Biogas upgrading, economy and utilization: a review

被引:0
作者
Shams Forruque Ahmed
M. Mofijur
Karishma Tarannum
Anika Tasnim Chowdhury
Nazifa Rafa
Samiha Nuzhat
P. Senthil Kumar
Dai-Viet N. Vo
Eric Lichtfouse
T. M. I. Mahlia
机构
[1] Asian University for Women,Science and Math Program
[2] University of Technology Sydney,Centre for Technology in Water and Wastewater, School of Civil and Environmental Engineering, Faculty of Engineering and Information Technology
[3] Prince Mohammad Bin Fahd University,Mechanical Engineering Department
[4] United Nations High Commissioner for Refugees (UNHCR),Energy and Environment Unit
[5] Asian University for Women,Environmental Sciences Program
[6] Water and Life Bangladesh,Department of Chemical Engineering
[7] Sri Sivasubramaniya Nadar College of Engineering,Center of Excellence for Green Energy and Environmental Nanomaterials (CE@GrEEN)
[8] Nguyen Tat Thanh University,CNRS, IRD, INRAE, CEREGE
[9] Aix-Marseille Univ,State Key Laboratory of Multiphase Flow in Power Engineering
[10] Xi’an Jiaotong University,undefined
来源
Environmental Chemistry Letters | 2021年 / 19卷
关键词
Biogas utilization; Biogas upgrading technologies; Techno-economic analysis; Biogas purification; Biogas upgradation challenges; Biomethane;
D O I
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中图分类号
学科分类号
摘要
Biogas production is rising in the context of fossil fuel decline and the future circular economy, yet raw biogas requires purification steps before use. Here, we review biogas upgrading using physical, chemical and biological methods such as water scrubbing, physical absorption, pressure swing adsorption, cryogenic separation, membrane separation, chemical scrubbing, chemoautotrophic methods, photosynthetic upgrading and desorption. We also discuss their techno-economic feasibility. We found that physical and chemical upgrading technologies are near-optimal, but still require high energy and resources. Biological methods are less explored despite their promising potential. High-pressure water scrubbing is more economic for small-sized plants, whereas potassium carbonate scrubbing provides the maximum net value for large-sized plants.
引用
收藏
页码:4137 / 4164
页数:27
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[41]  
Alitalo A(2020)A case study on the electricity generation using a micro gas turbine fuelled by biogas from a sewage treatment plant Environ Chem Lett 18 1581-315
[42]  
Niskanen M(2017)Membrane applications for microbial energy conversion: a review Renew Sustain Energy Rev 78 933-304
[43]  
Aura E(2015)Biogas system in rural China: upgrading from decentralized to centralized? RSC Adv 5 24399-651
[44]  
Al-Mamoori A(2019)Membrane gas separation technologies for biogas upgrading J Membr Sci 573 97-942
[45]  
Krishnamurthy A(2021)Mixed matrix membranes containing MOF@ COF hybrid fillers for efficient CO2/CH4 separation Environ Chem Lett 19 2921-875
[46]  
Rownaghi AA(2013)Effects of anaerobic digestion of food waste on biogas production and environmental impacts: a review CLEAN–Soil Air, Water 41 917-655
[47]  
Rezaei F(2020)Environmental impact assessment of high pressure water scrubbing biogas upgrading technology Biofuels 153 307-132
[48]  
Andriani D(2014)Biogas-based fuels as renewable energy in the transport sector: an overview of the potential of using CBG, LBG and other vehicle fuels produced from biogas Biores Technol 12 315-903
[49]  
Rajani A(2018)Evaluation of carbon dioxide mass transfer in raceway reactors for microalgae culture using flue gases Front Chem Sci Eng 253 119770-183
[50]  
Santosa A(2020)Mature versus emerging technologies for CO 2 capture in power plants: key open issues in post-combustion amine scrubbing and in chemical looping combustion J Clean Prod 59 102003-11661
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