Modeling of the shape of Taylor cone in EHD printing based on backpropagation neural network and genetic algorithm

IF 1.9 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Journal of Electrostatics Pub Date : 2024-04-17 DOI:10.1016/j.elstat.2024.103928
Yang Cheng , Ran Huang , Jianfeng Yu
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Abstract

Electrohydrodynamic (EHD) printing has been recognized as a promising additive manufacturing technology with superior pattern resolution and economic viability. The shape of Taylor cone is deemed a pivotal element for the amplification of deposition efficiency, and the maintenance of consistent operational steadiness in EHD printing. The correlations between diverse operating parameters and the shape of Taylor cone are presently not well investigated. In this paper, modeling of relationships between operating parameters and the shape of Taylor cone was conducted with a backpropagation neural network (BPNN) and a genetic algorithm optimized backpropagation (GA-BP) neural network. Taylor cone semi-vertical angle and the meniscus height were employed as two indexes to characterize the shape of Taylor cone. The prediction accuracies of BPNN model and GA-BP model were 92.79 % and 95.46 %, respectively. The GA-BP model demonstrated higher precision in forecasting the shape of Taylor cone. A predictive framework for the shape of Taylor cone was proposed, which provided a practical tool for process optimization in EHD printing.

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基于反向传播神经网络和遗传算法的电涡流印刷泰勒锥形状建模
电流体动力(EHD)打印被认为是一种前景广阔的增材制造技术,具有卓越的图案分辨率和经济可行性。泰勒锥的形状被认为是提高沉积效率和保持 EHD 印刷稳定运行的关键因素。目前,各种操作参数与泰勒锥形状之间的相关性尚未得到很好的研究。本文利用反向传播神经网络(BPNN)和遗传算法优化反向传播神经网络(GA-BP)对操作参数与泰勒锥形状之间的关系进行了建模。泰勒锥半垂直角和半月板高度是表征泰勒锥形状的两个指标。BPNN 模型和 GA-BP 模型的预测准确率分别为 92.79 % 和 95.46 %。GA-BP 模型对泰勒锥形状的预测精度更高。本文提出了泰勒锥形状的预测框架,为 EHD 印刷的工艺优化提供了实用工具。
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来源期刊
Journal of Electrostatics
Journal of Electrostatics 工程技术-工程:电子与电气
CiteScore
4.00
自引率
11.10%
发文量
81
审稿时长
49 days
期刊介绍: The Journal of Electrostatics is the leading forum for publishing research findings that advance knowledge in the field of electrostatics. We invite submissions in the following areas: Electrostatic charge separation processes. Electrostatic manipulation of particles, droplets, and biological cells. Electrostatically driven or controlled fluid flow. Electrostatics in the gas phase.
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