Abstract
Exploiting available condition monitoring data of industrial machines for intelligent maintenance purposes has been attracting attention in various application fields. Machine learning algorithms for fault detection, diagnosis and prognosis are popular and easily accessible. However, our experience in working at the intersection of academia and industry showed that the major challenges of building an end-to-end system in a real-world industrial setting go beyond the design of machine learning algorithms. One of the major challenges is the design of an end-to-end data management solution that is able to efficiently store and process large amounts of heterogeneous data streams resulting from a variety of physical machines. In this paper we present the design of an end-to-end Big Data architecture that enables intelligent maintenance in a real-world industrial setting. In particular, we will discuss various physical design choices for optimizing high-dimensional queries, such as partitioning and Z-ordering, that serve as the basis for health analytics. Finally, we describe a concrete fault detection use case with two different health monitoring algorithms based on machine learning and classical statistics and discuss their advantages and disadvantages. The paper covers some of the most important aspects of the practical implementation of such an end-to-end solution and demonstrates the challenges and their mitigation for the specific application of laser cutting machines.
Highlights
Producers and owners of industrial equipment have been showing a growing interest in implementing intelligent maintenance solutions
We present a scalable Internet of things (IoT) data analytics pipeline based on a Big Data architecture which integrates heterogeneous data streams across an entire fleet of laser cutting machines
Results and discussion we perform an experimental evaluation of the query performance in relation to Spark’s physical storage optimization techniques
Summary
Producers and owners of industrial equipment have been showing a growing interest in implementing intelligent maintenance solutions. The need for end-to-end solutions for data-driven decision support systems enabling intelligent maintenance spreads over many different fields of industry and infrastructure assets. Such end-to-end solutions are expected to integrate. The field of decision support for intelligent maintenance ranges from simple condition monitoring, through fault detection, up to fault diagnosis and prognosis The latter, sometimes termed “Predictive Maintenance” is nowadays only rarely possible due to a very high variability of operating conditions compared to the low availability of data which is representative of all of these conditions. A “plug-and-play” generic solution is inadequate to detect faults or degradation in complex systems This is due to the uniqueness of the physical systems and their potential critical failure modes.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
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
