Flexibility management and decision making in cyber-physical systems utilizing digital lean principles with Brain-inspired computing pattern recognition in Industry 4.0

IF 3.7 3区 工程技术 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Praful P. Ulhe, Aditya D. Dhepe, Vaibhav Devidas Shevale, Yash S. Warghane, Prayag S Jadhav, Success L. Babhare
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引用次数: 0

Abstract

Industry 4.0 and its accompanying Cyber-Physical Manufacturing Systems in digitized have recently made new approaches to optimising production operations in manufacturing. The objective of this article is to evaluate how digital lean principles can support Industry 4.0 in pursuit of reducing non-value-added tasks from production processes, flexibility management and decision-making process with machine learning techniques. This research study comes under three levels, such as data level, information level, and knowledge level. Initially, the data from the CNC machine are collected via a Wireless Sensor Network (WSN). The collected data are stored in the cloud platform where the unwanted wastes of 7 Muda are removed by using the Value Stream Mapping (VSM 4.0) tool. It is critical in the big data world to have a systematic method for gathering, managing, and analysing data to gain valuable insights from it. Predictive maintenance provides a detailed examination of the detection, location and diagnosis of faults in related types of machinery. Accordingly, Big Data Analytics empowers the lean principle technique of Total Productive Maintenance (TPM) is suggested for avoiding potential failures to predict maintenance by allowing KPIs to be calculated in real-time. This approach requires high-performance procedures and adaptable manufacturing systems in the current digitalized lean. The information is then processed in the knowledge layer, utilizing the algorithm, rule and lean knowledge bases. The flexibility of manufacturing firms is determined by the adaptability of their shop floor processes. To meet these requirements the article developed pull control techniques of capacity slack CONWIP (CSC) control in digital lean production systems to guide the CPS deployment to offer flexible production systems. Reliable software systems are hoped to facilitate data analysis and autonomous decision-making. Finally, in the decision-making process, the article proposed the Brain-Inspired Computing of Structural and Syntactic (BIC-SS) pattern recognition method. The performance analysis of these findings is simulated in MATLAB software. Simulation can be done with the identification of ideal Kanban parameters like cycle time, lead time, delivery frequency and lot size. Furthermore, lean manufacturing improves company quality and productivity by decreasing waste and production costs, as well as adapting well to the many innovative systems that encourage the culture of change and quality inside organizations.
工业4.0中利用数字精益原则和大脑启发计算模式识别的网络物理系统中的灵活性管理和决策
工业4.0及其伴随的数字化信息物理制造系统最近为优化制造业的生产操作提供了新的方法。本文的目的是评估数字化精益原则如何支持工业4.0,通过机器学习技术减少生产过程、灵活性管理和决策过程中的非增值任务。本研究分为数据层、信息层和知识层三个层次。最初,CNC机器的数据是通过无线传感器网络(WSN)收集的。收集到的数据存储在云平台中,通过价值流映射(VSM 4.0)工具将7 Muda的不需要的浪费去除。在大数据世界中,有一个系统的方法来收集、管理和分析数据,从中获得有价值的见解是至关重要的。预测性维护提供了对相关类型机械故障的检测、定位和诊断的详细检查。因此,大数据分析赋予了全面生产维护(TPM)的精益原则技术,通过实时计算kpi来避免潜在的故障来预测维护。这种方法需要当前数字化精益的高性能流程和适应性强的制造系统。然后在知识层利用算法、规则和精益知识库对信息进行处理。制造企业的灵活性是由其车间流程的适应性决定的。为了满足这些需求,本文开发了数字化精益生产系统中容量松弛CONWIP (CSC)控制的拉控制技术,以指导CPS的部署,提供灵活的生产系统。可靠的软件系统有望促进数据分析和自主决策。最后,在决策过程中,本文提出了脑启发计算结构和句法(BIC-SS)模式识别方法。在MATLAB软件中对这些结果进行了性能分析。模拟可以通过确定理想的看板参数来完成,如周期时间、交货时间、交货频率和批量大小。此外,精益生产通过减少浪费和生产成本,以及很好地适应许多鼓励组织内部变革和质量文化的创新系统,提高了公司的质量和生产力。
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
CiteScore
9.00
自引率
9.80%
发文量
73
审稿时长
10 months
期刊介绍: International Journal of Computer Integrated Manufacturing (IJCIM) reports new research in theory and applications of computer integrated manufacturing. The scope spans mechanical and manufacturing engineering, software and computer engineering as well as automation and control engineering with a particular focus on today’s data driven manufacturing. Terms such as industry 4.0, intelligent manufacturing, digital manufacturing and cyber-physical manufacturing systems are now used to identify the area of knowledge that IJCIM has supported and shaped in its history of more than 30 years. IJCIM continues to grow and has become a key forum for academics and industrial researchers to exchange information and ideas. In response to this interest, IJCIM is now published monthly, enabling the editors to target topical special issues; topics as diverse as digital twins, transdisciplinary engineering, cloud manufacturing, deep learning for manufacturing, service-oriented architectures, dematerialized manufacturing systems, wireless manufacturing and digital enterprise technologies to name a few.
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