로드
부가정보
다국어 초록 (Multilingual Abstract)
Silicon carbide (SiC), known for its excellent mechanical and chemical properties, is widely used in key industries such as aerospace, defense, and nuclear power generation. Due to its rapid heating characteristics when exposed to microwaves, SiC is being researched as a highly efficient heating element. In this study, Polycarbosilane (PCS) was treated by a mechanochemical reaction with iodine, followed by pyrolysis to create a microwave heating material. The effects of pyrolysis temperature and iodine additive content on microwave heating performance were investigated. The results showed that the fabricated specimen rapidly heated to a maximum of 800° C within approximately 60 sec and maintained a stable temperature of 700~750°C for up to 120 min
Silicon carbide (SiC), known for its excellent mechanical and chemical properties, is widely used in key industries such as aerospace, defense, and nuclear power generation. Due to its rapid heating characteristics when exposed to microwaves, SiC is being researched as a highly efficient heating element. In this study, Polycarbosilane (PCS) was treated by a mechanochemical reaction with iodine, followed by pyrolysis to create a microwave heating material. The effects of pyrolysis temperature and iodine additive content on microwave heating performance were investigated. The results showed that the fabricated specimen rapidly heated to a maximum of 800° C within approximately 60 sec and maintained a stable temperature of 700~750°C for up to 120 min
참고문헌 (Reference)
1 Y. Wang, "Synthesis, properties, and multifarious applications of SiC nanoparticles : A review" 48 : 8882-, 2022
2 Y. Hasegawa, "Synthesis of continuous silicon carbide fiber : Part3 Pyrolysis process of polycarbosilane and structure of the products" 18 : 3633-, 1983
3 Z. Shen, "Recent progress in SiC nanowires as electromagnetic microwaves absorbing materials" 815 : 15238-, 2020
4 M. Narisawa, "Reaction mechanism of the pyrolysis of polycarbosilane and polycarbosilazane as ceramic precursors" 68 : 1098-, 1995
5 R. He, "Progress and challenges towards additive manufacturing of SiC ceramic" 10 : 637-, 2012
6 J. H. Eom, "Processing and properties of macroporous silicon carbide ceramics : A review" 1 : 220-, 2013
7 Y. Hasegawa, "New curing method for polycarbosilane with unsaturated hydrocarbons and application to thermally stable SiC fibre" 51 : 161-, 1994
8 Y.J. Yoo, "Microwave-assisted heating behavior of amorphous SiC fibers derived from polycarbosilane" 8 : 035603-, 2021
9 E. Boldyreva, "Mechanochemistry of inorganic and organic systems : what is similar, what is different?" 42 : 7719-, 2013
10 A. N. Qinglong, "Machining of SiC ceramic matrix composites : A review" 34 : 540-, 2021
1 Y. Wang, "Synthesis, properties, and multifarious applications of SiC nanoparticles : A review" 48 : 8882-, 2022
2 Y. Hasegawa, "Synthesis of continuous silicon carbide fiber : Part3 Pyrolysis process of polycarbosilane and structure of the products" 18 : 3633-, 1983
3 Z. Shen, "Recent progress in SiC nanowires as electromagnetic microwaves absorbing materials" 815 : 15238-, 2020
4 M. Narisawa, "Reaction mechanism of the pyrolysis of polycarbosilane and polycarbosilazane as ceramic precursors" 68 : 1098-, 1995
5 R. He, "Progress and challenges towards additive manufacturing of SiC ceramic" 10 : 637-, 2012
6 J. H. Eom, "Processing and properties of macroporous silicon carbide ceramics : A review" 1 : 220-, 2013
7 Y. Hasegawa, "New curing method for polycarbosilane with unsaturated hydrocarbons and application to thermally stable SiC fibre" 51 : 161-, 1994
8 Y.J. Yoo, "Microwave-assisted heating behavior of amorphous SiC fibers derived from polycarbosilane" 8 : 035603-, 2021
9 E. Boldyreva, "Mechanochemistry of inorganic and organic systems : what is similar, what is different?" 42 : 7719-, 2013
10 A. N. Qinglong, "Machining of SiC ceramic matrix composites : A review" 34 : 540-, 2021
11 J. S. Hong, "Low-temperature chemical vapour curing using iodine for fabrication of continuous silicon carbide fibres from low-molecular-weight polycarbosilane" 2 : 2781-, 2014
12 J. S. Hong, "Iodine diffusion during iodine-vapor curing and its effects on the morphology of polycarbosilane/silicon carbide fibers" 132 : 42687-, 2015
13 N. R. Rose, "Iodine : an environmental trigger of thyroiditis" 1 : 97-, 2002
14 W. Krenkel, "Handbook of ceramic composites" Springer 117-, 2005
15 C. Ke, "Energy absorption performances of silicon carbide particles during microwave heating process" 172 : 108796-, 2022
16 H. Li, "Effect of the polycarbosilane structure on its final ceramic yield" 28 : 887-, 2008
17 Young Jun Joo ; Kwang-Youn Cho ; Cheol Jin Kim, "Effect of pyrolysis temperature on heat-generating behavior and morphology of SiC fiber mats" 20 : 563-, 2019
18 주영준 ; 주상현 ; 조광연, "Effect of pyrolysis temperature and pressing load on the densification of amorphous silicon carbide block" 30 : 271-, 2020
19 V. Verdingovas, "Effect of iodine on the corrosion of Au-Al wire bonds" 97 : 161-, 2015
20 H. Q. Ly, "Conversion of polycarbosilane(PCS)to SiC-based ceramic Part 1. Characterisation of PCS and curing products" 36 : 4037-, 2001
21 C. Sauder, "Ceramic matrix composites: materials, modeling and technology" Wiley 609-, 2014
22 H. Sugawara, "Behavior of microwaveheated silicon carbide particles at frequencies of 2.0~13.5 GHz" 105 : 034103-, 2014
23 K. Okamura, "Application of radiation curing in the preparation of polycarbosilane-derived SiC fibers" 2 : 171-, 1992
24 A. Idesaki, "Application of electron beam curing for silicon carbide fiber synthesis from blend polymer of polycarbosilane and polyvinylsilane" 60 : 483-, 2001
25 N. Eswara Prasad, "Aerospace materials and material technologies: Vol. 1: Aerospace materials" Springer 371-, 2017
26 T. Taki, "A study of the oxidation curing mechanism of polycarbosilane fibre by solid-state high-resolution nuclear magnetic resonance" 24 : 1263-, 1989
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