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氮掺杂碳材料分离烟道气的分子模拟 被引量:1

Molecular simulation of flue gas separation by nitrogen-doped carbon materials
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摘要 针对氮掺杂碳材料的微孔孔径分布和氮含量对CO_(2)吸附的单一影响难以量化问题,构建碳基吸附剂的狭缝孔模型,使用蒙特卡洛模拟方法,定量研究孔径结构、氮掺杂量、吸附温度对CO_(2)吸附及烟道气分离性能的影响,并从吸附质的相对浓度分布角度分析吸附机理。结果表明:CO_(2)吸附容量受孔径分布和氮掺杂量的协同作用,但0.8 nm以下的窄微孔对吸附量影响更大,1.5×10^(5)Pa时在模拟孔径范围内0.8 nm处CO_(2)吸附量最大为6.082 mol·kg^(-1),氮掺杂可以提高烟道气分离系数。研究结果可为碳基吸附剂的制备、改性和实际应用提供参考。 In order to solve the problem that the single effect of micro-pore size distribution and nitrogen content of nitrogen-doped carbon materials on CO_(2)adsorption are difficult to quantify,a slit pore model of carbon-based adsorbents was constructed,and the effects of pore sizes,nitrogen doping amounts and adsorption temperature on CO_(2)adsorption and flue gas separation performance were quantitatively studied by Monte Carlo simulation.The adsorption mechanism was analyzed from the perspective of relative concentration distribution of adsorbents.The results show that CO_(2)adsorption capacity is affected by the synergistic effect of pore size distribution and nitrogen doping,and the narrow micro-pores below 0.8 nm have a greater effect on the adsorption capacity.The maximum CO_(2)adsorption capacity at 0.8 nm in the simulated pore sizes range is 6.082 mol·kg^(-1)at 1.5×10^(5)Pa,and nitrogen doping can improve the separation coefficient of flue gas.The research results can provide a reference for the preparation,modification and practical application of carbon-based adsorbents.
作者 彭洁 王子瑶 唐忠利 李文彬 张东辉 PENG Jie;WANG Ziyao;TANG Zhongli;LI Wenbin;ZHANG Donghui(School of Chemical Engineering and Technology,Tianjin University,Tianjin 300350,China)
机构地区 天津大学化工学院
出处 《高校化学工程学报》 北大核心 2025年第1期131-140,共10页 Journal of Chemical Engineering of Chinese Universities
基金 国家重点研发项目(2019YFB1505002)。
关键词 碳材料 吸附 氮掺杂 烟道气 蒙特卡洛模拟 carbon materials adsorption nitrogen doping flue gas Monte Carlo simulation
分类号 TQ028.1 [化学工程]
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  • 1赵亮,周宏方,尹艳山,王邓惠.活性炭吸附CO2的研究进展[J].炭素技术,2019,38(5):17-22. 被引量:4
  • 2吴迪,孙可明.不同温度条件下型煤吸附CH_4/CO_2混合气的实验研究[J].岩石力学与工程学报,2013,32(S2):3291-3296. 被引量:19
  • 3何余生,李忠,奚红霞,郭建光,夏启斌.气固吸附等温线的研究进展[J].离子交换与吸附,2004,20(4):376-384. 被引量:194
  • 4钟璟,黄维秋,殷开梁.分子模拟技术在气体膜分离研究中的应用[J].化工进展,2005,24(7):743-748. 被引量:9
  • 5徐南平,邢卫红,赵宜江.无机膜分离技术及应用[M].北京:化学工业出版社,2003
  • 6Kazemi H, Gilman J R. Analytical and numerical solution of oil recovery from fractured reservoirs with empirical transfer functions [J] .SPE 19849, 1992.
  • 7Kazemi H. Effect of anisotropy and stratification on pressure transient analysis of wells with restricted flow entry [ C] . SPE 2153, 1969.
  • 8Warren J E, Root P J. The behaviors of naturally fractured reservoir [C] .SPE 426, 1963.
  • 9De Swaan 0 A. Analytic solutions for determining naturally fractured reservoir properties by well testing [ C ] .SPE5346, 1976.
  • 10Gruber A, Salimath P S, Chen J H. Direct numerical simulation of laminar flame-wall interaction for a novel H2-selective membrane/injector configuration [J]. International Journal of Hydrogen Energy, 2014, 39(11): 5906-5918.

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高校化学工程学报
2025年 第1期

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