CAJ | 학술논문

介绍了生物质热解的简单一级动力学模型和分布活化能模型,并利用这两种模型分别对玉米秸秆在15、25、30K/min升温速率下的热重分析数据进行了研究.利用简单一级动力学模型计算的活化能数值在7～54kJ/mol之间,指前因子在2.8×104～3.3×104min-1之间;利用分布式活化能模型计算的活化能数值在65～80kJ/mol之间,指前因子在1.9×105～3.0×10min-1之间.同时,分析了产生上述差异的原因,并通过研究分布活化能模型的计算结果得出分布活化能模型更能反映生物质热解动力学过程的结论.
개소료생물질열해적간단일급동역학모형화분포활화능모형,병이용저량충모형분별대옥미갈간재15、25、30K/min승온속솔하적열중분석수거진행료연구.이용간단일급동역학모형계산적활화능수치재7～54kJ/mol지간,지전인자재2.8×104～3.3×104min-1지간;이용분포식활화능모형계산적활화능수치재65～80kJ/mol지간,지전인자재1.9×105～3.0×10min-1지간.동시,분석료산생상술차이적원인,병통과연구분포활화능모형적계산결과득출분포활화능모형경능반영생물질열해동역학과정적결론.
Determined kinetic parameters can be used for design and control of thermal decomposition process. One order kinetics model and distributed activation energy model (DAEM) were compared. The different activation energy values from 7kJ/mol to 54kJ/mol for one order kinetics model and from 65kJ/mol to 80kJ/mol for DAEM were used. The frequency factors were also different, from 2.8×104 min-1 to 3.3 × 104 min-1 for one order kinetics model and from 1.9x105 min-1 to 3.0 × 105 min-1 for DAEM. These differences were also analysized. The results show that DAEM fits the experimental data very well.