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基于人工智能的柚木与滇橄榄生物柴油的预测及多目标响应面法优化

Artificial intelligence based prediction and multi-objective RSM optimization of tectona grandis biodiesel with Elaeocarpus Ganitrus.

作者信息

Kannan V Vinoth, Kanabar Bhavesh, Gowrishankar J, Khatibi Ali, Kamangar Sarfaraz, Arabi Amir Ibrahim Ali, Thomai Pushparaj, Lozanović Jasmina

机构信息

Indra Ganesan College of Engineering, Manikandam, Tiruchirappalli, Tamil Nadu, India.

Department of Mechanical Engineering, Faculty of Engineering & Technology, Marwadi University Research Center, Marwadi University, Rajkot, 360003, Gujarat, India.

出版信息

Sci Rep. 2025 Jan 30;15(1):3833. doi: 10.1038/s41598-025-87640-1.

DOI:10.1038/s41598-025-87640-1
PMID:39885203
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11782613/
Abstract

Meta-heuristic optimization algorithms are widely applied across various fields due to their intelligent behavior and fast convergence, but their use in optimizing engine behavior remains limited. This study addresses this gap by integrating the Design of Experiments-based Response Surface Methodology (RSM) with meta-heuristic optimization techniques to enhance engine performance and emissions characteristics using Tectona Grandi's biodiesel with Elaeocarpus Ganitrus as an additive. Advanced Machine Learning (ML) models, including Artificial Neural Networks (ANN), K-Nearest Neighbors (KNN), Extreme Gradient Boosting (XGB), and Random Trees (RT), were employed for predictive analysis, with ANN outperforming RSM in accuracy. The study identified the Teak biodiesel blend (TB20) with a 5 ml Elaeocarpus Ganitrus additive (TB20 + R5) as the optimal formulation, achieving the highest Brake Thermal Efficiency and reduced Brake-Specific Fuel Consumption. Desirability analysis further confirmed the blend's superior performance and emissions characteristics, with a desirability rating of 0.9282. This work highlights the potential of hybrid optimization approaches for improving biodiesel performance and emissions without engine modifications, contributing to the advancement of sustainable energy practices in internal combustion engines.

摘要

元启发式优化算法因其智能行为和快速收敛性而在各个领域得到广泛应用,但其在优化发动机性能方面的应用仍然有限。本研究通过将基于实验设计的响应面方法(RSM)与元启发式优化技术相结合,以使用柚木生物柴油并添加杜英作为添加剂来提高发动机性能和排放特性,从而弥补这一差距。先进的机器学习(ML)模型,包括人工神经网络(ANN)、K近邻(KNN)、极端梯度提升(XGB)和随机树(RT),被用于预测分析,其中ANN在准确性方面优于RSM。该研究确定了添加5毫升杜英添加剂的柚木生物柴油混合物(TB20 + R5)为最佳配方,实现了最高的制动热效率并降低了制动特定燃油消耗。合意性分析进一步证实了该混合物的卓越性能和排放特性,合意性评级为0.9282。这项工作突出了混合优化方法在不进行发动机改造的情况下改善生物柴油性能和排放的潜力,为内燃机可持续能源实践的发展做出了贡献。

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