Abstract

Modern cyber manufacturing has been introduced into a broad range of manufacturing processes to ease their digital reconfigurability and enhance flexibility while retaining a high throughput of quality products. Such a system provides real-time data acquisition, enabling monitoring of the actual condition of the manufacturing process. The Industrial Internet of Things (IIoT) facilitates such real-time monitoring and optimization of the fabricating system, which reduces time necessary for maintenance with the possibility of almost instantaneously taking any necessary corrective measures with respect to either human to the machine/process from learned algorithms. In this research, an original IIoT approach has been proposed to monitor the process conditions, including nozzle temperature and filament breakage/runout, of the additive manufacturing process. In particular, concurrent multi-task IIoT communication was developed for a network of five nodes. This was implemented to ensure real time monitoring of the manufacturing process via multi sensors and empowered by an embedded software design. The proposed embedded software architecture offers a reliable solution to eliminate communication latency and provides real-time response to acquired information. It is worth emphasizing that the embedded software was designed so that it optimally exploits the very great potential of the hardware resources, with the ability to detect run-time issues in the nodes’ performance and re-try to address such issues to maintain a high capability networking communication. The designed architecture also offers auto-scaling throughput of the data transferred to the cloud to minimize the bandwidth.

Full Text
Published version (Free)

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call