Abstract
A digital twin of a manufacturing system is a digital copy of the physical manufacturing system that consists of various digital models at multiple scales and levels. Digital twins that communicate with their physical counterparts throughout their lifecycle are the basis for data-driven factories. The problem with developing digital models that form the digital twin is that they operate with large amounts of heterogeneous data. Since the models represent simplifications of the physical world, managing the heterogeneous data and linking the data with the digital twin represent a challenge. The paper proposes a five-step approach to planning data-driven digital twins of manufacturing systems and their processes. The approach guides the user from breaking down the system and the underlying building blocks of the processes into four groups. The development of a digital model includes predefined necessary parameters that allow a digital model connecting with a real manufacturing system. The connection enables the control of the real manufacturing system and allows the creation of the digital twin. Presentation and visualization of a system functioning based on the digital twin for different participants is presented in the last step. The suitability of the approach for the industrial environment is illustrated using the case study of planning the digital twin for material logistics of the manufacturing system.
Highlights
All manufacturing systems, and a discrete manufacturing system should be more agile, flexible, and sustainable to cope with the dynamic changes in the manufacturing environment and market demands, while maintaining the quality of manufactured products [2,3,4]
We use a very similar interpretation of the digital twin in our approach, but our research focuses on the development of the digital twin, not just on the presentation of advantages of using the digital twin in manufacturing
Case, In thethe results were based on a linear assembly line with different building blocks
Summary
A discrete manufacturing system (where distinct items are manufactured [1]) should be more agile, flexible, and sustainable to cope with the dynamic changes in the manufacturing environment and market demands, while maintaining the quality of manufactured products [2,3,4]. This has been addressed by the concept of data-driven factories, which are characterized by the following features: agility, learning capability, and human-oriented manufacturing [5]. To develop the data-driven digital factory, digital models are a key enabling technology
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