Synchroperation in industry 4.0 manufacturing

Daqiang Guo; Mingxing Li; Zhongyuan Lyu; Kai Kang; Wei Wu; Ray Y. Zhong; George Q. Huang

doi:10.1016/j.ijpe.2021.108171

Synchroperation in industry 4.0 manufacturing

Daqiang Guo, Mingxing Li, Zhongyuan Lyu, Kai Kang, Wei Wu, Ray Y. Zhong, George Q. Huang

Research output: Journal article publication › Journal article › Academic research › peer-review

87 Citations (Scopus)

Abstract

Industry 4.0 connotes a new industrial revolution with the convergence between physical and digital spaces, which is revolutionizing the way that production operations are managed. The requirement of increased productivity, improved flexibility and resilience, and reduced cost in Industry 4.0 manufacturing calls for new paradigms that comply with the changing of production and operations management. In this paper, a concept of synchroperation, which is defined as “synchronized operations in an agile, resilient and cost-efficient way, with the spatiotemporal synchronization of men, machines and materials as well as data-driven decision-making, by creating, establishing and utilizing cyber-physical visibility and traceability in operations management”, is proposed as a new paradigm of production and operations management for Industry 4.0 manufacturing. A Hyperconnected Physical Internet-enabled Smart Manufacturing Platform (HPISMP) is developed as a technical solution to support manufacturing synchroperation. Graduation Intelligent Manufacturing System (GiMS) with divide and conquer principles is proposed to address the complex, stochastic, and dynamic nature of manufacturing for achieving synchroperation. An industrial case is carried out to validate the effectiveness of the proposed concept and method. This article provides insight into exploring production and operations management in the era of Industry 4.0.

Original language	English
Article number	108171
Journal	International Journal of Production Economics
Volume	238
DOIs	https://doi.org/10.1016/j.ijpe.2021.108171
Publication status	Published - Aug 2021
Externally published	Yes

Keywords

Graduation intelligent manufacturing system (GiMS)
Industry 4.0
Manufacturing synchroperation
Production and operations management

ASJC Scopus subject areas

General Business,Management and Accounting
Economics and Econometrics
Management Science and Operations Research
Industrial and Manufacturing Engineering

More information

10.1016/j.ijpe.2021.108171

Cite this

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title = "Synchroperation in industry 4.0 manufacturing",

abstract = "Industry 4.0 connotes a new industrial revolution with the convergence between physical and digital spaces, which is revolutionizing the way that production operations are managed. The requirement of increased productivity, improved flexibility and resilience, and reduced cost in Industry 4.0 manufacturing calls for new paradigms that comply with the changing of production and operations management. In this paper, a concept of synchroperation, which is defined as “synchronized operations in an agile, resilient and cost-efficient way, with the spatiotemporal synchronization of men, machines and materials as well as data-driven decision-making, by creating, establishing and utilizing cyber-physical visibility and traceability in operations management”, is proposed as a new paradigm of production and operations management for Industry 4.0 manufacturing. A Hyperconnected Physical Internet-enabled Smart Manufacturing Platform (HPISMP) is developed as a technical solution to support manufacturing synchroperation. Graduation Intelligent Manufacturing System (GiMS) with divide and conquer principles is proposed to address the complex, stochastic, and dynamic nature of manufacturing for achieving synchroperation. An industrial case is carried out to validate the effectiveness of the proposed concept and method. This article provides insight into exploring production and operations management in the era of Industry 4.0.",

keywords = "Graduation intelligent manufacturing system (GiMS), Industry 4.0, Manufacturing synchroperation, Production and operations management",

author = "Daqiang Guo and Mingxing Li and Zhongyuan Lyu and Kai Kang and Wei Wu and Zhong, {Ray Y.} and Huang, {George Q.}",

note = "Funding Information: There are several typical manufacturing paradigms such as flexible manufacturing system (FMS), reconfigurable manufacturing systems (RMS), computer-integrated manufacturing (CIM) and agile manufacturing (AM). Both FMS and RMS are introduced to increase flexibility and changeability in order to adapt to rapid changes in the type and volume of products (ElMaraghy, 2005; Wiendahl et al., 2007), but FMS provides general flexibility while RMS provides customized flexibility (Koren et al., 2018; Yadav and Jayswal, 2018). CIM utilizes computers and communication networks to establish highly interconnected manufacturing systems for controlling the entire production process (Nagalingam and Lin, 1999). AM enables enterprises to respond quickly to changing markets driven by individual customer specifications at a low cost but high-quality level (Gunasekaran et al., 2019), which is characterized by the customer-supplier integrated process for design, production, marketing and support services (Gunasekaran, 1999). JIT emphasizing that only the necessary products, at the necessary time, in necessary quantity are manufactured, has played a key role in revolutionizing production and operations management for the modern manufacturing industry (Holweg, 2007). The marriage of JIT and these manufacturing paradigms has rendered the feasibility of developing advanced manufacturing systems, such as ERP, APS, and MES.With the support of automation, information and communications technology as well as optimization models/algorithms, traditional production planning and control approaches focus on cost-efficiency centred around CIM and lean production methods. While based on automation, IoT, CPS, cloud computing, digital twin, blockchain, AI and optimization technologies, GiMS focuses on agility, resilience and cost-efficiency through cyber-physical synchronization, data-driven decision synchronization and spatio-temporal synchronization. Additionally, traditional production planning and control approaches mainly rely on client-server systems and web-server systems, while with the support of emerging technologies, GiMS uses VR/MR and cloud-based industrial Apps with enhanced visibility and mobility.Acknowledgement to Zhejiang Provincial, Hangzhou Municipal, Lin'an City Governments, Hong Kong ITF Innovation and Technology Support Program (ITP/079/16LP) and financial support from the 2019 Guangdong Special Support Talent Program-Innovation and Entrepreneurship Leading Team (China) (2019BT02S593). Funding Information: Acknowledgement to Zhejiang Provincial, Hangzhou Municipal, Lin'an City Governments, Hong Kong ITF Innovation and Technology Support Program ( ITP/079/16LP ) and financial support from the 2019 Guangdong Special Support Talent Program-Innovation and Entrepreneurship Leading Team (China) ( 2019BT02S593 ). Publisher Copyright: {\textcopyright} 2021 Elsevier B.V.",

year = "2021",

month = aug,

doi = "10.1016/j.ijpe.2021.108171",

language = "English",

volume = "238",

journal = "International Journal of Production Economics",

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AU - Guo, Daqiang

AU - Li, Mingxing

AU - Lyu, Zhongyuan

AU - Kang, Kai

AU - Wu, Wei

AU - Zhong, Ray Y.

AU - Huang, George Q.

N1 - Funding Information: There are several typical manufacturing paradigms such as flexible manufacturing system (FMS), reconfigurable manufacturing systems (RMS), computer-integrated manufacturing (CIM) and agile manufacturing (AM). Both FMS and RMS are introduced to increase flexibility and changeability in order to adapt to rapid changes in the type and volume of products (ElMaraghy, 2005; Wiendahl et al., 2007), but FMS provides general flexibility while RMS provides customized flexibility (Koren et al., 2018; Yadav and Jayswal, 2018). CIM utilizes computers and communication networks to establish highly interconnected manufacturing systems for controlling the entire production process (Nagalingam and Lin, 1999). AM enables enterprises to respond quickly to changing markets driven by individual customer specifications at a low cost but high-quality level (Gunasekaran et al., 2019), which is characterized by the customer-supplier integrated process for design, production, marketing and support services (Gunasekaran, 1999). JIT emphasizing that only the necessary products, at the necessary time, in necessary quantity are manufactured, has played a key role in revolutionizing production and operations management for the modern manufacturing industry (Holweg, 2007). The marriage of JIT and these manufacturing paradigms has rendered the feasibility of developing advanced manufacturing systems, such as ERP, APS, and MES.With the support of automation, information and communications technology as well as optimization models/algorithms, traditional production planning and control approaches focus on cost-efficiency centred around CIM and lean production methods. While based on automation, IoT, CPS, cloud computing, digital twin, blockchain, AI and optimization technologies, GiMS focuses on agility, resilience and cost-efficiency through cyber-physical synchronization, data-driven decision synchronization and spatio-temporal synchronization. Additionally, traditional production planning and control approaches mainly rely on client-server systems and web-server systems, while with the support of emerging technologies, GiMS uses VR/MR and cloud-based industrial Apps with enhanced visibility and mobility.Acknowledgement to Zhejiang Provincial, Hangzhou Municipal, Lin'an City Governments, Hong Kong ITF Innovation and Technology Support Program (ITP/079/16LP) and financial support from the 2019 Guangdong Special Support Talent Program-Innovation and Entrepreneurship Leading Team (China) (2019BT02S593). Funding Information: Acknowledgement to Zhejiang Provincial, Hangzhou Municipal, Lin'an City Governments, Hong Kong ITF Innovation and Technology Support Program ( ITP/079/16LP ) and financial support from the 2019 Guangdong Special Support Talent Program-Innovation and Entrepreneurship Leading Team (China) ( 2019BT02S593 ). Publisher Copyright: © 2021 Elsevier B.V.

PY - 2021/8

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N2 - Industry 4.0 connotes a new industrial revolution with the convergence between physical and digital spaces, which is revolutionizing the way that production operations are managed. The requirement of increased productivity, improved flexibility and resilience, and reduced cost in Industry 4.0 manufacturing calls for new paradigms that comply with the changing of production and operations management. In this paper, a concept of synchroperation, which is defined as “synchronized operations in an agile, resilient and cost-efficient way, with the spatiotemporal synchronization of men, machines and materials as well as data-driven decision-making, by creating, establishing and utilizing cyber-physical visibility and traceability in operations management”, is proposed as a new paradigm of production and operations management for Industry 4.0 manufacturing. A Hyperconnected Physical Internet-enabled Smart Manufacturing Platform (HPISMP) is developed as a technical solution to support manufacturing synchroperation. Graduation Intelligent Manufacturing System (GiMS) with divide and conquer principles is proposed to address the complex, stochastic, and dynamic nature of manufacturing for achieving synchroperation. An industrial case is carried out to validate the effectiveness of the proposed concept and method. This article provides insight into exploring production and operations management in the era of Industry 4.0.

AB - Industry 4.0 connotes a new industrial revolution with the convergence between physical and digital spaces, which is revolutionizing the way that production operations are managed. The requirement of increased productivity, improved flexibility and resilience, and reduced cost in Industry 4.0 manufacturing calls for new paradigms that comply with the changing of production and operations management. In this paper, a concept of synchroperation, which is defined as “synchronized operations in an agile, resilient and cost-efficient way, with the spatiotemporal synchronization of men, machines and materials as well as data-driven decision-making, by creating, establishing and utilizing cyber-physical visibility and traceability in operations management”, is proposed as a new paradigm of production and operations management for Industry 4.0 manufacturing. A Hyperconnected Physical Internet-enabled Smart Manufacturing Platform (HPISMP) is developed as a technical solution to support manufacturing synchroperation. Graduation Intelligent Manufacturing System (GiMS) with divide and conquer principles is proposed to address the complex, stochastic, and dynamic nature of manufacturing for achieving synchroperation. An industrial case is carried out to validate the effectiveness of the proposed concept and method. This article provides insight into exploring production and operations management in the era of Industry 4.0.

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Synchroperation in industry 4.0 manufacturing

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Keywords

ASJC Scopus subject areas

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