Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability
The intermittent energy supply from distributed resources and the coupling of different energy and application sectors play an important role for future energy systems. Novel operational concepts require the use of widespread and reliable Information and Communication Technology (ICT). This paper pr...
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MDPI AG
2021
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oai:doaj.org-article:98168e6b5f304114816b38ef547cf0a42021-11-25T17:58:48ZHolistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability10.3390/infrastructures61101502412-3811https://doaj.org/article/98168e6b5f304114816b38ef547cf0a42021-10-01T00:00:00Zhttps://www.mdpi.com/2412-3811/6/11/150https://doaj.org/toc/2412-3811The intermittent energy supply from distributed resources and the coupling of different energy and application sectors play an important role for future energy systems. Novel operational concepts require the use of widespread and reliable Information and Communication Technology (ICT). This paper presents the approach of a research project that focuses on the development of an innovative operational concept for a Smart Integrated Energy System (SIES), which consists of a physical architecture, ICT and energy management strategies. The cellular approach provides the architecture of the physical system in combination with Transactive Control (TC) as the system’s energy management framework. Independent dynamic models for each component, the physical and digital system, operational management and market are suggested and combined in a newly introduced co-simulation platform to create a holistic model of the integrated energy system. To verify the effectiveness of the operational concept, energy system scenarios are derived and evaluation criteria are suggested which can be employed to evaluate the future system operations.Kai HothTom SteffenBéla WiegelAmine YoussfiDavood BabazadehMarcus VenzkeChristian BeckerKathrin FischerVolker TurauMDPI AGarticlecyber physical energy systemcellular approachtransactive controlsmart integrated operationdynamic modelingco-simulationTechnologyTENInfrastructures, Vol 6, Iss 150, p 150 (2021) |
| institution |
DOAJ |
| collection |
DOAJ |
| language |
EN |
| topic |
cyber physical energy system cellular approach transactive control smart integrated operation dynamic modeling co-simulation Technology T |
| spellingShingle |
cyber physical energy system cellular approach transactive control smart integrated operation dynamic modeling co-simulation Technology T Kai Hoth Tom Steffen Béla Wiegel Amine Youssfi Davood Babazadeh Marcus Venzke Christian Becker Kathrin Fischer Volker Turau Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| description |
The intermittent energy supply from distributed resources and the coupling of different energy and application sectors play an important role for future energy systems. Novel operational concepts require the use of widespread and reliable Information and Communication Technology (ICT). This paper presents the approach of a research project that focuses on the development of an innovative operational concept for a Smart Integrated Energy System (SIES), which consists of a physical architecture, ICT and energy management strategies. The cellular approach provides the architecture of the physical system in combination with Transactive Control (TC) as the system’s energy management framework. Independent dynamic models for each component, the physical and digital system, operational management and market are suggested and combined in a newly introduced co-simulation platform to create a holistic model of the integrated energy system. To verify the effectiveness of the operational concept, energy system scenarios are derived and evaluation criteria are suggested which can be employed to evaluate the future system operations. |
| format |
article |
| author |
Kai Hoth Tom Steffen Béla Wiegel Amine Youssfi Davood Babazadeh Marcus Venzke Christian Becker Kathrin Fischer Volker Turau |
| author_facet |
Kai Hoth Tom Steffen Béla Wiegel Amine Youssfi Davood Babazadeh Marcus Venzke Christian Becker Kathrin Fischer Volker Turau |
| author_sort |
Kai Hoth |
| title |
Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| title_short |
Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| title_full |
Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| title_fullStr |
Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| title_full_unstemmed |
Holistic Simulation Approach for Optimal Operation of Smart Integrated Energy Systems under Consideration of Resilience, Economics and Sustainability |
| title_sort |
holistic simulation approach for optimal operation of smart integrated energy systems under consideration of resilience, economics and sustainability |
| publisher |
MDPI AG |
| publishDate |
2021 |
| url |
https://doaj.org/article/98168e6b5f304114816b38ef547cf0a4 |
| work_keys_str_mv |
AT kaihoth holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT tomsteffen holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT belawiegel holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT amineyoussfi holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT davoodbabazadeh holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT marcusvenzke holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT christianbecker holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT kathrinfischer holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability AT volkerturau holisticsimulationapproachforoptimaloperationofsmartintegratedenergysystemsunderconsiderationofresilienceeconomicsandsustainability |
| _version_ |
1718411761093181440 |