A life-cycle digital-twin collaboration framework based on the industrial internet identification and resolution

The new generation of smart manufacturing technology enables upgrading within the manufacturing industry, as well as increase the complexity of manufacturing systems. The integration of information and ontology across the full life cycle of a product involves multi-scientific and multi-disciplinary...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2022-12, Vol.123 (7-8), p.2883-2911
Main Authors: Fan, Yepeng, Dai, Chaoren, Huang, Si, Hu, Pengcheng, Wang, Xiaoyu, Yan, Man
Format: Article
Language:English
Subjects:
Agile manufacturing
CAE) and Design
Chains
Collaboration
Computer-Aided Engineering (CAD
Cyber-physical systems
Digital twins
Engineering
Flexible manufacturing systems
Industrial and Production Engineering
Internet
Manufacturing
Mechanical Engineering
Media Management
Ontology
Original Article
Prototyping
Upgrading
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Summary:The new generation of smart manufacturing technology enables upgrading within the manufacturing industry, as well as increase the complexity of manufacturing systems. The integration of information and ontology across the full life cycle of a product involves multi-scientific and multi-disciplinary dimensions. It requires a deep integration of industry chain enterprises in the process of domain ontology sharing and digital asset collaboration to achieve an efficient “new demand → existing ontology → innovation → new product → new ontology” agile manufacturing paradigm transfer. A digital-twin and ontology collaboration framework based on the industrial internet identification and resolution system (I 3 R system) is presented in this paper. Taking flexible manufacturing system (FMS) as an example, the four core key technologies required in this framework are described in detail: (1) a generic digital-twin modeling approach for the full life cycle of FMS; (2) ontology for the full life cycle of FMS; (3) digital-twin data collection technology for human-cyber-physical system (HCPS) in smart manufacturing; (4) distributed collaboration framework based on I 3 R. To illustrate in detail how the proposed methods and techniques can be applied in reality, we show different application scenarios based on the proposed methods and techniques in the various stages of the full FMS life cycle. Meanwhile, the implementation method of the I 3 R system-based digital-twin collaborative prototyping platform for industry chain cooperative enterprises is discussed, as well as the idea of its derived top-level application.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-022-10269-1