Progress and industrialization development trends of the anaerobic digestion technologies for bio-natural gas
Abstract
Key words: bio-natural gas; anaerobic digestion; technological progress; industrialization; sustainable development
DOI: 10.25165/j.ijabe.20241704.9036
Citation: Zhu H G, Lu F L, Pan F H. Progress and industrialization development trends of the anaerobic digestion technologies for bio-natural gas. Int J Agric & Biol Eng, 2024; 17(4): 1–12.
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Lu Q, Jiang Z W, Tang P F, Yu C J, Jiang F Z, Huang J Y, et al. Identify the potential driving mechanism of reconstructed bacterial community in reduce CO2 emissions and promote humus formation during cow manure composting. J Environ Manage, 2023; 345: 118896.
Mao Y L. Opportunities and challenges to promote the upgrading of China’s rural biogas industry under the high-quality green development. Agricultural Outlook, 2023; 19(6): 67–70. (in Chinese)
Sher F, Smječanin N, Hrnjić H, Karadža A, Omanović R, Šehović E, et al. Emerging technologies for biogas production: A critical review on recent progress, challenges and future perspectives. Process Saf Environ, 2024; 188: 834–859.
Lohani S P, Dhungana B, Horn H, Khatiwada D. Small-scale biogas technology and clean cooking fuel: Assessing the potential and links with SDGs in low-income countries - A case study of Nepal. Sustainable Energy Technologies and Assessments, 2021; 46: 101301.
Heidari-Maleni A, Taheri-Garavand A, Rezaei M, Jahanbakhshi A. Biogas production and electrical power potential, challenges and barriers from municipal solid waste (MSW) for developing countries: A review study in Iran. Journal of Agriculture and Food Research, 2023; 13: 100668.
Li J M, Xue M. Review and prospect on biogas development in China. Renewable Energy Resources, 2010; 28(3): 1–5.
Li J M, Xu W Y, Li B F, Zhang D L. The development dilemma and way out of China’s biogas industry. Renewable Energy Resources, 2020; 38(12): 1563–1568.
Zheng L, Cheng S K, Han Y Z, Wang M, Xiang Y, Guo J L, et al. Bio-natural gas industry in China: Current status and development. Renew Sust Energ Rev, 2020; 128: 109925.
Mazzanti M, Modica M, Rampa A. The biogas dilemma: An analysis on the social approval of large new plants. Waste Manage, 2021; 133: 10–18.
Luo E G, Zhang Y, Feng Y Y, Zhu L Z. The research on cours, current situation and future direction of China’s biogas industry development-based on the typical case analysis of Luohe area, Henan. Chinese Journal of Agricultural Resources and Regional Planning, 2022; 43(5): 132–142. (in Chinese)
Liao Z Q. Resource utilization of livestock and poultry manure in large-scale biogas projects. Yunnan Agriculture, 2022; 9: 50–52. (in Chinese)
Dang L, Hu W B, Qiu Z j, Tong M, Cui Y R, Liu H C. Review of life cycle assessment of agricultural biogas plants in China. Renewable Energy Resources, 2023; 41(4): 442–451.
Insam H, Gómez-Brandón M, Ascher J. Manure-based biogas fermentation residues - Friend or foe of soil fertility? Soil Biology and Biochemistry, 2015; 84: 1–14.
Sullivan T S, Stromberger M E, Paschke M W, Ippolito J A. Long-term impacts of infrequent biosolids applications on chemical and microbial properties of a semi-arid rangeland soil. Biol Fert Soils, 2006; 42: 258–266.
De Neve S, Sleutel S, Hofman G. Carbon mineralization from composts and food industry wastes added to soil. Nutr Cycl Agroecosys, 2003; 67: 13–20.
Grigatti M, Di Girolamo G, Chincarini R, Ciavatta C, Barbanti L. Potential nitrogen mineralization, plant utilization efficiency and soil CO2 emissions following the addition of anaerobic digested slurries. Biomass Bioenerg, 2011; 35(11): 4619–4629.
Gasser M-O, Chantigny M H, Angers D A, Bittman S, Buckley K E, Rochette P, et al. Plant-available and water-soluble phosphorus in soils amended with separated manure solids. J Environ Qual, 2012; 41(4): 1290–1300.
Masse D I, Croteau F, Masse L. The fate of crop nutrients during digestion of swine manure in psychrophilic anaerobic sequencing batch reactors. Bioresource Technol, 2007; 98(15): 2819–2823.
Braendli R C, Bucheli T D, Kupper T, Mayer J, Stadelmann F X, Tarradellas J. Fate of PCBs, PAHs and their source characteristic ratios during composting and digestion of source-separated organic waste in full-scale plants. Environ Pollut, 2007; 148(2): 520–528.
Bassil R J, Bashour I I, Sleiman F T, Abou-Jawdeh Y A. Antibiotic uptake by plants from manure-amended soils. Journal of Environmental Science and Health, Part B, 2013; 48(7): 570–574.
Lee S, Hung R, Schink A, Mauro J, Bennett J W. Arabidopsis thaliana for testing the phytotoxicity of volatile organic compounds. Plant Growth Regul, 2014; 74: 177–186.
Erga L. Research on the influence of policy on biogas production and utilization. Institute of Agricultural Economy and Development, 2020; 65p. doi: 10.27630/d.cnki.gznky.2020.000824. (in Chinese)
Wang X J, Lu X G, Yang G H, Feng Y Z, Ren G X, Han X H. Development process and probable future transformations of rural biogas in China. Renew Sust Energ Rev, 2016; 55: 703–712.
Abram S, Atkins E, Dietzel A, Jenkins K, Kiamba L, Kirshner J, et al. Just Transition: A whole-systems approach to decarbonisation. Clim Policy, 2022; 22(8): 1033–1049.
Gupta P, Kurien C, Mittal M. Biogas (a promising bioenergy source): A critical review on the potential of biogas as a sustainable energy source for gaseous fuelled spark ignition engines. Int J Hydrogen Energ, 2023; 48(21): 7747–7769.
Robinson B L, Clifford M J, Selby G. Towards fair, just and equitable energy ecosystems through smart monitoring of household-scale biogas plants in Kenya. Energy Res Soc Sci, 2023; 98: 103007.
Mistretta M, Gulotta T M, Caputo P, Cellura M. Bioenergy from anaerobic digestion plants: Energy and environmental assessment of a wide sample of Italian plants. Sci Total Environ, 2022; 843: 157012.
Sarkar A, Saha U K. A critique on the research activities and potential benefits of dual-fuel diesel engines run on biogas and oxygenated liquid fuels. J Eng Gas Turbines Power, 2019; 141(6): 1–26.
Vasco-Correa J, Khanal S, Manandhar A, Shah A. Anaerobic digestion for bioenergy production: Global status, environmental and techno-economic implications, and government policies. Bioresource Technol, 2018; 247: 1015–1026.
Brémond U, Bertrandias A, Steyer J, Bernet N, Carrere H. A vision of European biogas sector development towards 2030: Trends and challenges. Journal of Cleaner Production, 2021; 287: 125065.
D’Adamo I, Falcone P M, Ferella F. A socio-economic analysis of biomethane in the transport sector: The case of Italy. Waste Manage, 2019; 95: 102–115.
Chasnyk O, Solowski G, Shkarupa O. Historical, technical and economic aspects of biogas development: Case of Poland and Ukraine. Renew Sust Energ Rev, 2015; 52: 227–239.
Feiz R, Johansson M, Lindkvist E, Moestedt J, Paledal S N, Ometto F. The biogas yield, climate impact, energy balance, nutrient recovery, and resource cost of biogas production from household food waste-A comparison of multiple cases from Sweden. J Clean Prod, 2022; 378: 134536.
De Oliveira L G S, Negro S O. Contextual structures and interaction dynamics in the Brazilian Biogas Innovation System. Renew Sust Energ Rev, 2019; 107: 462–481.
Bertolino A M, Giganti P, Dos Santos D D, Falcone P M. A matter of energy injustice? A comparative analysis of biogas development in Brazil and Italy. Energy Res Soc Sci, 2023; 105: 103278.
Singh P, Kalamdhad A S. Assessment of small-scale biogas digesters and its impact on the household cooking sector in India: Environmental-resource-economic analysis. Energy for Sustainable Development, 2022; 70: 170–180.
Nevzorova T. Functional analysis of technological innovation system with inclusion of sectoral and spatial perspectives: The case of the biogas industry in Russia. Environmental Innovation and Societal Transitions, 2022; 42: 232–250.
Venus T E, Strauss F, Venus T J, Sauer J. Understanding stakeholder preferences for future biogas development in Germany. Land Use Policy, 2021; 109: 105704.
Sica D, Esposito B, Supino S, Malandrino O, Sessa M R. Biogas-based systems: An opportunity towards a post-fossil and circular economy perspective in Italy. Energ Policy, 2023; 182: 113719.
Korberg A D, Skov I R, Mathiesen B V. The role of biogas and biogas-derived fuels in a 100% renewable energy system in Denmark. Energy, 2020; 199: 117426.
Hao J J, Jia S F, Sun H, Chen G P, Zhang J X, Zhao Y B, et al. Effects of cow manure ratios on methane production and microbial community evolution in anaerobic co-digestion with different crop wastes. Int J Agric & Biol Eng, 2022; 15(5): 219–228.
López R A, Tena M, Solera R, Pérez M. Anaerobic co-digestion of sewage sludge and wine vinasse mixtures in single-stage and sequential-temperature processes. Fuel, 2023; 348: 128531.
Xu Y H, Song Y N, Jiang H, Zhang H Q, Sun Y. Effect of vacuum negative pressure aerobic hydrolysis pretreatment on corn stover anaerobic fermentation. Int J Agric & Biol Eng, 2023; 16(2): 241–248.
Ibro M K, Ancha V R, Lemma D B. Impacts of anaerobic co-digestion on different influencing parameters: A critical review. Sustainability, 2022; 14(15): 9387.
Xie J X, Cheng Z, Zhu S Y, Xu J. Lewis base enhanced neutral deep eutectic solvent pretreatment for enzymatic hydrolysis of corn straw and lignin characterization. Renewable Energy, 2022; 188: 320–328.
Mirmohamadsadeghi S, Karimi K, Azarbaijani R, Yeganeh L P, Angelidaki I, Nizami A-S, et al. Pretreatment of lignocelluloses for enhanced biogas production: A review on influencing mechanisms and the importance of microbial diversity. Renewable and Sustainable Energy Reviews, 2021; 135: 110173.
Donkor K O, Gottumukkala L D, Lin R, Murphy J D. A perspective on the combination of alkali pre-treatment with bioaugmentation to improve biogas production from lignocellulose biomass. Bioresource Technology, 2022; 351: 126950.
Jin X D, Ai W D, Dong W Y. Lignocellulose degradation, biogas production and characteristics of the microbial community in solid-state anaerobic digestion of wheat straw waste. Life Sciences in Space Research, 2022; 32: 1–7.
Dahunsi S O. Mechanical pretreatment of lignocelluloses for enhanced biogas production: Methane yield prediction from biomass structural components. Bioresource Technol, 2019; 280: 18–26.
Bittencourt G A, Barretob E d S, Brandao R L, Baêta B E L, Gurgel L V A. Fractionation of sugarcane bagasse using hydrothermal and advanced oxidative pretreatments for bioethanol and biogas production in lignocellulose biorefineries. Bioresource Technol, 2019; 292: 121963.
Xu N, Liu S X, Xin F X, Zhou J, Jia H H, Xu J M, et al. Biomethane production from lignocellulose: Biomass recalcitrance and its impacts on anaerobic digestion. Front Bioeng Biotechnol, 2019; 7: 00191.
Bobade V, Das T, Usher S P, McMurrich D, Stickland A D, Eshtiaghi N. Formation mechanisms and mechanical properties of anaerobic lagoon scum. Science of The Total Environment, 2022; 843: 156907.
Hao J. Study on inhibition mechanism of corn stalks pretreatment on anaerobic digestion scum layer formation. PhD dissertation. Haerbin: Northeast Agricultural University, 2022; 119p. (in Chinese)
Pan S Y, Wen C, Liu Q Q, Chi Y, Mi H Z, Li Z C, et al. A novel hydraulic biogas digester controlling the scum formation in batch and semi-continuous tests using banana stems. Bioresource Technol, 2019; 286.
Mu D Y, Addy M, Anderson E, Chen P, Ruan R. A life cycle assessment and economic analysis of the Scum-to-Biodiesel technology in wastewater treatment plants. Bioresource Technol, 2016; 204: 89–97.
Bi C H, Min M, Nie Y, Xie Q L, Lu Q, Deng X Y, et al. Process development for scum to biodiesel conversion. Bioresource Technol, 2015; 185: 185–193.
Anderson E, Addy M, Xie Q L, Ma H, Liu Y H, Cheng Y L, et al. Glycerin esterification of scum derived free fatty acids for biodiesel production. Bioresource Technol, 2016; 200: 153–160.
Guo Z D, Usman M, Alsareii S A, Harraz F A, Al-Assiri M S, Jalalah M, et al. Synergistic ammonia and fatty acids inhibition of microbial communities during slaughterhouse waste digestion for biogas production. Bioresource Technol, 2021; 337: 125383.
Xu J, Zhu W Z, Xie L. Effect of bioaugmentation on the performance of anaerobic digestion: A review. Chemical Industry and Engineering Progress, 2019; 38(9): 4227–4237. (in Chinese)
Fu J Q, Wang H Y, Wang T, Gui S L. Ammonia inhibition and mitigation strategies in anaerobic digestion of pig manure. Energy research and management, 2022; 14(4): 85–90,145.
Yellezuome D, Zhu X P, Wang Z Z, Liu R H. Mitigation of ammonia inhibition in anaerobic digestion of nitrogen-rich substrates for biogas production by ammonia stripping: A review. Renewable and Sustainable Energy Reviews, 2022; 157: 112043.
Lv Z P, Hu M, Harms H, Richnow H H, Liebetrau J, Nikolausz M. Stable isotope composition of biogas allows early warning of complete process failure as a result of ammonia inhibition in anaerobic digesters. Bioresource Technol, 2014; 167: 251–259.
Tong H, Zhou B Y, Liu C M, Wachemo A C, Li X J, Zuo X Y. Improving biomethane yield by strengthening acidification of maize stover in two-phase anaerobic digestion. Int J Agric & Biol Eng, 2020; 13(4): 226–231.
Ren Q S, Zhang H B, Cheng H Y, Wang Y M, Luo Y, Liu Na. Effect of pH value on acid production characteristics and microbial community in co‐fermentation of pig manure and spent mushroom substrate. Journal of Henan Agricultural Sciences, 2023; 52(5): 110–120. (in Chinese)
Ren H W, Mei Z L, Fan W G, Wang Y J, Liu F F, Luo T, et al. Effects of temperature on the performance of anaerobic co-digestion of vegetable waste and swine manure. Int J Agric & Biol Eng, 2018; 11(1): 218–225.
Zhao P X, Cui F J, Bu L X, Jiang J X. Biogas production from microbial-alkali pretreated corn stover by solid-state anaerobic digestion. Int J Agric & Biol Eng, 2015; 8(5): 96–104.
Zheng G X, Lu Z X, Li J, Ai S, Sun Y. Screening and performance of L-14, a novel, highly efficient and low temperature-resistant cellulose-degrading strain. Int J Agric & Biol Eng, 2020; 13(1): 247–254.
Romio C, Kofoed M V W, Moller H B. Digestate post-treatment strategies for additional biogas recovery: A review. Sustainability, 2021; 13(16): 9295.
Zheng Y, Zhao J, Xu F Q, Li Y B. Pretreatment of lignocellulosic biomass for enhanced biogas production. Progress in Energy and Combustion Science, 2014; 42: 35–53.
Karimipour-Fard P, Chio C, Brunone A, Marway H, Thompson M, Abdehagh N, et al. Lignocellulosic biomass pretreatment: Industrial oriented high-solid twin-screw extrusion method to improve biogas production from forestry biomass resources. Bioresource Technol, 2024; 393: 130000.
Luo T, Huang H L, Mei Z L, Shen F, Ge Y H, Hu G Q, et al. Hydrothermal pretreatment of rice straw at relatively lower temperature to improve biogas production via anaerobic digestion. Chinese Chemical Letters, 2019; 30(6): 1219–1223.
Qian Y T, Du J, Chen G Y, Huang H Y, Jin H M, Xi Y L, et al. Optimization of conditions for promoting biogas production with hydrothermal pretreatment for straw. China Environmental Science, 2016; 36(12): 3703–3710. (in Chinese)
Meng F Z, Ju T Y, Han S Y, Lin L, Li J L, Chen K L, et al. Novel monoethanolamine absorption using ionic liquids as phase splitter for CO2 capture in biogas upgrading: High CH4 purity and low energy consumption. Chemical Engineering Journal, 2023; 462: 142296.
Khan J, Saif-ul-Allah M W, Qyyum M A, Ahmed F, Yasin M, Hussain A, et al. Reduction in specific energy consumption of overall biogas upgrading and biomethane liquefaction process: Energy and exergy analysis. Energ Convers Manage, 2022; 271: 116269.
Mahmoodi-Eshkaftaki M, Houshyar E. Biogas recirculation technology: Effect on biogas purification, slurry characteristics, microbial activity and energy consumption. Environmental Technology & Innovation, 2020; 19: 100867.
Liu Q Y, Zhao Z X, Xue Z P, Li D, Wen Z N, Ran Y, et al. Comprehensive risk assessment of applying biogas slurry in peanut cultivation. Front Nutr, 2021; 8: 702096.
Ma J Q, Zhu H G, Fan M. Distribution of heavy metals in pig farm biogas residues and the safety and feasibility assessment of biogas fertilizer. Int J Agric & Biol Eng, 2013; 6(4): 35–43.
Chang Y J, Zhao H J, Sun L H, Cui J, Liu J J, Tang Q, et al. Resource utilization of biogas waste as fertilizer in China needs more inspections due to the risk of heavy metals. Agriculture, 2022; 12(1): 0072.
Fu J J, Chen Y S, Xu B X, Ma B, Wang P J, Wu A B, et al. Investigation of distribution uniformity of distributor for biogas slurry application based on CFD analysis. Int J Agric & Biol Eng, 2023; 16(1): 45–52.
Fan M, Zhu H G, Ma J Q. Measurement and analysis of biogas fertilizer use efficiency, nutrient distribution and influencing factors of biogas residues and slurry on pig farms. Int J Agric & Biol Eng, 2014; 7(1): 60–69.
Zheng J, Qi X Y, Yang S H, Shi C, Feng Z J. Effects and evaluation of biogas slurry/water integrated irrigation technology on the growth, yield and quality of tomatoes. Int J Agric & Biol Eng, 2022; 15(5): 123–131.
Li G, Zhang J, Li H, Hu R C, Yao X L, Liu Y, et al. Towards high-quality biodiesel production from microalgae using original and anaerobically-digested livestock wastewater. Chemosphere, 2021; 273: 128578.
Li G, Hu R C, Wang N, Yang T L, Xu F Z, Li J L, et al. Cultivation of microalgae in adjusted wastewater to enhance biofuel production and reduce environmental impact: Pyrolysis performances and life cycle assessment. Journal of Cleaner Production, 2022; 355: 131768.
Yang Y, Zhu H G. Fluid-solid drag models selection for simulating wheat straw particle movement in anaerobic digester. Int J Agric & Biol Eng, 2023; 16(2): 249–258.
Liu X Y, Zhu H G. Treatment of low C/N ratio wastewater by a carbon cloth bipolar plate multicompartment electroenhanced bioreactor (CBM-EEB). ACS Omega, 2020; 5(43): 27823–27832.
Wu Q, Xiao H, Zhu H G, Pan F H, Lu F L. Carbon felt composite electrode plates promote methanogenesis through microbial electrolytic cells. Energies, 2023; 16(11): 4416.
Sun J H, Pan F H, Zhu H G, Wu Q, Pan C H, Lu F L. Enhancing low-temperature anaerobic digestion of low-strength organic wastewater through bio-electrochemical technology. International Journal of Hydrogen Energy, 2024; 58: 1062–1074.
Lu F L, Pan C H, Zhu H G, Pan F H, Wu Q. Energy management strategy for a biogas plant in Anhui, China based on waste heat recovery and thermoeconomic analysis. Energy Conversion and Management, 2022; 273: 116399.
Pan C H, Lu F L, Zhu H G, Pan F H, Sun J H. Thermo-economic analysis of combined transcritical CO2 power cycle based on a novel liquefied-biomethane energy storage system. Applied Thermal Engineering, 2023; 222: 119922.
Xiao H, Pan F H, Huang F, Zhu H G, Wu Q. Three-segmented counterflow pilot-scale electrodialysis for ammonia and potassium treatment in liquid anaerobic digestate: A trade-off among advanced ion removal, nutrients concentration limitation, and energy consumption. Chemical Engineering Journal, 2023; 472: 144941.
Pan F H, Xiao H, Huang F, Lei J J, Zhu H G, Ma J. Macroscale preparation of nanosized calcium carbonate by exploiting biogas slurry synchronous metathesis encapsulation method. New Journal of Chemistry, 2023; 47(26): 12445–12457.
Pan F H, Xiao H, Huang F, Zhu H G, Lei J J, Ma J. Preliminary study on the preparation of conductive nanosized calcium carbonate utilizing biogas slurry by a synchronous double decomposition coating method. Nanomaterials, 2023; 13(13): 1938.
Yu H, Zhang X Y, Chen M Y, Chen F. Application of energy storage allocation model in the context of mitigating new energy source power fluctuation. Energy Reports, 2023; 10: 4791–4799.
Yu H M, Shao Z G, Hou M, Yi B L, Duan F W, Yang Y X. Hydrogen Production by Water Electrolysis: Progress and Suggestions. China Academic Journal Electronic Publishing House, 2021; 23(2): 146–152. (in Chinese)
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