Performance evaluation of various training functions using ANN to predict the thermal conductivity of EG/water-based GNP/CNC hybrid nanofluid for heat transfer application

IF 3 3区工程技术 Q2 CHEMISTRY, ANALYTICAL

Journal of Thermal Analysis and Calorimetry Pub Date : 2025-01-10 DOI:10.1007/s10973-024-13873-3

Md. Munirul Hasan, Md Mustafizur Rahman, Suraya Abu Bakar, Muhammad Nomani Kabir, Devarajan Ramasamy, A. H. M. Saifullah Sadi

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引用次数: 0

Abstract

Thermal management efficiency is still a significant problem in many industries and techniques due to the ultimate limitations in the performance of conventional heat transfer fluids. The present research focuses on predicting the thermophysical properties of hybrid graphene nanoplatelet (GNP) and cellulose nanocrystal (CNC) nanoparticles to improve the thermal performance of heat transfer systems. Resolving the thermal management issues can be critical for saving energy, enhancing the effectiveness of the systems, and advancing the existing and emerging technologies needed to handle high temperatures. GNP-CNC/ethylene glycol–water hybrid nanofluids were prepared in volume concentrations from 0.01 to 0.2%. Thermal conductivity was measured from 30 to 80 °C, providing comprehensive data for analysis. The most important resolution was formulated at 0.1% volume concentration within a 60:40 volume ratio of ethylene glycol and water, with UV–Vis analysis showing absorption peaks in the highest order at 0.10% and 0.2% concentrations. Thermogravimetric analysis has shown an increase towards thermal resilience, with the mass decline beginning at 130 °C and full degradation at 500 °C. An interesting observation was invested for 0.20% GNP: CNC, where the onset of degradation occurred at 150 °C, providing an increased variety of potential high temperatures. An artificial neural network (ANN) model was implemented to predict thermal conductivity, and 15 training functions were examined for the ANN structure. The model's best prediction results were obtained by utilizing tansig and Purlin transfer functions in a single hidden layer with ten neurons, which employed the Bayesian regularization function. It reached R² = 99.99%, MSE = 4.8352 × 10⁻⁷, and RMSE = 1.2083 × 10⁻³, which is superior to other functions, e.g. trainlm. The novelty is successfully synthesizing a stable GNP-CNC hybrid nanofluid with excellent thermophysical properties and establishing a highly accurate predictive model. The impact could be widespread in various industries, from better cooling to more efficient energy systems, and even the applicability of this effect in improving industrial processes.

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利用人工神经网络预测EG/水基GNP/CNC混合纳米流体导热系数的性能评价

由于传统传热流体性能的极限限制，热管理效率在许多行业和技术中仍然是一个重要的问题。本研究的重点是预测混合石墨烯纳米血小板（GNP）和纤维素纳米晶体（CNC）纳米颗粒的热物理性质，以改善传热系统的热性能。解决热管理问题对于节约能源、提高系统效率、推进处理高温所需的现有和新兴技术至关重要。制备了体积浓度为0.01 ~ 0.2%的GNP-CNC/乙二醇-水杂化纳米流体。在30 ~ 80℃范围内测量了导热系数，为分析提供了全面的数据。最重要的分辨率是在体积浓度为0.1%，乙二醇和水体积比为60:40的情况下配制的，紫外-可见分析显示，在0.10%和0.2%的浓度下吸收峰最高。热重分析表明，热弹性增加，质量下降开始于130°C，在500°C时完全降解。对0.20% GNP: CNC进行了有趣的观察，其中降解发生在150°C，提供了更多的潜在高温。采用人工神经网络（ANN）模型进行热导率预测，并对人工神经网络结构进行了15个训练函数检验。利用tansig和Purlin传递函数在10个神经元的单个隐藏层中使用贝叶斯正则化函数，获得了模型的最佳预测结果。R2 = 99.99%, MSE = 4.8352 × 10−7,RMSE = 1.2083 × 10−3，优于trainlm等其他函数。成功合成了具有优异热物理性能的稳定的GNP-CNC混合纳米流体，并建立了高精度的预测模型。这种影响可以广泛应用于各个行业，从更好的冷却到更有效的能源系统，甚至可以应用于改善工业过程。

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来源期刊

Journal of Thermal Analysis and Calorimetry 化学-分析化学

CiteScore

8.50

自引率

9.10%

发文量

577

审稿时长

3.8 months

期刊介绍： Journal of Thermal Analysis and Calorimetry is a fully peer reviewed journal publishing high quality papers covering all aspects of thermal analysis, calorimetry, and experimental thermodynamics. The journal publishes regular and special issues in twelve issues every year. The following types of papers are published: Original Research Papers, Short Communications, Reviews, Modern Instruments, Events and Book reviews. The subjects covered are: thermogravimetry, derivative thermogravimetry, differential thermal analysis, thermodilatometry, differential scanning calorimetry of all types, non-scanning calorimetry of all types, thermometry, evolved gas analysis, thermomechanical analysis, emanation thermal analysis, thermal conductivity, multiple techniques, and miscellaneous thermal methods (including the combination of the thermal method with various instrumental techniques), theory and instrumentation for thermal analysis and calorimetry.