Framework for Automated Data-Driven Model Adaption for the Application in Industrial Energy Systems

Leopold Prendl,Rene Hofmann,Lukas Kasper,Markus Holzegger

doi:10.1109/access.2021.3104058

Leopold Prendl, Rene Hofmann + Show 2 more

Open Access

https://doi.org/10.1109/access.2021.3104058

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Abstract

Increasing flexibility and efficiency of energy-intensive industrial processes is generally seen as a big lever towards a decarbonized energy system of the future. However, to leverage these potentials, the accurate prediction of unit behavior is essential to be able to close the gap between supply and demand. Not only pose nonlinear relations a serious challenge in thermal systems engineering and optimization but real-world unit behavior furthermore changes during operation due to wear, fouling and other effects. In the present work, a novel framework for automated data-driven model adaption is presented which is capable of automating fast and accurate predictions of current system behavior. The framework is based on open protocol bidirectional live communication and mechanistic grey box modeling. While especially thermal energy storage is considered a solution to increase flexibility, it is very challenging for operation optimization. A packed bed thermal energy storage operated under severe conditions leading to continuous fouling acts as proof of concept of the proposed framework. The obtained results indicate major improvement for storage output prediction with the novel framework compared to a conventional approach without readjustment. Furthermore, the presented framework is perfectly suitable and an essential foundation for live condition monitoring, fault prediction, predictive maintenance, and operation optimization.

Highlights

This Introduction presents a short motivation for the present work and a brief history and summary of related work that can be found in current literature, followed by highlighting the main contributions and the remaining structure of this paper.A
The charging temperatures vary between 170 ◦C and 260 ◦C whereas the discharging temperature is constant at a 22 ◦C ambient temperature
For the simulation of pollution or fouling, it is assumed that the given load cycle is repeated in a cyclical manner while the heat transfer coefficient between heat transfer fluid (HTF) and storage medium (SM) is gradually decreasing over time

Summary

Introduction

A. MOTIVATION Decarbonization efforts are a driving force for the energyintensive industries to drastically increase energy efficiency. Leopold Prendl et al.: Framework for automated data-driven model adaption for the application in industrial energy systems try4.0, driven by evolving Information and Communication Technologies [1]. Most researchers agree on the huge potential of digitalization for reducing energy consumption and for increasing economic sustainability [4]–[7]. As another paradigm of Industry4.0, Predictive Maintenance, achieved by real-time monitoring, can positively affect the environment [3]. Preventive and predictive maintenance promoted by data analytics extends the lifespan of machinery, minimizing end of life waste [8]

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