Indexed by:
期刊论文
First Author:
Chen, Bo
Correspondence Author:
He, GH (reprint author), Dalian Univ Technol, Sch Chem Engn, Res & Dev Ctr Membrane Sci & Technol, State Key Lab Fine Chem, Dalian 116024, LN, Peoples R China.
Co-author:
Jiang, Xiaobin,Xiao, Wu,Dong, Yanan,El Hamouti, Issam,He, Gaohong
Date of Publication:
2016-08-01
Journal:
JOURNAL OF NATURAL GAS SCIENCE AND ENGINEERING
Included Journals:
SCIE、EI、Scopus
Document Type:
J
Volume:
34
Page Number:
563-574
ISSN No.:
1875-5100
Key Words:
Enhanced gas recovery; Process intensification; Natural gas
pretreatment; Membrane gas separation
Abstract:
Membrane-based natural gas pretreatment process is able to efficiently recover hydrocarbons and separate low-cost CO2 for enhanced gas recovery (EGR). Dual-membrane module (DMM) is an enhanced module configuration for membrane gas separation, which synchronously recovering CO2 and hydrocarbons by housing CO2-selective and hydrocarbon-selective membranes in the same module. Implementing DMMs in natural gas pretreatment system could significantly improve the separation performance of membranes, and further reduce investment and operational costs; however, the impacts of separation sequence still require intensive investigations. In this work, two DMM-based processes are proposed and compared with conventional single-membrane-based processes, aiming to find the optimal separation sequence and quantify the enhancing effects of DMMs. The results indicate that condensation-DMM is the optimal process design, which is able to provide 90-mol%-purity CO2 for EGR, and reduce 3-12% investment cost and CO2 avoidance cost. The sensitivity analysis of membrane selectivity shows that, the DMM-based processes demands lower investment cost than single membrane -based processes with elevated membrane selectivities, and the DMM-condensation becomes the best-performance process design. The effect implies that the synergetic enrichment effect inside DMMs could amplify the impacts of membrane selectivity, enabling the DMMs to provide higher separation performance. This work demonstrates the potential applications of DMMs, and indicates that employing DMM to natural gas industry is an effective solution for current-available and advanced membrane materials. (C) 2016 Elsevier B.V. All rights reserved.
Translation or Not:
no