Abstract
Digital twins offer a unique opportunity to design, test, deploy, monitor, and control real-world robotic processes. In this paper we present a novel, modular digital twinning framework developed for the investigation of safety within collaborative robotic manufacturing processes. The modular architecture supports scalable representations of user-defined cyber-physical environments, and tools for safety analysis and control. This versatile research tool facilitates the creation of mixed environments of Digital Models, Digital Shadows, and Digital Twins, whilst standardising communication and physical system representation across different hardware platforms. The framework is demonstrated as applied to an industrial case-study focused on the safety assurance of a collaborative robotic manufacturing process. We describe the creation of a digital twin scenario, consisting of individual digital twins of entities in the manufacturing case study, and the application of a synthesised safety controller from our wider work. We show how the framework is able to provide adequate evidence to virtually assess safety claims made against the safety controller using a supporting validation module and testing strategy. The implementation, evidence and safety investigation is presented and discussed, raising exciting possibilities for the use of digital twins in robotic safety assurance.
Highlights
Collaborative robots promise to transform the manufacturing sector, enabling humans and robots to work together in shared spaces and physically interact to maximise the benefits of both manual and robotic processes
The modular digital twins (DTs) paradigm supports the collection of evidence for safety assurance tasks on new scenarios offline and before their deployment, as we demonstrated with the addition of a novel work-preserving safety controller in an industrial work-cell
We present a highly modular environment for the development of safety critical digital-twins for collaborative robotic processes
Summary
Collaborative robots promise to transform the manufacturing sector, enabling humans and robots to work together in shared spaces and physically interact to maximise the benefits of both manual and robotic processes. As such the market for collaborative robots has seen rapid growth in recent years, and is predicted to reach $5.6bn by 2027, accounting for 30% of the total robot market (Interact analysis, 2019). In Kritzinger et al (2018), an indepth review is categorising concepts associated with DTs is provided Concepts such as the Digital Shadow (DS) and Digital Model (DM), differ with respect to the communication infrastructure between the physical and digital components; which is typically unilateral or not considered, respectively. The user is presented with a single interface to the cyber-physical system (CPS) that persists throughout its operational life time (Kritzinger et al, 2018; Qi et al, 2018)
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