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SICS Software-Intensive Cyber-Physical Systems

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30-08-2017 | Special Issue Paper

A comprehensive modelling framework for demand side flexibility in smart grids

Authors: Lukas Barth, Nicole Ludwig, Esther Mengelkamp, Philipp Staudt

Published in: SICS Software-Intensive Cyber-Physical Systems | Issue 1-2/2018

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Abstract

The increasing share of renewable energy generation in the electricity system comes with significant challenges, such as the volatility of renewable energy sources. To tackle those challenges, demand side management is a frequently mentioned remedy. However, measures of demand side management need a high level of flexibility to be successful. Although extensive research exists that describes, models and optimises various processes with flexible electrical demands, there is no unified notation. Additionally, most descriptions are very process-specific and cannot be generalised. In this paper, we develop a comprehensive modelling framework to mathematically describe demand side flexibility in smart grids while integrating a majority of constraints from different existing models. We provide a universally applicable modelling framework for demand side flexibility and evaluate its practicality by looking at how well Mixed-Integer Linear Program solvers are able to optimise the resulting models, if applied to artificially generated instances. From the evaluation, we derive that our model improves the performance of previous models while integrating additional flexibility characteristics.

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Title: A comprehensive modelling framework for demand side flexibility in smart grids
Authors: Lukas Barth
Nicole Ludwig
Esther Mengelkamp
Philipp Staudt
Publication date: 30-08-2017
Publisher: Springer Berlin Heidelberg
Published in: SICS Software-Intensive Cyber-Physical Systems / Issue 1-2/2018
Print ISSN: 2524-8510
Electronic ISSN: 2524-8529
DOI: https://doi.org/10.1007/s00450-017-0343-x

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