Duc Minh Ly, Bilik Petr, Martinek Radek
Faculty of Commerce, Van Lang University, Ho Chi Minh City, Vietnam.
Department of Cybernetics and Biomedical Engineering, Faculty of Electrical Engineering and Computer Science, VSB-Technical University of Ostrava, 17. listopadu 15, Ostrava, 708 00, Czechia.
Sci Rep. 2025 Jul 2;15(1):22607. doi: 10.1038/s41598-025-03787-x.
This study proposes a model to integrate the Multi-Attribute Decision-Making (MADM) method into the Analysis phase of the Six Sigma (DMAIC) method to improve product quality and optimize processing conditions during high-frequency quenching heat treatment. One of the breakthroughs of the study is the combination of Industry 4.0 technology and the implementation of Shunt Active Power Filter (SAPF) to improve power quality, reduce harmonic distortion (THD), ensure product hardness of 58-62 HRC, and thermal permeability of 1.8-2.2 mm according to standards. Previously, many studies only focused on improving the heat treatment process but did not fully integrate MADM, Six Sigma, and Industry 4.0 technology, nor did any study consider the combination of SAPF to control power quality during high-frequency quenching. Another gap is the lack of quantitative assessment of operator satisfaction after improvement using PLS-SEM. The study applied the Six Sigma DMAIC model combined with MADM to analyze and rank factors affecting product quality. In the improvement phase, the Taguchi method was used to optimize processing conditions, minimizing errors in the production process. At the same time, Industry 4.0 technology and RFID systems were integrated to control production conditions in real time, ensuring the accuracy and reliability of the process. Power quality was improved thanks to the implementation of SAPF, helping to control harmonic distortion (THD) below 5% according to the IEEE 519:2022 standard, minimizing the negative impact of voltage on the heat treatment process. In addition, the study also applied PLS-SEM to measure operator satisfaction after implementing the improved system. The research results show that the rate of substandard products has decreased sharply from 90 to 1%, ensuring hardness of 58-62 HRC and thermal permeability of 1.8-2.2 mm. Power quality is better controlled, with the THD value reduced from more than 34% to less than 5%, meeting the IEEE 519:2022 standard. As a result, production costs are optimized, helping to minimize the waste of raw materials and energy. After implementing the improved system, operators' satisfaction levels have also increased significantly, reflected in the PLS-SEM measurement indicators. More importantly, this research model is not only effectively applied in the precision engineering industry but also has the potential to be expanded to many other industries, especially small and medium-sized manufacturing enterprises, helping them to increase productivity and improve product quality in the context of Industry 4.0.
本研究提出了一种模型,将多属性决策(MADM)方法集成到六西格玛(DMAIC)方法的分析阶段,以提高产品质量,并在高频淬火热处理过程中优化加工条件。该研究的突破之一是将工业4.0技术与并联有源电力滤波器(SAPF)的应用相结合,以改善电能质量、降低谐波失真(THD),确保产品硬度达到58 - 62 HRC标准,热透性达到1.8 - 2.2毫米标准。此前,许多研究仅专注于改进热处理工艺,但未充分整合MADM、六西格玛和工业4.0技术,也没有研究考虑在高频淬火过程中结合SAPF来控制电能质量。另一个差距是缺乏使用偏最小二乘结构方程模型(PLS - SEM)对改进后操作员满意度进行定量评估。该研究应用六西格玛DMAIC模型结合MADM来分析影响产品质量的因素并进行排序。在改进阶段,使用田口方法优化加工条件,将生产过程中的误差降至最低。同时,集成工业4.0技术和射频识别(RFID)系统以实时控制生产条件,确保工艺的准确性和可靠性。由于实施了SAPF,电能质量得到改善,有助于将谐波失真(THD)控制在IEEE 519:2022标准规定的5%以下,最大限度地减少电压对热处理过程的负面影响。此外,该研究还应用PLS - SEM来衡量实施改进系统后操作员的满意度。研究结果表明,不合格产品率从90%大幅降至1%,确保了硬度达到58 - 62 HRC,热透性达到1.8 - 2.2毫米。电能质量得到更好控制,THD值从超过34%降至低于5%,符合IEEE 519:2022标准。结果,生产成本得到优化,有助于最大限度地减少原材料和能源的浪费。实施改进系统后,操作员的满意度也显著提高,这在PLS - SEM测量指标中得到体现。更重要的是,该研究模型不仅在精密工程行业中得到有效应用,而且有潜力扩展到许多其他行业,特别是中小型制造企业,帮助它们在工业4.0背景下提高生产率和产品质量。
