Abstract
Current efforts towards achieving better connectivity and increasing intelligence in functioning of industrial processes are guided by the Industrial Internet of Things paradigm and implicitly stimulate occurrence of data accumulation. In recent years, several researchers and industrial products have presented Historian application solutions for data accumulation. The large amounts of data that are gathered by these Historians remains mostly unused or used only for reporting purposes. So far, Historians have been focused on connectivity, data manipulation possibilities, and sometimes on low-cost solutions in order to gain higher applicability or to integrate multiple SCADA servers (e.g. Siemens–WinCC, Schneider Electric – Vijeo Citect, IGSS, Wonderware, InduSoft Web Studio, Inductive Automation – Ignition, etc.), etc. Both literature and industry are currently unable to identify a Historian solution that functions in fog and efficiently applies and is built upon Industry 4.0 ideas. The future is to conceive a proactive Historian that is able to, besides gathering data, identify dependencies and patterns for particular processes and elaborate strategies to increase performance in order to provide feedback through corrective action on the functional system. Using available solutions, determining patterns by the Historian operator in the context of big data is a tremendous effort. The motivation of this research is provided by the currently unoptimized and partly inefficient systems in the water industry that can benefit from cost reduction and quality indicator improvements through IIoT concepts related to data processing and process adjustments. As the first part of more complex research to obtain a proactive Historian, the current paper wishes to propose a reference architecture and to address the issue of data dependency analyses as part of pattern identification structures. The conceptual approach targets a highly customizable solution considering the variety of industrial processes, but it also underlines basic software modules as generally applicable for the same reason. To prove the efficiency of the obtained solution in the context of real industrial processes, and their corresponding monitoring and control solutions, the paper presents a test scenario in the water industry.
Highlights
The current transition towards the Industrial Internet of Things (IIoT) paradigm is stimulated by the benefits that lie ahead such as cost reduction and increases in safety, productivity, and availability
The current paper proposes a reference architecture for a proactive Historian that consists of a multilevel algorithm hierarchy
The developed algorithm was applied in the water industry integrated in the previously developed
Summary
The water industry is represented by highly heterogeneous and geographically dispersed processes and technical solutions These include legacy systems and new structures that are in stringent need of connecting the digital and the physical worlds in the context of highly functional process dependencies without interoperation. The current transition towards the IIoT paradigm is stimulated by the benefits that lie ahead such as cost reduction and increases in safety, productivity, and availability This transition is revealing a series of problems for the water industry. Under the IIoT paradigm, the fog computing concept is emerging and becoming more significant in industry This new term defines solutions that are placed closer to local automation and, are much more accessible and reliable
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