Artificial neural networks-based modelling of effects of cryogenic electrode treatment, nano-powder, and surfactant-mixed dielectrics on wear performance and dimensional errors on superalloy machining

IF 1.8 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Muhammad Sana, Anamta Khan, Muhammad Umar Farooq, Saqib Anwar
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Abstract

In the present era dominated by Industry 4.0, the digital transformation and intelligent management of industrial systems is significantly important to enhance efficiency, quality, and the effective use of resources. This underscores the need for a framework that goes beyond merely boosting productivity and work quality, aiming for a net-zero impact from industrial activities. This research introduces a comprehensive and adaptable analytical framework intended to bridge existing gaps in research and technology within the manufacturing sector. It encompasses the essential stages of using artificial intelligence (AI) for modelling and optimizing manufacturing systems. The effectiveness of the proposed AI framework is evaluated through a case study on electric discharge machining (EDM), concentrating on optimizing the electrode wear rate (EWR) and overcut (OC) for aerospace alloy Inconel 617. Utilizing a comprehensive design of experiments, the process modelling through an artificial neural network (ANN) is carried out, accompanied by careful fine-tuning of hyperparameters throughout the training process. The trained models are further assessed using an external validation (Valext) dataset. The results of the sensitivity analysis indicated that the surfactant concentration (Sc) has the highest level of influence, accounting for 52.41% of the observed influence on the EWR, followed by the powder concentration (Cp) with a contribution of 33.14%, and the treatment variable with a contribution of 14.43%. Regarding OC, Sc holds the highest percentage significance at 72.67%, followed by Cp at 21.25%, and treatment at 6.06%. Additionally, parametric optimization (PO) shows that EWR and OC overcome experimental data by 47.05% and 85.00%, respectively, showcasing successful performance optimization with potential applications across diverse manufacturing systems.

Abstract Image

基于人工神经网络的低温电极处理、纳米粉末和表面活性剂混合电介质对超耐热合金加工磨损性能和尺寸误差影响的建模研究
在当今以工业 4.0 为主导的时代,工业系统的数字化转型和智能化管理对于提高效率、质量和资源的有效利用至关重要。这就强调了需要一个不仅仅能提高生产率和工作质量,而且能实现工业活动净零影响的框架。这项研究引入了一个全面、适应性强的分析框架,旨在弥补制造业在研究和技术方面的现有差距。它涵盖了使用人工智能(AI)对制造系统进行建模和优化的基本阶段。通过对电火花加工(EDM)的案例研究,对所提出的人工智能框架的有效性进行了评估,重点是优化航空航天合金 Inconel 617 的电极磨损率(EWR)和过切削(OC)。利用综合实验设计,通过人工神经网络(ANN)进行工艺建模,并在整个训练过程中对超参数进行仔细微调。使用外部验证(Valext)数据集对训练好的模型进行进一步评估。敏感性分析的结果表明,表面活性剂浓度(Sc)的影响程度最大,占观察到的对 EWR 影响的 52.41%,其次是粉末浓度(Cp),占 33.14%,处理变量占 14.43%。在 OC 方面,Sc 的显著性最高,占 72.67%,其次是 Cp,占 21.25%,处理变量占 6.06%。此外,参数优化(PO)表明,EWR 和 OC 分别以 47.05% 和 85.00% 的优势战胜了实验数据,展示了性能优化的成功,并有望应用于各种制造系统。
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来源期刊
CiteScore
3.60
自引率
13.60%
发文量
536
审稿时长
4.8 months
期刊介绍: The Journal of the Brazilian Society of Mechanical Sciences and Engineering publishes manuscripts on research, development and design related to science and technology in Mechanical Engineering. It is an interdisciplinary journal with interfaces to other branches of Engineering, as well as with Physics and Applied Mathematics. The Journal accepts manuscripts in four different formats: Full Length Articles, Review Articles, Book Reviews and Letters to the Editor. Interfaces with other branches of engineering, along with physics, applied mathematics and more Presents manuscripts on research, development and design related to science and technology in mechanical engineering.
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