Optimizing Numerous Influencing Parameters of Nano-SiO2/Banana Fiber-Reinforced Hybrid Composites using Taguchi and ANN Approach

4区 材料科学 Q2 Materials Science
L. Natrayan, Raviteja Surakasi, Pravin P. Patil, S. Kaliappan, V. Selvam, P. Murugan
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引用次数: 2

Abstract

High specific strength, strength-to-weight ratio, cheap cost, and other advantages, nanofillers are now the subject of most research on natural fibers. The current research’s main goal is to combine the Taguchi and artificial neural networks (ANN) approaches to maximize the mechanical characteristics of nanocomposites. The parameters: (i) nano-SiO2 wt%, (ii) banana fiber wt%, (iii) compression pressure in MPa, and (iv) compression molding temperature in °C were selected to achieve the objectives above. An L16 orthogonal array was used to optimize the process parameters based on the Taguchi technique. According to the intended experiment, mechanical characteristics, such as tension, bending, and impact strength, were assessed. The ANN was used to forecast outcomes that were optimized. The fiber mat thickness of banana fiber and the weight ratio of nano-SiO2 showed a considerable improvement in the mechanical characteristics of hybrid composites. According to the Taguchi technique, the most significant mechanical characteristics were 47.36 MPa tensile, 64.48 MPa flexural, and 35.33 kJ of impact under circumstances of 5% SiO2, 19 MPa pressure, and 110 °C. With 95% accuracy, ANN-predicted mechanical strength. The ANN forecast was more accurate than the regression model and experimental data. The above nanobased hybrid composites are mainly employed to satisfy the needs of the contemporary vehicle sector.
采用田口法和人工神经网络优化纳米sio2 /香蕉纤维增强混杂复合材料的众多影响参数
纳米填料具有比强度高、强重比大、成本低廉等优点,是目前天然纤维研究的热点。目前研究的主要目标是结合田口法和人工神经网络(ANN)方法来最大限度地提高纳米复合材料的力学特性。为实现上述目标,选择的参数为(i)纳米sio2 wt%, (ii)香蕉纤维wt%, (iii)压缩压力MPa, (iv)压缩成型温度℃。以田口法为基础,采用L16正交阵列法对工艺参数进行优化。根据预期的实验,机械特性,如张力,弯曲和冲击强度,进行了评估。利用人工神经网络对优化后的结果进行预测。香蕉纤维的纤维垫厚度和纳米sio2的重量比对混杂复合材料的力学性能有较大的改善。根据Taguchi技术,在5% SiO2、19 MPa压力和110°C条件下,最显著的力学特性是47.36 MPa拉伸、64.48 MPa弯曲和35.33 kJ冲击。人工神经网络预测机械强度的准确率为95%。人工神经网络预测比回归模型和实验数据更准确。上述纳米基混合复合材料主要用于满足当代汽车领域的需求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Nanomaterials
Journal of Nanomaterials 工程技术-材料科学:综合
CiteScore
6.10
自引率
0.00%
发文量
577
审稿时长
2.3 months
期刊介绍: The overall aim of the Journal of Nanomaterials is to bring science and applications together on nanoscale and nanostructured materials with emphasis on synthesis, processing, characterization, and applications of materials containing true nanosize dimensions or nanostructures that enable novel/enhanced properties or functions. It is directed at both academic researchers and practicing engineers. Journal of Nanomaterials will highlight the continued growth and new challenges in nanomaterials science, engineering, and nanotechnology, both for application development and for basic research.
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