Artificial neural network based prediction of engine-out responses from a biodiesel fuelled compression ignition engine

IF 1.1 4区工程技术 Q4 THERMODYNAMICS

Thermal Science Pub Date : 2023-01-01 DOI:10.2298/tsci2304433k

Cheikh Kezrane, Houcine Habib, Mustafa Bayram, Sultan Alqahtani, Sultan Alshehery, Omolayo Ikumapayi, Esther Akinlabi, Stephen Akinlabi, Khaled Loubar, Younes Menni

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引用次数: 0

Abstract

Numerical simulations, based on relatively complex physical models developed for CFD, can accurately predict engine-out responses, but they require huge memory space and/or computation time. In terms of resources and computer time, artificial intelligence methodologies are more cost-effective. In this work, we used an ANN to predict the performance and exhaust emissions of a single-cylinder Diesel engine running on fossil diesel, biodiesel, and their blends under various speed and load regimes. To perform the modeling, we employed multilayer perceptrons and a back-propagation gradient algorithm with momentum to train the network weights. The modification of the network weights was done using the second-order method of Levenberg-Marquardt, and the technique of early termination was utilized to avoid overtraining the model. The study involved using 70% of the complete experimental data to train the neural network, allocating 15% for network validation, and reserving the remaining 15% to evaluate the trained network effectiveness. The ANN model that was created demonstrated remarkable accuracy in predicting both engine performance and emissions. This is evident from the strong correlation coefficients observed, which ranged from 0.987 to 0.999, as well as the low mean squared errors ranging from 7.44?10-4 to 2.49?10-3.

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基于人工神经网络的生物柴油压缩点火发动机熄火响应预测

基于CFD开发的相对复杂的物理模型的数值模拟可以准确地预测发动机出机响应，但它们需要巨大的存储空间和/或计算时间。在资源和计算机时间方面，人工智能方法更具成本效益。在这项工作中，我们使用人工神经网络来预测使用化石柴油、生物柴油及其混合物的单缸柴油发动机在不同速度和负载下的性能和废气排放。为了进行建模，我们使用多层感知器和带动量的反向传播梯度算法来训练网络权重。采用二阶Levenberg-Marquardt方法对网络权值进行修正，并采用提前终止技术避免模型过度训练。该研究涉及使用完整实验数据的70%来训练神经网络，分配15%用于网络验证，保留剩余的15%用于评估训练后的网络有效性。所建立的人工神经网络模型在预测发动机性能和排放方面都表现出了惊人的准确性。从观察到的强相关系数(0.987至0.999)以及均方误差(7.44?10-4到2.49?10-3。

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来源期刊

Thermal Science 工程技术-热力学

CiteScore

2.70

自引率

29.40%

发文量

399

审稿时长

5 months

期刊介绍： The main aims of Thermal Science to publish papers giving results of the fundamental and applied research in different, but closely connected fields: fluid mechanics (mainly turbulent flows), heat transfer, mass transfer, combustion and chemical processes in single, and specifically in multi-phase and multi-component flows in high-temperature chemically reacting flows processes present in thermal engineering, energy generating or consuming equipment, process and chemical engineering equipment and devices, ecological engineering, The important characteristic of the journal is the orientation to the fundamental results of the investigations of different physical and chemical processes, always jointly present in real conditions, and their mutual influence. To publish papers written by experts from different fields: mechanical engineering, chemical engineering, fluid dynamics, thermodynamics and related fields. To inform international scientific community about the recent, and most prominent fundamental results achieved in the South-East European region, and particularly in Serbia, and - vice versa - to inform the scientific community from South-East European Region about recent fundamental and applied scientific achievements in developed countries, serving as a basis for technology development. To achieve international standards of the published papers, by the engagement of experts from different countries in the International Advisory board.