通过精益六西格玛和基于工业4.0的零缺陷提高制造卓越性

M. Ly Duc, L. Hlavaty, P. Bilik, R. Martinek
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摘要

提高质量,提高生产率,重新设计加工工具,消除生产中的浪费,缩短交货时间,这些都是旨在提高客户满意度和增加制造公司盈利能力的目标。本研究运用DMAIC(定义-测量-分析-改进-控制)模型,将精益制造与六西格玛技术相结合,形成精益六西格玛(LSS)技术。本研究建议使用统计检验模型来分析直接从操作员处收集的真实数据。本研究提出采用田口优化技术确定钼材料浸油罐的最佳工艺条件。此外,本研究还提出了一种利用LABVIEW软件平台上的颜色识别技术进行物体识别的计算机视觉技术。本研究以数位讯号处理技术为基础,建立数位数位控制(DNC)模型,将各工序的资料连结在一起。结果使整个加工阶段的次品率从6.5%降至零次品,整条加工线的生产能力提高了7.9%,整条生产线的利润为35762美元/年。作为一个有价值的外部结果,LSS项目的结束培养了一种持续改进的精神。对于作业者来说,研究环境的研究结果在实际生产环境中的利用率大大提高。为LSS项目团队的每个成员配置了具体的任务和目标,并优化了每个特定阶段的加工条件,如浸油工艺和磨孔工艺。工业4.0技术,包括计算机视觉、数字数控和商业软件,如LabVIEW和MINITAB,都经过优化,简化了加工操作。并对今后的研究方向提出了建议。例如,研究通过消除加工厂的谐波来改善220v电源的质量是一个有趣的研究领域。此外,在工业4.0背景下探索大数据的数据安全将是一个有价值的研究,以提高未来大数据技术的客户满意度。
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Enhancing manufacturing excellence with Lean Six Sigma and zero defects based on Industry 4.0
Improving quality, enhancing productivity, redesigning machining tools, eliminating waste in production, and shortening lead time are all objectives aimed at improving customer satisfaction and increasing profitability for manufacturing companies. This study combines lean manufacturing and six sigma techniques to form a technique called Lean Six Sigma (LSS) by using the DMAIC (Define-Measure-Analysis-Improve-Control) model. This study proposes to use statistical test models to analyze real data collected directly from the operator. The study proposes to use the Taguchi optimization technique to determine the optimal conditions for oil dipping tanks of molybdenum materials. In addition, the study also proposes a computer vision technique to recognize objects using color recognition techniques running on the LABVIEW software platform. This study builds a digital numerical control (DNC) model operating on digital signal processing techniques, linking the data of each process together. The results reduced the rate of defective parts in the whole processing stage from 6.5 % to zero defects, the whole processing line production capacity increased by 7.9 %, and the profit of the whole production line was USD 35762 per year. As a valuable external outcome, the conclusion of the LSS project fostered a spirit of continuous improvement. The utilization of research results from the research environment in the actual production setting is significantly enhanced for the operator. The LSS model is deployed with specific tasks and targets for each member of the LSS project team, and the processing conditions for each specific stage are optimized, such as the oil dipping process and hole grinding process. Industry 4.0 techniques, including computer vision, digital numerical control, and commercial software such as LabVIEW and MINITAB, are optimized for use, simplifying machining operations. Some proposed directions for future research are also presented in detail. For example, studying the improvement of the quality of the 220 V power supply through harmonic mitigation in processing factories is an intriguing area of investigation. Additionally, exploring data security for big data in the context of Industry 4.0 would be a valuable study to enhance customer satisfaction with big data technology in the future.
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