Prediction and optimisation of gasoline quality in petroleum refining: The use of machine learning model as a surrogate in optimisation framework

IF 8.4 2区计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

CAAI Transactions on Intelligence Technology Pub Date : 2024-05-13 DOI:10.1049/cit2.12324

Husnain Saghir, Iftikhar Ahmad, Manabu Kano, Hakan Caliskan, Hiki Hong

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引用次数: 0

Abstract

Hardware‐based sensing frameworks such as cooperative fuel research engines are conventionally used to monitor research octane number (RON) in the petroleum refining industry. Machine learning techniques are employed to predict the RON of integrated naphtha reforming and isomerisation processes. A dynamic Aspen HYSYS model was used to generate data by introducing artificial uncertainties in the range of ±5% in process conditions, such as temperature, flow rates, etc. The generated data was used to train support vector machines (SVM), Gaussian process regression (GPR), artificial neural networks (ANN), regression trees (RT), and ensemble trees (ET). Hyperparameter tuning was performed to enhance the prediction capabilities of GPR, ANN, SVM, ET and RT models. Performance analysis of the models indicates that GPR, ANN, and SVM with R2 values of 0.99, 0.978, and 0.979 and RMSE values of 0.108, 0.262, and 0.258, respectively performed better than the remaining models and had the prediction capability to capture the RON dependence on predictor variables. ET and RT had an R2 value of 0.94 and 0.89, respectively. The GPR model was used as a surrogate model for fitness function evaluations in two optimisation frameworks based on genetic algorithm and particle swarm method. Optimal parameter values found by the optimisation methodology increased the RON value by 3.52%. The proposed methodology of surrogate‐based optimisation will provide a platform for plant‐level implementation to realise the concept of industry 4.0 in the refinery.

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预测和优化石油炼制过程中的汽油质量：在优化框架中使用机器学习模型作为替代品

基于硬件的传感框架（如合作燃料研究引擎）通常用于监测石油精炼行业的研究辛烷值（RON）。机器学习技术被用于预测集成石脑油重整和异构化过程的 RON。使用动态 Aspen HYSYS 模型生成数据，在温度、流速等工艺条件中引入 ±5% 范围内的人为不确定性。生成的数据用于训练支持向量机 (SVM)、高斯过程回归 (GPR)、人工神经网络 (ANN)、回归树 (RT) 和集合树 (ET)。对超参数进行了调整，以增强 GPR、ANN、SVM、ET 和 RT 模型的预测能力。对模型的性能分析表明，GPR、ANN 和 SVM 的 R2 值分别为 0.99、0.978 和 0.979，RMSE 值分别为 0.108、0.262 和 0.258，其性能优于其余模型，并具有捕捉 RON 与预测变量相关性的预测能力。ET 和 RT 的 R2 值分别为 0.94 和 0.89。在基于遗传算法和粒子群法的两个优化框架中，GPR 模型被用作适合度函数评估的替代模型。通过优化方法找到的最佳参数值将 RON 值提高了 3.52%。所提出的基于代用模型的优化方法将为在炼油厂实现工业 4.0 概念提供一个工厂级实施平台。

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来源期刊

CAAI Transactions on Intelligence Technology COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-

CiteScore

11.00

自引率

3.90%

发文量

134

审稿时长

35 weeks

期刊介绍： CAAI Transactions on Intelligence Technology is a leading venue for original research on the theoretical and experimental aspects of artificial intelligence technology. We are a fully open access journal co-published by the Institution of Engineering and Technology (IET) and the Chinese Association for Artificial Intelligence (CAAI) providing research which is openly accessible to read and share worldwide.