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[ Article ] | |
Journal of the KNST - Vol. 3, No. 1, pp. 8-13 | |
Abbreviation: KNST | |
ISSN: 2635-4926 (Print) | |
Print publication date 31 Mar 2020 | |
Received 07 Nov 2019 Revised 07 Jan 2020 Accepted 08 Feb 2020 | |
DOI: https://doi.org/10.31818/JKNST.2020.03.3.1.8 | |
Body 온도 특성 분석을 통한 In-Line Flame Arrester의 소염 성능 분석 | |
(재)한국조선해양기자재연구원 방폭전력팀 | |
Analysis of Quenching Performance of In-Line Flame Arrester by Analyzing Temperature Characteristics of Body | |
Explosion Protection Team, Korea Marine Equipment Research Institute | |
Correspondence to : *Sun-Kwon Lee Explosion Protection Team, Korea Marine Equipment Research Institute, Ulsan, Republic of Korea Tel: +82-52-280-9911 Fax: +82-52-280-9911 E-mail: sunkwonlee@komeri.re.kr | |
© 2020 Korea Society for Naval Science & Technology | |
Funding Information ▼ |
본 연구에서는 화염방지기 소염성능을 housing 온도 특성의 분석을 통해 유추할 수 있는 방법을 제안하였다. 특히 폭굉 조건에서 화염방지기의 Body 외부의 온도상승과 전이, 그리고 분포 특성 확인을 통해 현상을 실험적으로 분석하고, 소염 성능과의 연계성을 검토하였다.
In this study, we proposed a method to infer flame arrester anti-flame performance through analysis of Housing temperature characteristics. Especially in the detonation condition, the phenomenon was analyzed experimentally by checking the temperature rise, the transition outside the body of the flame arrester, and the distribution characteristics.
Keywords: Flame Arrester, Quenching, External Temperature, Detonation 키워드: 화염방지기, 소염, 외부 온도, 폭굉 |
이 논문은 산업통상자원부에서 경제협력권산업육성사업(비즈니스협력형, P0004681)의 지원으로 수행된 연구임.
1. | Ko, S.J., Lee, S.K., Kang, G.H., “Performance test of end-of-line flame arrester,” Journal of the Korean Society of Marine Engineering, VOL. 42, pp. 197-202, 2018. |
2. | “Flame arresters-performance requirements, test methods and limits for use,” IEC Int. Standard 16852, Second edition, 2016. |
3. | Yoichi Okawa, Seiichiro Asano, Chongho Youn, Syunsuke Ikeda, Toshiharu Kagawa, “Experimental research on a newly developed detonation flame arrester,” SICE Annual Conference, 2008. |
4. | Joo, H.I., K. Duncan, G. Ciccarelli, “Flame-quenching performance of ceramic foam,” Combustion Science and Technology, VOL. 178, pp. 10-11, 2006. |
5. | M. H. Mat Kiah, R. M. Kasmani, “Experimental study on premixed flame acceleration in closed pipe,” Jurnal Teknologi. VOL. 62, no. 1 pp. 45-51, 2013. |
6. | Siti zubaidah sulaiman, Rafiziana M.Kasmani and Azeman mustafa, “Experimental study on the effect of curved tube of premixed hydrogen-air explosion,” Journal of Engineering Science and Technology, special issue on SOMCHE 2014 & RSCE 2014 conference, pp. 50-60, 2015. |
7. | ShaoChen Sun, Yuan Shu, Yu Feng, DaChao Sun, HaiTao Long and MingShu Bi, “Numerical simulation of detonation wave propagation and quenching process in in-line crimped-ribbon flame arrester,” Cogent Engineering, 2018. |