Energy storage systems have a central role in future energy systems. In the context of the energy transition, there are various changes and challenges in the energy sector - the elimination of conventional generators, the digitization, and decentralization of the electricity supply, as well as an increasing sector coupling of electricity to the heat and mobility sector are just selected examples. In various applications, stationary storage systems can contribute to the energy transition, operate profitably and - if used correctly - make a contribution to reducing CO2 emissions.
The SES team aims to investigate fundamental issues relating to system design, optimal operation, efficiency, and the degradation of storage systems as a whole - i.e. including the associated peripherals. The findings flow directly into technical and economic evaluations. It is our concern to make the most comprehensive simulation and optimization tool landscape available to the general public in the form of open-source code.
Further details can be found on the following pages:
Electric vehicle multi-use: Optimizing multiple value streams using mobile storage systems in a vehicle-to-grid context. S. Englberger, K. Abo Gamra, B. Tepe, M. Schreiber, A. Jossen, H. Hesse. Applied Energy 304, 2021.
Evaluating the interdependency between peer-to-peer networks and energy storages: A techno-economic proof for prosumers. S. Englberger, A. Chapman, W. Tushar, T. Almomani, S. Snow, R. Witzmann, A. Jossen, H. Hesse. Advances in Applied Energy 3, 2021.
The carbon footprint of island grids with lithium-ion battery systems: An analysis based on levelized emissions of energy supply. A. Parlikar, C.N. Truong, A. Jossen, H. Hesse. Renewable and Sustainable Energy Reviews 149, 2021.
Reducing grid peak load through the coordinated control of battery energy storage systems located at electric vehicle charging parks. D. Kucevic, S. Englberger, A. Sharma, A. Trivedi, B. Tepe, B. Schachler, H. Hesse, D. Srinivasan, A. Jossen. Applied Energy 295, 2021.
Stationary Battery Storage in Germany - Current Developments and Trends 2021 (German only) - published in "Energiewirtschaftliche Tagesfragen" B. Tepe, N. Collath, H.Hesse, M. Rosenthal, U.Windelen
Energy Arbitrage Optimization with Battery Storage: 3D-MILP for Electro-thermal Performance and Semi-empirical Aging Models. V. Kumtepeli, H. Hesse, M. Schimpe, A. Tripathi, Y. Wang and A. Jossen. IEEE Access 8, 2020.
Unlocking the Potential of Battery Storage with the Dynamic Stacking of Multiple Applications. S. Englberger, A. Jossen, H. Hesse. Cell Reports Physical Science 1, 2020.
Standard battery energy storage system profiles: Analysis of various applications for stationary energy storage systems using a holistic simulation framework. D. Kucevic, B. Tepe, S. Englberger, A. Parlikar, M. Mühlbauer, O. Bohlen, A. Jossen, H. Hesse. Journal of Energy Storage 28, 2020.
A Techno-Economic Analysis of Vehicle-to-Building: Battery Degradation and Efficiency Analysis in the Context of Coordinated Electric Vehicle Charging. S. Englberger, H. Hesse, D. Kucevic, and A. Jossen. Energies 12 (5), 2019.
Energy efficiency evaluation of a stationary lithium-ion battery container storage system via electro-thermal modeling and detailed component analysis. M. Schimpe, M. Naumann, N. Truong, H. Hesse, S. Santhanagopalan, et al. Applied Energy 210, 211-229, 2018.
|Collath, Nils; M.Sc.||+49 (89) 289 - email@example.com||room 3019|
|Cornejo Vorbeck, Santiago; M.Sc.||+49 (89) 289 - firstname.lastname@example.org||room 3008|
|Englberger, Stefan; M.Sc.||+49 (89) 289 - email@example.com||room 3005|
|Hesse, Holger; Dr. rer. nat.||+49 (89) 289 - firstname.lastname@example.org||room 1013|
|Kucevic, Daniel; M.Sc.||+49 (89) 289 - email@example.com||room 3004|
|Möckl, Maximilian; Dipl.-Ing. (Univ.)||firstname.lastname@example.org|
|Möller, Marc; M.Sc.||+49 (89) 289 - email@example.com||room 3019|
|Parlikar, Anupam; M.Sc.||+49 (89) 289 - firstname.lastname@example.org||room 3005|
|Tepe, Benedikt; M.Sc.||+49 (89) 289 - email@example.com||room 3004|