Artificial intelligence and machine learning models application in biodiesel optimization process and fuel properties prediction

被引：6

作者：

Arif, Muhammad ^{[1
,6
]}

Alalawy, Adel I. ^{[2
]}

Zheng, Yuanzhang ^{[3
]}

Koutb, Mostafa ^{[4
]}

Kareri, Tareq ^{[5
]}

Salama, El-Sayed ^{[6
]}

Li, Xiangkai ^{[1
]}

机构：

[1] MOE, Key Laboratory of Cell Activities and Stress Adaptations, School of Life Sciences, Lanzhou University, Gansu Province, Lanzhou

[2] Department of Biochemistry, Faculty of Science, University of Tabuk, Tabuk

[3] Discovery Biology, CuriaGlobal Inc., NY

[4] Department of Biology, Faculty of Science, Umm Al-Qura University, Makkah

[5] Department of Electrical Engineering, College of Engineering, Najran University, Najran

[6] Department of Occupational and Environmental Health, School of Public Health, Lanzhou University, Gansu Province, Lanzhou

来源：

Sustainable Energy Technologies and Assessments | 2025年 / 73卷

关键词：

Artificial intelligence; Biodiesel; Machine learning models; Optimization; Predictions;

D O I：

10.1016/j.seta.2024.104097

中图分类号：

学科分类号：

摘要：

Inefficient transesterification, low-quality fuel properties, and high resource consumption are the bottlenecks associated with conventional biodiesel production. The current research trends include the application of artificial intelligence (AI) and machine learning (ML) to optimize the biodiesel process for improved yield and fuel quality. Previous reviews discussed the applications of ML in the optimization of transesterification parameters and fuel properties. However, there is a lack of deep discussion on feedstock selection, optimization, process monitoring, and cost analysis. The challenges during biodiesel production, ML model selection, and assessment of plant and animal lipid potential for biodiesel under different conditions using AI tools are reviewed. All the parameters that affect biodiesel yield and fuel properties through ML, the efficiency of different models, and pilot-scale techno-economic analyses are also discussed. Biodiesel production from animal and plant lipids showed high yield potential ranging from 78-99 %. ML models demonstrated higher efficacy in transesterification optimization to attain > 90 % yield. Various AI models exhibit a predictive efficiency range (R2 = 0.85 to 0.99) for yield and fuel qualities. Economic analyses reveal that the choice of feedstock and catalyst significantly impacts final production costs. ML and AI approaches exhibit the potential for improving the biodiesel process. © 2024 Elsevier Ltd

引用

共 167 条

[31]

Guo L., Xie W., Gao C., Heterogeneous H6PV3MoW8O40/AC-Ag catalyst for biodiesel production: Preparation, characterization and catalytic performance, Fuel, (2022)

[32]

Maniam G.P., Lim H.S., Hussin N.M., Effect of free fatty acid on transesterification of waste cooking oil, Current Science and Technology, pp. 57-63, (2023)

[33]

Zhang P., Chang Z., Wang D., Blamo B.J., Li W., Effect of water content on product distribution of base-catalyzed transesterification, Waste Biomass Valoriz, pp. 95-102, (2016)

[34]

Nahas L., Dahdah E., Aouad S., El Khoury B., Gennequin C., Abi Aad E., Et al., Highly efficient scallop seashell-derived catalyst for biodiesel production from sunflower and waste cooking oils: Reaction kinetics and effect of calcination temperature studies, Renew Energy, pp. 1086-1095, (2023)

[35]

Oyekunle D.T., Barasa M., Gendy E.A., Tiong S.K., Heterogeneous catalytic transesterification for biodiesel production: Feedstock properties, catalysts and process parameters, Process Saf Environ Prot, (2023)

[36]

Slamet S., Dewi A.S.C., Synthesis of biodiesel from waste cooking oil using heterogeneous CaO catalyst: Effect of stirring speed, AIP Conference Proceedings, (2018)

[37]

Andreo-Martinez P., Ortiz-Martinez V.M., Salar-Garcia M.J., Veiga-del-Bano J.M., Chica A., Quesada-Medina J., Waste animal fats as feedstock for biodiesel production using non-catalytic supercritical alcohol transesterification: A perspective by the PRISMA methodology, Energy Sustain Dev, pp. 150-163, (2022)

[38]

Kurczynski D., Wcislo G., Le{acute{s}}niak A., Kozak M., Lagowski P., Production and testing of butyl and methyl esters as new generation biodiesels from fatty wastes of the leather industry, Energies, (2022)

[39]

Monika S., Banga V.V.P., Biodiesel production from waste cooking oil: A comprehensive review on the application of heterogenous catalysts, Energy Nexus, (2023)

[40]

Catarino M., Ferreira E., Dias A.P.S., Gomes J., Dry washing biodiesel purification using fumed silica sorbent, Chem Eng J, (2020)

← 1 2 3 4 5 6 7 8 9 10 →