Towards Port-Hamiltonian Modeling of Multi-Carrier Energy Systems: A Case Study for a Coupled Electricity and Gas Distribution System

Authors

Felix Strehle, Martin Pfeifer, Lukas Kölsch, Charlotte Degünther, Johannes Ruf, Lisa Andresen, Sören Hohmann

Abstract

Multi-carrier energy systems have been identified as a major concept for future energy supply. For their operation, model-based control methods are necessary whose design requires modular, multi-physical control-oriented models. In literature, there exists no control design model which combines the variables of the networks and system dynamics that go beyond ideal storage elements. Port-Hamiltonian systems represent a promising approach for the scalable modeling and control of multi-carrier energy systems. In this publication we present a case study which illustrates the port-Hamiltonian modeling of an exemplary coupled electricity and gas distribution system. Simulations indicate the plausibility of the presented model.

Keywords

Modeling; Multi-Carrier Energy Systems; Port-Hamiltonian Systems; Bond Graphs

Citation

Journal: IFAC-PapersOnLine
Year: 2018
Volume: 51
Issue: 2
Pages: 463–468
Publisher: Elsevier BV
DOI: 10.1016/j.ifacol.2018.03.078
Note: 9th Vienna International Conference on Mathematical Modelling

BibTeX

@article{Strehle_2018,
  title={{Towards Port-Hamiltonian Modeling of Multi-Carrier Energy Systems: A Case Study for a Coupled Electricity and Gas Distribution System}},
  volume={51},
  ISSN={2405-8963},
  DOI={10.1016/j.ifacol.2018.03.078},
  number={2},
  journal={IFAC-PapersOnLine},
  publisher={Elsevier BV},
  author={Strehle, Felix and Pfeifer, Martin and Kölsch, Lukas and Degünther, Charlotte and Ruf, Johannes and Andresen, Lisa and Hohmann, Sören},
  year={2018},
  pages={463--468}
}

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