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      Methyl Butanoate의 상세 화학 반응 메커니즘 자동 축소화를 통한 기초 반응 메커니즘의 생성 및 검증

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      https://www.riss.kr/link?id=A102075243

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      다국어 초록 (Multilingual Abstract)

      In this study, skeletal mechanisms are produced by directed relation graph with specified threshold value and sensitivity analysis based on species database from the directed relation graph. Skeletal mechanism is optimized through the elimination of u...

      In this study, skeletal mechanisms are produced by directed relation graph with specified threshold value and sensitivity analysis based on species database from the directed relation graph. Skeletal mechanism is optimized through the elimination of unimportant reaction steps by computational singular perturbation importance index. Reduction is performed for the detailed mechanism of methyl butanoate consisting of 264 species and 1219 elementary reactions. Validation shows acceptable agreement for auto-ignition delays in wide parametric ranges of pressure, temperature and equivalence ratio. Methyl butanoate has been proposed as a simple biodiesel surrogate although the alkyl chain consists of four carbon atoms. The resulting surrogate mechanism for n-heptane and MB consists of 76 species and 226 reaction steps including those for NOx.

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      목차 (Table of Contents)

      • ABSTRACT
      • 1. 서론
      • 2. 화학 반응 메커니즘 축소 방법론
      • 3. 상세 화학 반응 메커니즘 자동 축소화
      • 4. 결론
      • ABSTRACT
      • 1. 서론
      • 2. 화학 반응 메커니즘 축소 방법론
      • 3. 상세 화학 반응 메커니즘 자동 축소화
      • 4. 결론
      • References
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      참고문헌 (Reference)

      1 N. Peters, "The computation of stretched laminar methane-air diffusion flames using a reduced four-step mechanism" 68 : 17-29, 1987

      2 T.F. Lu, "Strategies for mechanism reduction for large hydrocarbons: n-heptane" 154 : 153-163, 2008

      3 K. E. Niemeyer, "Skeletal mechanism generation for surrogate fuels" Case western Reserve University 2010

      4 U. Maas, "Simplifying chemical kinetics:Intrinsic low-dimensional manifolds in composition space" 88 : 239-264, 1992

      5 T. Turanyi, "Reduction of large reaction mechanisms" 14 : 795-803, 1990

      6 M.D. Smooke, "Reduced kinetic mechanisms and asymptotic approximations for methan-air flames" Springer-Verlag 384 : 1-28, 1991

      7 W. J. Pitz, "Recent Progress in the development of diesel surrogate fuels" 37 : 330-350, 2011

      8 N. Peters, "Numerical Simulation of Combustion Phenomena" Springer 241 : 90-109, 1985

      9 A.S. Tomlin, "Mecahanism reduction for the oscillatory oxidation of hydrogen: Sensitivity and quasi-steady-sate analyses" 91 : 107-130, 1992

      10 T.F. Lu, "Linear time reduction of large kinetic mechanism with directed realtion graph: n-Heptane and iso-octane" 144 : 24-36, 2006

      1 N. Peters, "The computation of stretched laminar methane-air diffusion flames using a reduced four-step mechanism" 68 : 17-29, 1987

      2 T.F. Lu, "Strategies for mechanism reduction for large hydrocarbons: n-heptane" 154 : 153-163, 2008

      3 K. E. Niemeyer, "Skeletal mechanism generation for surrogate fuels" Case western Reserve University 2010

      4 U. Maas, "Simplifying chemical kinetics:Intrinsic low-dimensional manifolds in composition space" 88 : 239-264, 1992

      5 T. Turanyi, "Reduction of large reaction mechanisms" 14 : 795-803, 1990

      6 M.D. Smooke, "Reduced kinetic mechanisms and asymptotic approximations for methan-air flames" Springer-Verlag 384 : 1-28, 1991

      7 W. J. Pitz, "Recent Progress in the development of diesel surrogate fuels" 37 : 330-350, 2011

      8 N. Peters, "Numerical Simulation of Combustion Phenomena" Springer 241 : 90-109, 1985

      9 A.S. Tomlin, "Mecahanism reduction for the oscillatory oxidation of hydrogen: Sensitivity and quasi-steady-sate analyses" 91 : 107-130, 1992

      10 T.F. Lu, "Linear time reduction of large kinetic mechanism with directed realtion graph: n-Heptane and iso-octane" 144 : 24-36, 2006

      11 A. Massias, "Global reduced mechanisms for methane and hydrogen combustion with nitric oxide formation constructed with CSP data" 3 : 233-257, 1999

      12 J. L. Brakora, "Development and validation of a reduced reaction mechanism for biodiesel-fueled engine simulation" SAE 2008

      13 H. Wang, "Detailed reduction of reaction mechanisms for flame modeling" 87 : 365-370, 1991

      14 E. M. Fisher, "Detailed chemical kinetic mechanisms for combustion of oxygenated fuels" 28 : 1579-1586, 2000

      15 T.F. Lu, "Complex CSP for chemistry reduction and analysis" 126 : 1445-1455, 2001

      16 B. AKih-Kumgeh, "Comparative study of methyl butanoate and n-heptane high temperature autoignition" 24 (24): 2439-2448, 2010

      17 R. J. Kee, "Chemkin-II: A FORTRAN chemical Kinetics Package for the Analysis of Gas-Phase Chemical Kinetics" 1989

      18 A. Massias, "An algorithm for the construction of global reduced mechanisms with CSP data" 117 : 685-708, 1999

      19 J.Y. Chen, "A general procedure for constructing reduced reaction mechanisms with given independent relations" 57 : 89-94, 1988

      20 T.F. Lu, "A directed relation graph method for mechanism reduction" 30 : 1333-1341, 2005

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      2022 평가예정 재인증평가 신청대상 (재인증)
      2019-01-01 평가 등재학술지 유지 (계속평가) KCI등재
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      2009-01-01 평가 등재학술지 선정 (등재후보2차) KCI등재
      2008-01-01 평가 등재후보 1차 PASS (등재후보1차) KCI등재후보
      2007-01-01 평가 등재후보 1차 FAIL (등재후보1차) KCI등재후보
      2005-01-01 평가 등재후보학술지 선정 (신규평가) KCI등재후보
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      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 0.31 0.31 0.29
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.27 0.25 0.632 0.05
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