丙烷CVI工艺热解炭沉积非均相反应动力学模拟

新型炭材料, 2016, 31(1): 77-86.

丙烷CVI工艺热解炭沉积非均相反应动力学模拟

汤哲鹏 ^1, , 徐伟 ^2, , 李爱军 ^3, , 张中伟 ^4, , 白瑞成 ^5, , 王俊山 ^6, , 任慕苏 ^7,

1.上海大学材料复合及先进分散技术教育部工程中心,上海,200072

2.上海大学材料复合及先进分散技术教育部工程中心,上海,200072

3.上海大学材料复合及先进分散技术教育部工程中心,上海,200072

4.航天材料及工艺研究所先进功能复合材料技术国防科技重点实验室,北京,100076

5.上海大学材料复合及先进分散技术教育部工程中心,上海,200072

6.航天材料及工艺研究所先进功能复合材料技术国防科技重点实验室,北京,100076

7.上海大学材料复合及先进分散技术教育部工程中心,上海,200072

基金项目: 上海人才发展资金(2011028) Doctoral Fund of Ministry of Education(20113108120019) 上海市科委基金(13521101202) Aviation Fund(2013ZFS6001) 航空基金(2013ZFS6001) 教育部博士点基金(20113108120019) Shanghai Committee of Science and Technology(13521101202) Shanghai Talent Development Fund(2011028)

关键词：模拟 , 热解炭 , 表面动力学 , 丙烷 , 化学气相渗透

Modeling of carbon deposition from propane in chemical vapor infiltration

Keywords： Modeling , Pyrocarbon , Surface kinetics , Propane , Chemical vapor infiltration

分别运用总括非均相反应机理和详细非均相反应机理,结合均相反应机理(包括285种气相组分,1 074个气相可逆基元反应)来模拟C3H8在CVI工艺条件下炭纤维表面热解炭的沉积过程,进而对实验中的气相组分和热解炭的形成过程进行预测.总括非均相反应机理对炭沉积反应进行了简化处理,气相中的烃组分直接在表面脱氢沉积为热解炭;而详细非均相反应机理则利用表面基元反应来描述热解炭沉积过程,包括66种表面组分和250个表面基元反应.本文以C3H8为炭源,N2为稀释气体,温度1 173～1 323 K、低压(2.6 kPa)和滞留时间为0.5 ～4 s条件下的连续搅拌釜反应器为模型进行模拟,气相组成和沉积动力学两方面的预测与实验结果都较好吻合.计算表明在该设定条件下热解炭的前驱体主要为不饱和小分子(C2H2和C2H4)和甲基,进而利用这些组分定量解释热解炭的沉积动力学.

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