The whole process of biofuel production from Desmodesmus sp. EJ 8-10 cultivated in anaerobic digested wastewater (ADW) under the optimal temperature was evaluated by using the method of Life Cycle Assessment (LCA). The energy efficiency and environment emissions were under considerable for the corresponding parametric study. The functional unit was 1 kg microalgae. It was concluded that the harvest stage was responsible for the main energy consumption during the microalgal whole pyrolysis process. The energy conversion efficiency of the whole process was larger than 1, which indicated that the process was profitable. The environmental impact of the whole process was 1165.67 mPET2000, among which the primary impact on the environment was eutrophication that accounts for 57.36%, followed by photochemical ozone synthesis (22.56%), acidification (17.36%); and global warming (2.73%), respectively.
Keywords: microalgae, fast pyrolysis, life cycle assessment (LCA), anaerobic digested wastewater (ADW), biofuel production
DOI: 10.25165/j.ijabe.20201301.4178

Citation: Li G, Lu Z T, Zhang J, Li H, Zhou Y G, Zayan A M I, et al. Life cycle assessment of biofuel production from microalgae cultivated in anaerobic digested wastewater. Int J Agric & Biol Eng, 2020; 13(1): 241–246.

microalgae, fast pyrolysis, life cycle assessment (LCA), anaerobic digested wastewater (ADW), biofuel production

Li G, Xiang S N, Ji F, Zhou Y G, Huang Z G. Thermal cracking products and bio-oil production from microalgae Desmodesmus sp. Inter Agric & Biol Eng, 2017; 10(4): 198–206.

Marjakangas J M, Chen C Y, Lakaniemi A M, Puhakka J A, Whang L M, Chang J S. Simultaneous nutrient removal and lipid production with Chlorella vulgaris on sterilized and non-sterilized anaerobically pretreated piggery wastewater. Biochemical Engineering Journal, 2015; 103: 177–184.

Li G, Bai X, Li H, Lu Z T, Zhou Y G, Wang Y K, et al. Nutrients removal and biomass production from anaerobic digested effluent by microalgae: A review. Inter Agric & Biol Eng, 2019; 12(5): 8–13.

Chang H X, Fu Q, Huang Y, Xia A, Liao Q, Zhu X. Improvement of microalgae lipid productivity and quality in an ion-exchange-membrane photobioreactor using real municipal wastewater. Inter Agric & Biol Eng, 2017; 10(1): 97–106.

Ji F, Liu Y, Hao R, Li G, Zhou Y G, Dong R J. Biomass production and nutrients removal by a new microalgae strain Desmodesmus sp. in anaerobic digestion wastewater. Bioresource Technology, 2014; 161: 200–207.

Eltanahy E, Salim S, Vadiveloo A, Verduin J, Pais B, Moheimani N. Comparison between jet and paddlewheel mixing for the cultivation of microalgae in anaerobic digestate of piggery effluent (ADPE). Algal Research, 2018; 35: 274–282.

Chang X M, Yao X L, Ding N, Ying X F, Zheng Q M, Lu S L, et al. Photocatalytic degradation of trihalomethanes and haloacetonitriles on graphitic carbon nitril under visible light irradiation. Sci Total Environ, 2019; 682: 200–207.

Lu Q, Yang X C, Dong C Q, Zhang Z F, Zhang X M, Zhu X F. Influence of pyrolysis temperature and time on the cellulose fast pyrolysis products: Analytical Py-GC/MS study. Journal of Analytical and Applied Pyrolysis, 2011; 92 (2): 430–438.

Liu Y, Yao X L, Wang Z B, Li H L, Shen X B, Yao Z L, et al. Synthesis of activated carbon from critic acid residue by phosphoric acid activation for the removal of chemical oxygen demand from sugar-containing wastewater. Environ Eng Sci, 2019; 36: 6. DOI: 10.1089/ees.2018.0506.

Li G, Ji F, Bai X, Zhou Y G, Dong R J, Huang Z G. Comparative study on thermal cracking characteristics and bio-oil production from different microalgae using by Py-GC/MS. Inter Agric & Biol Eng, 2019; 12(1): 208–213.

Arun J, Varshini P, Prithvinath P K, Priyadarshini V, Gopinath K P. Enrichment of bio-oil after hydrothermal liquefaction (HTL) of microalgae C. vulgaris grown in wastewater: Bio-char and post HTL wastewater utilization studies. Bioresource Technology, 2018; 261: 182–187.

Wang Z H, Adhikari S, Valdez P, Shakya R, Laird C. Upgrading of hydrothermal liquefaction biocrude from algae grown in municipal wastewater. Fuel processing Technology, 2016: 142: 147–156.

Lee J K, Sohn D H, Lee K Y, Park K Y. Solid fuel production through hydrothermal carbonization of sewage sludge and microalgae Chlorella sp. from wastewater treatment plant. Chemosphere, 2019; 230: 157–163.

Li G, Dong R J, Fu N, Zhou Y G, Li D, Chen X D. Characterization of pyrolysis products obtained from Desmodesmus sp. cultivated in anaerobic digested effluents (DADE). International Journal of Food Engineering, 2015; 11(6): 825–831.

Xin C H, Addy M M, Zhao J Y, Chen Y L, Ma Y W, Liu S Y et al. Waste-to-biofuel integrated system and its comprehensive techno-economic assessment in wastewater treatment plants. Bioresource Technology, 2018; 250: 523–531.

Quinteiro P, Tarelho L, Marques P, Martin-Gamboa M, Freire F, Arroja L, et al. Life cycle assessment of wood pellets and wood split logs for residential heating. Science of the Total Environment, 2019; 689: 580–589.

Arashio L T, Montero N, Ferrer I, Acién F G, Gómez C, Garfí M. Life cycle assessment of high rate algal ponds for wastewater treatment and resource recovery. Science of the Total Environment, 2018; 622-623: 1118–1130.

Lee K, Inaba A. Life cycle assessment best practices of ISO 14040 series. Center for Ecodesign and LCA (CEL), Ajou University, 2004.

ISO14043: Environmental management-life cycle assessment-life cycle interpretation, 2000 (E).

Morales M, Quintero J, Conejeros R, Aroca G. Life cycle assessment lignocellulosic bioethanol: Environmental impacts and energy balance. Renewable Sustainable Energy Review, 2015; 42: 1349–1361.

Ubando A T, Rivera D R T, Chen W H, Culaba A B. A comprehensive review of life cycle assessment (LCA) of microalgal and lignocellulosic bioenergy products from thermochemical processes. Bioresource Technology, 2019; 291: 12183.

Marsmann M. The ISO 14040 family. International Journal of Life Cycle Assessment, 2000; 5(6): 317–318.

Li G, Ji F, Zhou Y G, Dong R J. Life cycle assessment of pyrolysis process of Desmodesmus sp. Inter Agric & Biol Eng, 2015; 8(5): 105–112.

Mahinpey N, Murugan P, Mani T, Raina R. Analysis of bio-oil, biogas, and biochar from pressurized pyrolysis of wheat straw using a tubular reactor. Energy Fuels, 2009; 23(5): 2736–2742.

Liu Y X, Langer V, Hogh-Jensen H, Egelyng H. Life cycle assessment of fossil energy use and greenhouse gas emissions in Chinese pear production. Journal of Clean Production, 2010; 18(14): 1423–1430.

Liu J, Ma X Q. The analysis on energy and environmental impacts of microalgae-based fuel methanol in China. Energy Policy, 2009; 37(4): 1479–1488.

Wang H R, Xu J L, Yang X F, Miao Z, Yu C. Organic rankine cycle saves energy and reduces gas emissions for cement production. Energy, 2015; 86: 59–73.

Houghton J T. (Ed.). Climate change 1995: The science of climate change: contributing of working group 1 to the second assessment report of the intergovernmental panel on climate change. Cambridge University Press, 1996.

Brentrup F, Küsters J, Kuhlmann H, Lammel J. Environmental impact assessment of agricultural production systems using the life cycle assessment methodology: I. Theoretical concept of a LCA method tailored to crop production. European Journal of Agronomy, 2004; 20(3): 247–264.

Wang M X, Bao Y H, Wu W L, Liu W N. Life cycle environmental impact assessment of winter in north China plain. Journal of Agro-Environment Science, 2006; 25(5): 1127–1132.

Sleeswijk A W, van Oers L F C M, Guinée J B, Struijs J, Huijbregts M A J. Normalisation in product life cycle assessment: An LCA of the global and European economic systems in the year 2000. Science of the Total Environment, 2008; 390(1): 227–240.

Huang C L. Life cycle assessment (LCA) for the product of synthesized polymer biomedical material. Master Dissertation. Sichuan: Southwest Jiaotong University, 2004. (in Chinese)

Finnveden G, Hauschild M Z, Ekvall T, GuinéeJ, Heijungs R, Hellweg S, et al. Recent developments in life cycle assessment. Journal of Environmental Management, 2009; 91(1): 1–21.