Modelling and simulation of two-bed PSA process for separating H2 from methane steam reforming 被引量：11

Modelling and simulation of two-bed PSA process for separating H2 from methane steam reforming

下载PDF

导出

摘要 Methane steam reforming is the main hydrogen production method in the industry. The product of methane steam reforming contains H2, CH4, CO and CO2 and is then purified by pressure swing adsorption(PSA) technology. In this study, a layered two-bed PSA process was designed theoretically to purify H2 from methane steam reforming off gas. The effects of adsorption pressure, adsorption time and purgeto-feed ratio(P/F ratio) on process performance were investigated to design a PSA process with more than99.95% purity and 80% recovery. Since the feed composition of the PSA process changes with the upstream process, the effect of the feed composition on the process performance was discussed as well.The result showed that the increase of CH4 concentration, which was the weakest adsorbate, would have a negative impact on product purity. Methane steam reforming is the main hydrogen production method in the industry. The product of methane steam reforming contains H2, CH4, CO and CO2 and is then purified by pressure swing adsorption（PSA） technology. In this study, a layered two-bed PSA process was designed theoretically to purify H2 from methane steam reforming off gas. The effects of adsorption pressure, adsorption time and purgeto-feed ratio（P/F ratio） on process performance were investigated to design a PSA process with more than99.95% purity and 80% recovery. Since the feed composition of the PSA process changes with the upstream process, the effect of the feed composition on the process performance was discussed as well.The result showed that the increase of CH4 concentration, which was the weakest adsorbate, would have a negative impact on product purity.

作者 Huiru Li Zuwei Liao Jingyuan Sun Binbo Jiang Jingdai Wang Yongrong Yang

机构地区 Zhejiang Provincial Key Laboratory of Advanced Chemical Engineering Manufacture Technology State Key Laboratory of Chemical Engineering

出处《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2019年第8期1870-1878,共9页 中国化学工程学报（英文版）

基金 The financial support from the project of National Natural Science Foundation of China(21822809&61590925) the National Science Fund for Distinguished Young Scholars(21525627)

关键词 Hydrogen Adsorption PURITY Recovery FEED COMPOSITION Hydrogen Adsorption Purity Recovery Feed composition

分类号 O64 [理学—物理化学]

引文网络
相关文献

参考文献2

1Hao Yang Maochu Gong Yaoqiang Chen.Preparation of activated carbons and their adsorption properties for greenhouse gases:CH_4 and CO_2[J].Journal of Natural Gas Chemistry,2011,20(5):460-464. 被引量：9
2张湜,陈文亮,李晖,张亚兵,韦萍.真空变压吸附沼气净化过程的仿真研究[J].化工学报,2013,64(4):1300-1305. 被引量：9

二级参考文献23

1戴先知,刘应书.变压吸附过程数学模型及其应用[J].低温与特气,2006,24(1):36-42. 被引量：6
2Chaffee A L, Knowles G R Liang Z J, Zhang J, Xiao R Webley P A. Int J Greenh Gas Control, 2007, 1(1): 11.
3Xu X C, Song C S, Andresen J M, Miller B G, Scaroni A W. Microporous Mesoporous Mater, 2003, 62(1-2): 29.
4Idem R, Tontiwachwuthikul P. Ind Eng Chem Res, 2006, 45(8)2413.
5Zhou L, Liu X M, Li J W, Wang N, Wang Z, Zhou Y R Chem Phys Lett, 2005, 413(1-3): 6.
6Zhao H L, Hu J, Wang J J, Zhou L H, Liu H L. Acta Phys -Chim Sin, 2007, 23(6): 801.
7Warmuzinski K, Tanczyk M. Chem Eng Proc, 1997, 36:89.
8Kim S, Ida J, Guliants V V, Lin J Y S. J Phys Chem B, 2005, 109(13): 6287.
9MacGibbon R M A, Badheka R, Sermon P A. J Sol-Gel Sci Technol, 2004, 32(1-3): 53.
10Bae Y S, Moon J H, Ahn H, Lee C H. Korean J Chem Eng, 2004, 21(3): 712.

共引文献16

1黄锦锋,黄彪,陈翠霞,林冠锋,陈学榕,陈燕丹,谭非,吴耿烽.机械力辅助氯化锌活化法制备甘蔗渣活性炭[J].林业科学,2012,48(10):131-135. 被引量：6
2段延萍.高比表面积活性炭的制备及应用现状[J].化工技术与开发,2012,41(11):35-38. 被引量：5
3李勇,李磊,闻霞,王峰,赵宁,肖福魁,魏伟,孙予罕.二次嫁接法制备氨基修饰的硅基二氧化碳吸附剂[J].燃料化学学报,2013,41(9):1122-1128. 被引量：7
4银醇彪,张东辉,鲁东东,张正旺.数值模拟和优化变压吸附流程研究进展[J].化工进展,2014,33(3):550-557. 被引量：10
5王海鸿,刘应书,李子宜,杨雄.一种改进的LDF模型及其在活性炭吸附中的应用[J].化工学报,2014,65(10):3953-3959. 被引量：3
6李素琼.机械力-磷酸法木质活性炭的制备[J].大庆师范学院学报,2014,34(6):53-62. 被引量：1
7王俊,李晖,曹逊,陈祎,张艳,韦萍.微波辅助对秸秆厌氧发酵过程的影响[J].江苏农业科学,2015,43(1):251-253. 被引量：3
8黄毅雄,陈树军,付越,安家荣,赵世杰.天然气净化脱CO_2吸附剂的微观结构分析[J].油气田地面工程,2016,35(6):1-4. 被引量：1
9刘皓,邓保炜,陈娟,白晓慧,张楠.兰炭粉粒度对活性炭性能的影响[J].炭素技术,2016,35(4):38-40. 被引量：1
10祝显强,刘应书,杨雄,刘文海,李永玲.中间气两步充压对快速真空变压吸附制氧的影响[J].化工学报,2016,67(10):4264-4272. 被引量：9

同被引文献59

1Bing Yuan,Junbo Xu,Zaisha Mao,Yongqiang Zhang,Chao Yang.Particle-resolved simulation of packed beds by non-body conforming locally refined orthogonal hexahedral mesh[J].Chinese Journal of Chemical Engineering,2019,27(11):2635-2642. 被引量：5
2Ze-Zhang Song,Abide Abula,Jun-Yi Zhao,Guang-Di Liu,Ming-Rui Li,Dai-Lin Yang,Yun-Long Wang.A novel hybrid thermodynamic model for pore size distribution characterisation for shale[J].Petroleum Science,2022,19(3):963-978. 被引量：3
3张进华,王鹏,李雪飞,李兰廷,车永芳,曲思建,梁大明,许德平.CH_(4)/N_(2)在椰壳活性炭上吸附平衡和动力学扩散机制[J].煤炭学报,2020,45(S01):427-435. 被引量：1
4宁平,谷俊杰,BartHJ,王安忠.边流效应对固定床吸附器穿透曲线的影响[J].化工学报,1998,49(6):678-682. 被引量：10
5付大春.大型往复式与离心式富氢气压缩机组的选型比较[J].化工设备与管道,2010,47(3):25-28. 被引量：7
6孔祥东,钟伟民,杜文莉,钱锋.Three Stage Equilibrium Model for Coal Gasification in Entrained Flow Gasifiers Based on Aspen Plus[J].Chinese Journal of Chemical Engineering,2013,21(1):79-84. 被引量：10
7Zengzhi Du,Chunxi Li,Wei Sun,Jianhong Wang.A simulation of diesel hydrotreating process with real component method[J].Chinese Journal of Chemical Engineering,2015,23(5):780-788. 被引量：1
8张桥,杨敏博,刘桂莲.基于约束松弛的多杂质氢网络优化[J].计算机与应用化学,2015,32(11):1377-1382. 被引量：3
9杨声,梁嘉能,杨思宇,钱宇.煤制气中甲烷化余热利用集成串级吸收式制冷新工艺[J].化工学报,2016,67(3):779-787. 被引量：1
10Baojun Li,Gaohong He,Xiaobin Jiang,Yan Dai,Xuehua Ruan.Pressure swing adsorption/membrane hybrid processes for hydrogen purification with a high recovery[J].Frontiers of Chemical Science and Engineering,2016,10(2):255-264. 被引量：9

引证文献11

1Mohsin Ali,Liao Zuwei,Yao Yang,Sun Jingyuan,Jiang Binbo,Wang Jingdai,Yang Yongrong.Modeling and Optimization of Ethane Steam Cracking Process in An Industrial Tubular Reactor with Improved Reaction Scheme[J].China Petroleum Processing & Petrochemical Technology,2020,22(4):117-125. 被引量：3
2Yonghou Xiao,Shuang Qiu,Qidong Zhao,Yuhao Zhu,Chirag BGodiya,Gaohong He.Numerical simulation of low-concentration CO_(2) adsorption on fixed bed using finite element analysis[J].Chinese Journal of Chemical Engineering,2021,34(8):47-56. 被引量：3
3Xuehua Ruan,Wenbo Huo,Jiaming Wang,Minggang Guo,Wenji Zheng,Yun Zou,Aibin Huang,Jianxiang Shou,Gaohong He.Multi-technique integration separation frameworks after steam reforming for coal-based hydrogen generation[J].Chinese Journal of Chemical Engineering,2021,34(7):163-172. 被引量：3
4张超,陈健,殷文华,沈圆辉,钮朝阳,余秀鑫,张东辉,唐忠利.变压吸附氢气纯化过程瞬态分析[J].化工学报,2022,73(1):308-321. 被引量：3
5Tao Tian,Yayan Wang,Bing Liu,Zhaoyang Ding,Xinxi Xu,Meisheng Shi,Jun Ma,Yanjun Zhang,Donghui Zhang.Simulation and experiment of six-bed PSA process for air separation with rotating distribution valve[J].Chinese Journal of Chemical Engineering,2022,35(2):329-337. 被引量：1
6伊迎秋,李广学,姚宗城.基于组态王的低浓度煤矿瓦斯抑爆式变压吸附的仿真与模拟[J].工业控制计算机,2022,35(6):53-55. 被引量：3
7Chun Deng,Xuantong Lu,Qixin Zhang,Jian Liu,Jui-Yuan Lee,Xiao Feng.Fuzzy optimization design of multicomponent refinery hydrogen network[J].Chinese Journal of Chemical Engineering,2022,35(8):125-139.
8周迎千,冯霄,杨敏博.基于压缩机选型的炼厂氢网络集成[J].清华大学学报（自然科学版）,2023,63(5):723-729.
9徐汉城,李广学,张陈.低浓度煤层气变压吸附制甲烷研究进展[J].现代化工,2023,43(9):57-60. 被引量：3
10麻蓉,张桥.PSA-低温甲醇洗-膜分离耦合的氢气分离系统建立与模拟[J].化工学报,2023,74(10):4201-4207.

二级引证文献19

1郑云栋,杨松柏,鲁浩然,祁小娟,翟迎春,闫飞.乙烷裂解炉的模拟分析[J].炼油技术与工程,2022,52(12):41-44. 被引量：2
2Deng Zhonghuo,Dai Lishun,Niu Chuanfeng,Jia Yanzi,Wei Xiaoli,Cai Xinheng.Effects of Hydrotreating Severity on Hydrocarbon Compositions and Deep Catalytic Cracking Product Yields[J].China Petroleum Processing & Petrochemical Technology,2021,23(3):112-118. 被引量：1
3谭遥,李琦,王捷,刘蔷,黄晨直,班久庆.掺氢天然气分离工艺方案及经济性分析[J].石油与天然气化工,2023,52(4):41-47. 被引量：3
4杜刚.基于无线传输技术的矿用新型瓦斯监控系统设计[J].西部探矿工程,2023,35(8):102-105. 被引量：1
5肖鑫,韩郑良,王一凡.基于复合吸附剂的固定除湿床传递特性的数值模拟[J].东华大学学报（自然科学版）,2023,49(5):97-104.
6徐汉城,李广学,张陈.低浓度煤层气变压吸附制甲烷研究进展[J].现代化工,2023,43(9):57-60. 被引量：3
7郭强,赵文凯,肖永厚.增强流体扰动强化变压吸附甲硫醚/氮气分离的数值模拟[J].化工进展,2023,42(S01):64-72.
8张硕,宋强,张玉龙,张佳丽,孙琦.变压吸附提纯氢气的研究进展及应用[J].辽宁石油化工大学学报,2023,43(6):30-36. 被引量：2
9李战华,邬鑫,逯晓臻.低瓦斯煤矿综采工作面采煤机综合控制研究[J].能源与节能,2024(2):246-249. 被引量：1
10孔德齐,张莹莹,武文玲,马军,宋振兴,张东辉,张彦军.六塔变压吸附制氧工艺的模拟与分析[J].化工学报,2023,74(12):4934-4944.

1Alessandro Bazzi.Editorial of the Open Journal on Modelling and Simulation[J].Open Journal of Modelling and Simulation,2013,1(3):25-26.
2Akila Belhadi,Mohamed Trari,Chérifa Rabia,Ouiza Cherifi.Methane Steam Reforming on Supported Nickel Based Catalysts. Effect of Oxide ZrO2, La2O3and Nickel Composition[J].Open Journal of Physical Chemistry,2013,3(2):89-96. 被引量：1
3Liang Hai,Wang Wanting.Synthesis of 2-Amino-4,6-dimethoxypyrimidine(ADM)[J].Plant Diseases and Pests,2019,10(2):1-3.
4Kuo-Hsin Lin,Cheng-You Tsai,Alex C. C. Chang.Preparation of High Surface Area Mesoporous Ni2xCe1-xO2(x = 0, 0.05, 0.13, 0.2) and Its Applications in Methane Steam Reforming[J].Modern Research in Catalysis,2013,2(2):42-49.
5Kathya de la Luz-Hernández,Yamilé Rabasa,Raquel Montesinos,Dasha Fuentes,Julio Felipe Santo Tomás,Orlando Morales,Yadira Aguilar,Blanca Pacheco,Adolfo Castillo,Ana Maria Vazquez.Comparability Assessments of Process Changes Made during Development of Anti-Idiotype Vaccine[J].World Journal of Vaccines,2014,4(1):24-32.
6Tianying Lin,Ang Liu,Xiaopei Zhang,He Li,Liping Wang,Hailong Han,Ze Chen,Xiaoping Liu,Haibin Lü.Analyzing OAM mode purity in optical fibers with CNN-based deep learning[J].Chinese Optics Letters,2019,17(10):108-113.
7Mohamed H. Mohamed,Kerry M. Peru,John V. Headley,Lee D. Wilson.Chitosan Biopolymers for Analysis of Organic Acids in Aquatic Environments of Treatment Wetlands[J].Journal of Geoscience and Environment Protection,2017,5(6):214-225.
8Yilan Tian,Zhongwu Liu,Guoqing Zhang.Recovering REEs from NdFeB wastes with high purity and efficiency by leaching and selective precipitation process with modified agents[J].Journal of Rare Earths,2019,37(2):205-210. 被引量：10
9Yoke-Rung Wong,Xin Pang.A New Characterization Approach of Weld Nugget Growth by Real-Time Input Electrical Impedance[J].Engineering（科研）,2014,6(9):516-525. 被引量：2
10L. M. Chechin.On the Modern Status of the Universe Rotation Problem[J].Journal of Modern Physics,2013,4(8):126-132.

Chinese Journal of Chemical Engineering

2019年第8期

浏览历史

内容加载中请稍等...