Simulation and analysis of dual-reflux pressure swing adsorption for air separation

doi:10.11949/0438-1157.20190172

Abstract

Abstract:

Double reflux pressure swing adsorption is a pressure swing adsorption process in which the feed is carried out in the middle of the adsorption tower, and the top and bottom of the tower are respectively reflowed with light and heavy components, and two high purity and high recovery product gases can be simultaneously produced. In this paper, a LiLSX zeolite synthesized by the laboratory was used as the adsorbent, meanwhile, numerical simulation of a two-bed dual-reflux pressure swing adsorption air separation process was carried out with feed mixture (78%N₂/21%O₂/1%Ar) using the commercial software Aspen Adsorption. The adsorption and desorption pressure are 2 bar and 0.3 bar, the feed flow rate is 0.4 m³/h, the light and the heavy component reflux flow rate are 0.095 L/min and 5.22 L/min. Ultimately, the purity of O₂ and N₂ reach 95.67% and 98.25% in their respective product gas, and the recovery rates are 94.60% and 99.91%, respectively. Besides, effects of operating parameters (the feed position, duration of feed step, light reflux flow rate, heavy product flow rate) on the process performances were investigated, which was more helpful for understanding this process.

Key words: dual-reflux, pressure swing adsorption, air separation, LiLSX zeolite, numerical simulation

摘要：

双回流变压吸附是一种在吸附塔中间位置进料，塔顶和塔底分别采用轻、重组分回流的变压吸附过程，能够同时生产两种高纯度、高回收率的产品气。以实验室自主合成的LiLSX分子筛为吸附剂，利用Aspen Adsorption模拟软件，对进料组成为78%N₂/21%O₂/1%Ar的实际空气进行了两塔双回流变压吸附的模拟研究。模拟结果表明：当原料气为78%N₂/21%O₂/1%Ar，吸附压力为2 bar(1 bar=10⁵ Pa)，解吸压力为0.3 bar，进料量为0.4 m³/h，轻组分回流流量为0.095 L/min，重组分回流流量为5.22 L/min时，能够得到体积分数为95.67%的O₂和体积分数为98.25%的N₂，回收率分别为94.60%和99.91%。并且进一步探究了进料位置、吸附时间、轻组分回流流量、重组分产品气流量等因素对O₂和N₂两种产品气纯度和回收率的影响。

关键词: 双回流, 变压吸附, 空气分离, LiLSX沸石, 数值模拟

CLC Number:

TQ 028.1

Yayan WANG, Caixia TIAN, Zhaoyang DING, Zhongli TANG, Donghui ZHANG. Simulation and analysis of dual-reflux pressure swing adsorption for air separation[J]. CIESC Journal, 2019, 70(10): 4002-4011.

汪亚燕, 田彩霞, 丁兆阳, 唐忠利, 张东辉. 基于双回流变压吸附工艺的空气分离模拟及分析[J]. 化工学报, 2019, 70(10): 4002-4011.

References 32

1	Skarstrom C W . Use of adsorption phenomena in automatic plant-type gas analyzers[J]. Annals of the New York Academy of Sciences, 1959, 72(13): 751-763.
2	Seshan K . Pressure swing adsorption[J]. Applied Catalysis, 1989, 46(1): 180.
3	Smith A R , Klosek J . A review of air separation technologies and their integration with energy conversion processes[J]. Fuel Processing Technology, 2001, 70(2): 115-134.
4	Castle W F . Air separation and liquefaction: recent developments and prospects for the beginning of the new millennium[J]. International Journal of Refrigeration, 2002, 25(1): 158-172.
5	Sircar S , Rao M B , Golden T C . Fractionation of air by zeolites[J]. Studies in Surface Science & Catalysis, 1999, 120(99): 395-423.
6	Sircar S . Air fractionation by adsorption[J]. Separation Science, 1988, 23(14/15): 18.
7	Sircar S , Golden T C . Purification of hydrogen by pressure swing adsorption[J]. Fuel & Energy Abstracts, 2000, 35(5): 667-687.
8	Step G K , Petrovichev M V . Pressure swing adsorption for air separation and purification[J]. Chemical & Petroleum Engineering, 2002, 38(3/4): 154-158.
9	耿云峰, 耿晨霞, 张文效 . 变压吸附(PSA)空分制氧技术进展[J]. 煤化工, 2003, 31(1): 33-36.
	Geng Y F , Geng C X , Zhang W X . Technology development of pressure swing adsorption for oxygen generation[J]. Coal Chemical Industry, 2003, 31(1): 33-36.
10	李杰, 周理 . 变压吸附空分制氧的技术进展[J]. 化学工业与工程, 2004, 21(3): 201-205.
	Li J , Zhou L . Progress in oxygen separation from air by pressure swing adsorption[J]. Chemical Industry and Engineering, 2004, 21(3): 201-205.
11	侯瑞宏 . 国外变压吸附空分制氧技术进展[J]. 黎明化工, 1994, (6): 10-12.
	Hou R H . Progress in foreign oxygen separation from air by pressure swing adsorption[J]. Dawn Chemicals, 1994, (6): 10-12.
12	祝显强, 刘应书, 杨雄, 等 . 我国变压吸附制氧吸附剂及工艺研究进展[J]. 化工进展, 2015, 34(1): 19-25.
	Zhu X Q , Liu Y S , Yang X , et al . Progress of modified adsorbent and pressure swing adsorption for oxygen production in China[J]. Chemical Industry and Engineering Progress, 2015, 34(1): 19-25.
13	Leavitt F W . Air separation pressure swing adsorption process: US5074892A[P]. 1991-12-24.
14	Diagne D , Goto M , Hirose T . New PSA process with intermediate feed inlet position operated with dual refluxes: application to carbon dioxide removal and enrichment[J]. Journal of Chemical Engineering of Japan, 2005, 27(1): 85-89.
15	Kearns D T , Webley P A . Modelling and evaluation of dual-reflux pressure swing adsorption cycles(Ⅰ): Mathematical models[J]. Chemical Engineering Science, 2006, 61(22): 7223-7233.
16	Kearns D T , Webley P A . Modelling and evaluation of dual reflux pressure swing adsorption cycles(Ⅱ): Productivity and energy consumption[J]. Chemical Engineering Science, 2006, 61(22): 7234-7239.
17	Ruthven D M , Farooq S . Air separation by pressure swing adsorption[J]. Gas Separation & Purification, 1990, 4(3): 141-148.
18	Ebner A D , Ritter J A . Equilibrium theory analysis of dual reflux PSA for separation of a binary mixture[J]. AIChE Journal, 2010, 50(10): 2418-2429.
19	Schell J , Casas N , Mazzotti M . Pre-combustion CO₂ capture for IGCC plants by an adsorption process[J]. Energy Procedia, 2009, 1(1): 655-660.
20	Spoorthi G , Thakur R S , Kaistha N , et al . Process intensification in PSA processes for upgrading synthetic landfill and lean natural gases[J]. Adsorption-Journal of the International Adsorption Society, 2011, 17(1): 121-133.
21	Thakur R S , Kaistha N , Rao D P . Process intensification in duplex pressure swing adsorption[J]. Computers & Chemical Engineering, 2011, 35(5): 973-983.
22	Sivakumar S V , Rao D P . Modified duplex PSA(Ⅰ): Sharp separation and process intensification for CO₂-N₂-13X zeolite system[J]. Industrial & Engineering Chemistry Research, 2011, 50(6): 3426-3436.
23	Sivakumar S V , Rao D P . Modified duplex PSA(Ⅱ): Sharp separation and process intensification for N₂-O₂-5A zeolite system[J]. Industrial & Engineering Chemistry Research, 2011, 50(6): 3437-3445.
24	Diagne D , Goto M , Hirose T . Experimental study of simultaneous removal and concentration of CO₂ by an improved pressure swing adsorption process[J]. Energy Conversion & Management, 1995, 36(6/7/8/9): 431-434.
25	Diagne D , Goto M , Hirose T . Parametric studies on CO₂ separation and recovery by a dual reflux PSA process consisting of both rectifying and stripping sections[J]. Industrial & Engineering Chemistry Research, 1995, 34(9): 3083-3089.
26	Intyre J A M , Holland C E , Ritter J A . High enrichment and recovery of dilute hydrocarbons by dual-reflux pressure-swing adsorption[J]. Industrial & Engineering Chemistry Research, 2002, 41(14): 3499-3504.
27	Mcintyre J A , Ebner A D , Ritter J A . Experimental study of a dual reflux enriching pressure swing adsorption process for concentrating dilute feed streams[J]. Industrial & Engineering Chemistry Research, 2010, 49(4): 1848-1858.
28	Li D , Zhou Y , Shen Y , et al . Experiment and simulation for separating CO₂/N₂ by dual-reflux pressure swing adsorption process[J]. Chemical Engineering Journal, 2016, 297: 315-324.
29	鲁东东, 张正旺, 银醇彪, 等 . 双回流真空变压吸附空分模拟[J]. 现代化工, 2014, 34(4): 152-157.
	Lu D D , Zhang Z W , Yin C B , et al . Simulation of duplex vacuum pressure swing adsorption (duplex VPSA) process for air separation[J]. Modern Chemical Industry, 2014, 34(4): 152-157.
30	Tian C , Li D , Ding Z , et al . Experiment and simulation study of a dual reflux pressure swing adsorption process for separating N₂/O₂ [J]. Separation & Purification Technology, 2017, 189: 54-65.
31	Jee J G , Lee J S , Lee C H . Air separation by a small-scale two-bed medical O₂ pressure swing adsorption[J]. Industrial & Engineering Chemistry Research, 2001, 40(16): 3647-3658.
32	Rege S U , Yang R T . Limits for air separation by adsorption with LiX zeolite[J]. Industrial & Engineering Chemistry Research, 1997, 36(12): 5358-5365.

[1]	Jiahao SONG, Wen WANG. Study on coupling operation characteristics of Stirling engine and high temperature heat pipe [J]. CIESC Journal, 2023, 74(S1): 287-294.
[2]	Siyu ZHANG, Yonggao YIN, Pengqi JIA, Wei YE. Study on seasonal thermal energy storage characteristics of double U-shaped buried pipe group [J]. CIESC Journal, 2023, 74(S1): 295-301.
[3]	Zhanyu YE, He SHAN, Zhenyuan XU. Performance simulation of paper folding-like evaporator for solar evaporation systems [J]. CIESC Journal, 2023, 74(S1): 132-140.
[4]	Yifei ZHANG, Fangchen LIU, Shuangxing ZHANG, Wenjing DU. Performance analysis of printed circuit heat exchanger for supercritical carbon dioxide [J]. CIESC Journal, 2023, 74(S1): 183-190.
[5]	Zhiguo WANG, Meng XUE, Yushuang DONG, Tianzhen ZHANG, Xiaokai QIN, Qiang HAN. Numerical simulation and analysis of geothermal rock mass heat flow coupling based on fracture roughness characterization method [J]. CIESC Journal, 2023, 74(S1): 223-234.
[6]	Song HE, Qiaomai LIU, Guangshuo XIE, Simin WANG, Juan XIAO. Two-phase flow simulation and surrogate-assisted optimization of gas film drag reduction in high-concentration coal-water slurry pipeline [J]. CIESC Journal, 2023, 74(9): 3766-3774.
[7]	Lei XING, Chunyu MIAO, Minghu JIANG, Lixin ZHAO, Xinya LI. Optimal design and performance analysis of downhole micro gas-liquid hydrocyclone [J]. CIESC Journal, 2023, 74(8): 3394-3406.
[8]	Xiaosong CHENG, Yonggao YIN, Chunwen CHE. Performance comparison of different working pairs on a liquid desiccant dehumidification system with vacuum regeneration [J]. CIESC Journal, 2023, 74(8): 3494-3501.
[9]	Wenzhu LIU, Heming YUN, Baoxue WANG, Mingzhe HU, Chonglong ZHONG. Research on topology optimization of microchannel based on field synergy and entransy dissipation [J]. CIESC Journal, 2023, 74(8): 3329-3341.
[10]	Rui HONG, Baoqiang YUAN, Wenjing DU. Analysis on mechanism of heat transfer deterioration of supercritical carbon dioxide in vertical upward tube [J]. CIESC Journal, 2023, 74(8): 3309-3319.
[11]	Chen HAN, Youmin SITU, Bin ZHU, Jianliang XU, Xiaolei GUO, Haifeng LIU. Study of reaction and flow characteristics in multi-nozzle pulverized coal gasifier with co-processing of wastewater [J]. CIESC Journal, 2023, 74(8): 3266-3278.
[12]	Kexin HUANG, Tong LI, Anqi LI, Mei LIN. Mode decomposition of flow field in T-junction with rotating impeller [J]. CIESC Journal, 2023, 74(7): 2848-2857.
[13]	Fangzhe SHI, Yunhua GAN. Numerical simulation of start-up characteristics and heat transfer performance of ultra-thin heat pipe [J]. CIESC Journal, 2023, 74(7): 2814-2823.
[14]	Zhaolun WEN, Peirui LI, Zhonglin ZHANG, Xiao DU, Qiwang HOU, Yegang LIU, Xiaogang HAO, Guoqing GUAN. Design and optimization of cryogenic air separation process with dividing wall column based on self-heat regeneration [J]. CIESC Journal, 2023, 74(7): 2988-2998.
[15]	Xingchi ZHU, Zhiyuan GUO, Zhiyong JI, Jing WANG, Panpan ZHANG, Jie LIU, Yingying ZHAO, Junsheng YUAN. Simulation and optimization of selective electrodialysis magnesium and lithium separation process [J]. CIESC Journal, 2023, 74(6): 2477-2485.