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Seitz, Gabriele

Gabriele Seitz

Dr. -Ing.

Departure in June 2021
Institute for Modelling Hydraulic and Environmental Systems
Department of Hydromechanics and Modelling of Hydrosystems

Contact

Business card (VCF)

Germany

Vita

Abitur

June 2008, Ursberg (Germany)

Academic Degrees

September 2012: B.Sc. in Environmental Engineering, University of Stuttgart

December 2014: M.Sc. in Environmental Engineering, University of Stuttgart

Academic Career

since March 2015: Scientific Assistant (doctoral student), Department of Hydromechanics and Modelling of Hydrosystems, University of Stuttgart

publications

(Journal-) Articles
1. Koch, T., Gläser, D., Weishaupt, K., Ackermann, S., Beck, M., Becker, B., Burbulla, S., Class, H., Coltman, E., Emmert, S., Fetzer, T., Grüninger, C., Heck, K., Hommel, J., Kurz, T., Lipp, M., Mohammadi, F., Scherrer, S., Schneider, M., et al. (2021). DuMux 3 – an open-source simulator for solving flow and transport problems in porous media with a focus on model coupling. Computers & Mathematics with Applications. https://doi.org/10.1016/j.camwa.2020.02.012
  Abstract
  We present version 3 of the open-source simulator for flow and transport processes in porous media DuMux. DuMux is based on the modular C++ framework Dune (Distributed and Unified Numerics Environment) and is developed as a research code with a focus on modularity and reusability. We describe recent efforts in improving the transparency and efficiency of the development process and community-building, as well as efforts towards quality assurance and reproducible research. In addition to a major redesign of many simulation components in order to facilitate setting up complex simulations in DuMux, version 3 introduces a more consistent abstraction of finite volume schemes. Finally, the new framework for multi-domain simulations is described, and three numerical examples demonstrate its flexibility.
  BibTeX
  @article{Version3Dumux, abstract = {We present version 3 of the open-source simulator for flow and transport processes in porous media DuMux. DuMux is based on the modular C++ framework Dune (Distributed and Unified Numerics Environment) and is developed as a research code with a focus on modularity and reusability. We describe recent efforts in improving the transparency and efficiency of the development process and community-building, as well as efforts towards quality assurance and reproducible research. In addition to a major redesign of many simulation components in order to facilitate setting up complex simulations in DuMux, version 3 introduces a more consistent abstraction of finite volume schemes. Finally, the new framework for multi-domain simulations is described, and three numerical examples demonstrate its flexibility.}, author = {Koch, Timo and Gl\"{a}ser, Dennis and Weishaupt, Kilian and Ackermann, Sina and Beck, Martin and Becker, Beatrix and Burbulla, Samuel and Class, Holger and Coltman, Edward and Emmert, Simon and Fetzer, Thomas and Gr\"{u}ninger, Christoph and Heck, Katharina and Hommel, Johannes and Kurz, Theresa and Lipp, Melanie and Mohammadi, Farid and Scherrer, Samuel and Schneider, Martin and Seitz, Gabriele and Stadler, Leopold and Utz, Martin and Weinhardt, Felix and Flemisch, Bernd}, doi = {10.1016/j.camwa.2020.02.012}, issn = {0898-1221}, journal = {Computers {\&} Mathematics with Applications}, month = {01}, publisher = {Elsevier {BV}}, title = {{DuMux} 3 {\textendash} an open-source simulator for solving flow and transport problems in porous media with a focus on model coupling}, url = {https://doi.org/10.1016/j.camwa.2020.02.012}, year = 2021 }
  Link
  https://doi.org/10.1016/j.camwa.2020.02.012
2. Seitz, G., Mohammadi, F., & Class, H. (2021). Thermochemical Heat Storage in a Lab-Scale Indirectly Operated CaO/Ca(OH)2 Reactor - Numerical Modeling and Model Validation through Inverse Parameter Estimation. Applied Sciences, 11, Article 2. https://doi.org/10.3390/app11020682
  Abstract
  Calcium oxide/Calcium hydroxide can be utilized as a reaction system for thermochemical heat storage. It features a high storage capacity, is cheap, and does not involve major environmental concerns. Operationally, different fixed-bed reactor concepts can be distinguished; direct reactor are characterized by gas flow through the reactive bulk material, while in indirect reactors, the heat-carrying gas flow is separated from the bulk material. This study puts a focus on the indirectly operated fixed-bed reactor setup. The fluxes of the reaction fluid and the heat-carrying flow are decoupled in order to overcome limitations due to heat conduction in the reactive bulk material. The fixed bed represents a porous medium where Darcy-type flow conditions can be assumed. Here, a numerical model for such a reactor concept is presented, which has been implemented in the software DuMux. An attempt to calibrate and validate it with experimental results from the literature is discussed in detail. This allows for the identification of a deficient insulation of the experimental setup. Accordingly, heat-loss mechanisms are included in the model. However, it can be shown that heat losses alone are not sufficient to explain the experimental results. It is evident that another effect plays a role here. Using Bayesian inference, this effect is identified as the reaction rate decreasing with progressing conversion of reactive material. The calibrated model reveals that more heat is lost over the reactor surface than transported in the heat transfer channel, which causes a considerable speed-up of the discharge reaction. An observed deceleration of the reaction rate at progressed conversion is attributed to the presence of agglomerates of the bulk material in the fixed bed. This retardation is represented phenomenologically by mofifying the reaction kinetics. After the calibration, the model is validated with a second set of experimental results. To speed up the calculations for the calibration, the numerical model is replaced by a surrogate model based on Polynomial Chaos Expansion and Principal Component Analysis.
  BibTeX
  @article{Seitz2021-01, abstract = {Calcium oxide/Calcium hydroxide can be utilized as a reaction system for thermochemical heat storage. It features a high storage capacity, is cheap, and does not involve major environmental concerns. Operationally, different fixed-bed reactor concepts can be distinguished; direct reactor are characterized by gas flow through the reactive bulk material, while in indirect reactors, the heat-carrying gas flow is separated from the bulk material. This study puts a focus on the indirectly operated fixed-bed reactor setup. The fluxes of the reaction fluid and the heat-carrying flow are decoupled in order to overcome limitations due to heat conduction in the reactive bulk material. The fixed bed represents a porous medium where Darcy-type flow conditions can be assumed. Here, a numerical model for such a reactor concept is presented, which has been implemented in the software DuMux. An attempt to calibrate and validate it with experimental results from the literature is discussed in detail. This allows for the identification of a deficient insulation of the experimental setup. Accordingly, heat-loss mechanisms are included in the model. However, it can be shown that heat losses alone are not sufficient to explain the experimental results. It is evident that another effect plays a role here. Using Bayesian inference, this effect is identified as the reaction rate decreasing with progressing conversion of reactive material. The calibrated model reveals that more heat is lost over the reactor surface than transported in the heat transfer channel, which causes a considerable speed-up of the discharge reaction. An observed deceleration of the reaction rate at progressed conversion is attributed to the presence of agglomerates of the bulk material in the fixed bed. This retardation is represented phenomenologically by mofifying the reaction kinetics. After the calibration, the model is validated with a second set of experimental results. To speed up the calculations for the calibration, the numerical model is replaced by a surrogate model based on Polynomial Chaos Expansion and Principal Component Analysis.}, article-number = {682}, author = {Seitz, Gabriele and Mohammadi, Farid and Class, Holger}, doi = {10.3390/app11020682}, issn = {2076-3417}, journal = {Applied Sciences}, month = {01}, number = 2, pages = 682, publisher = {MDPI AG}, title = {Thermochemical Heat Storage in a Lab-Scale Indirectly Operated CaO/Ca(OH)2 Reactor - Numerical Modeling and Model Validation through Inverse Parameter Estimation}, url = {https://www.mdpi.com/2076-3417/11/2/682}, volume = 11, year = 2021 }
  Link
  https://www.mdpi.com/2076-3417/11/2/682
3. Seitz, G., Helmig, R., & Class, H. (2020). A numerical modeling study on the influence of porosity changes during thermochemical heat storage. Applied Energy, 259, 114152. https://doi.org/10.1016/j.apenergy.2019.114152
  - BibTeX
  - Link
  BibTeX
  @article{Seitz-Seitz-2020-01, author = {Seitz, Gabriele and Helmig, Rainer and Class, Holger}, doi = {10.1016/j.apenergy.2019.114152}, issn = {0306-2619}, journal = {Applied Energy}, month = {02}, pages = 114152, title = {A numerical modeling study on the influence of porosity changes during thermochemical heat storage}, url = {http://www.sciencedirect.com/science/article/pii/S0306261919318392}, volume = 259, year = 2020 }
  Link
  http://www.sciencedirect.com/science/article/pii/S0306261919318392
4. Koch, T., Gläser, D., Weishaupt, K., Ackermann, S., Beck, M., Becker, B., Burbulla, S., Class, H., Coltman, E., Fetzer, T., Flemisch, B., Grüninger, C., Heck, K., Hommel, J., Kurz, T., Lipp, M., Mohammadi, F., Schneider, M., Seitz, G., et al. (2018). DuMuX 3.0.0. https://doi.org/10.5281/zenodo.2479595
  - BibTeX
  BibTeX
  @article{koch2018dumux, author = {Koch, Timo and Gläser, Dennis and Weishaupt, Kilian and Ackermann, Sina and Beck, Martin and Becker, Beatrix and Burbulla, S. and Class, Holger and Coltman, Edward and Fetzer, Thomas and Flemisch, Bernd and Grüninger, Christoph and Heck, Katharina and Hommel, Johannes and Kurz, Theresa and Lipp, Melanie and Mohammadi, Farid and Schneider, Martin and Seitz, Gabriele and Scholz, Simon and Weinhardt, Felix}, doi = {10.5281/zenodo.2479595}, title = {DuMuX 3.0.0}, year = 2018 }
5. Beck, M., Seitz, G., & Class, H. (2016). Volume-Based Modelling of Fault Reactivation in Porous Media Using a Visco-Elastic Proxy Model. Transport in Porous Media.
  - BibTeX
  BibTeX
  @article{NULL, author = {Beck, Martin and Seitz, Gabriele and Class, Holger}, journal = {Transport in Porous Media}, month = {03}, note = {, IWS2ID=4366 }, page = {DOI10.1007/s11}, title = {Volume-Based Modelling of Fault Reactivation in Porous Media Using a Visco-Elastic Proxy Model}, year = 2016 }
Theses
1. Seitz, G. (2014). A conceptional approach to the effect of shear failure on the stress field in porous media [Masterthesis].
  - BibTeX
  BibTeX
  @mastersthesis{NULL, author = {Seitz, Gabriele}, month = {12}, note = {, IWS2ID=3051 , Institution: Institut für Wasser- und Umweltsystemmodellierung , Address: Universität Stuttgart }, school = {Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung}, title = {A conceptional approach to the effect of shear failure on the stress field in porous media}, type = {Masterthesis}, year = 2014 }
2. Seitz, G. (2011). Vereinfachte Methoden zur Flutwellenabschätzung [Bachelorarbeit].
  - BibTeX
  BibTeX
  @mastersthesis{NULL, author = {Seitz, Gabriele}, month = {10}, note = {, IWS2ID=2674 , Institution: Institut für Wasserbau , Address: Universität Stuttgart , Partnerinstitution: Landesamt Böblingen, Wasserwirtschaftsamt , Partneraddress: Böblingen }, school = {Universität Stuttgart, Institut für Wasserbau}, title = {Vereinfachte Methoden zur Flutwellenabschätzung}, type = {Bachelorarbeit}, year = 2011 }
PhDs
1. Seitz, G. (2021). Modeling fixed-bed reactors for thermochemical heat storage with the reaction system CaO/Ca(OH)2 (Dissertation No. 278, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung). https://doi.org/10.18419/opus-11522
  - BibTeX
  - Link
  BibTeX
  @phdthesis{lh2-diss-2021-seitz, address = {Stuttgart}, author = {Seitz, Gabriele}, doi = {10.18419/opus-11522}, eventdate = {2021-02-24}, isbn = {978-3-942036-82-5}, language = {eng}, month = {02}, number = 278, publisher = {Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung}, school = {Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung}, series = {Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart}, supervisor = {Class, Holger}, title = {Modeling fixed-bed reactors for thermochemical heat storage with the reaction system CaO/Ca(OH)2}, type = {Dissertation}, url = {http://dx.doi.org/10.18419/opus-11522}, year = 2021 }
  Link
  http://dx.doi.org/10.18419/opus-11522

posters

2019
1. G. Seitz, R. Helmig, and H. Class, “Model Coupling in thermochemical Heat Storage,” InterPore 2019. May 2019. [Online]. Available: https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2019/2019_SeitzG_Interpore_Poster.pdf
  - BibTeX
  - Link
  BibTeX
  @misc{seitz2019interpore, author = {Seitz, Gabriele and Helmig, Rainer and Class, Holger}, booktitle = {InterPore 2019}, month = {05}, title = {Model Coupling in thermochemical Heat Storage}, type = {Poster Session}, url = {https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2019/2019_SeitzG_Interpore_Poster.pdf}, year = 2019 }
  Link
  https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2019/2019_SeitzG_Interpore_Poster.pdf
2017
1. G. Seitz, R. Helmig, and H. Class, “Numerical Model of a Ca(OH)2 / CaO thermochemical heat storage reactor,” 9th International Conference on Porous Media & Annual Meeting - InterPore 2017, 08.05.2017 - 11.05.2017, Rotterdam, The Netherlands. May 2017. [Online]. Available: https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2017/Seitz_IWS_Interpore2017.pdf
  - BibTeX
  - Link
  BibTeX
  @misc{NULL, author = {Seitz, Gabriele and Helmig, Rainer and Class, Holger}, booktitle = {9th International Conference on Porous Media & Annual Meeting - InterPore 2017, 08.05.2017 - 11.05.2017, Rotterdam, The Netherlands}, month = {05}, note = {, IWS2ID=4459 }, title = {Numerical Model of a Ca(OH)2 / CaO thermochemical heat storage reactor}, type = {Poster}, url = {https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2017/Seitz_IWS_Interpore2017.pdf}, year = 2017 }
  Link
  https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2017/Seitz_IWS_Interpore2017.pdf
2015
1. M. Beck, G. Seitz, H. Class, and R. Helmig, “A new phenomenological approach to modelling of shear failure in porous media,” NUPUS annual meeting 2015 , 08.09.2015 - 12.09.2015, Freudenstadt. Sep. 2015. [Online]. Available: https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2015/NupusPoster_Beck_2015.pdf
  - BibTeX
  - Link
  BibTeX
  @misc{NULL, author = {Beck, Martin and Seitz, Gabriele and Class, Holger and Helmig, Rainer}, booktitle = {NUPUS annual meeting 2015 , 08.09.2015 - 12.09.2015, Freudenstadt}, month = {09}, note = {, date=09.09.2015, IWS2ID=3109 }, title = {A new phenomenological approach to modelling of shear failure in porous media}, type = {Poster}, url = {https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2015/NupusPoster_Beck_2015.pdf}, year = 2015 }
  Link
  https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2015/NupusPoster_Beck_2015.pdf

supervised student assignements

Untersuchung von Rissstrukturen bei der thermochemischen Wärmespeicherung mit CaO/Ca(OH)2. (2020). (Bachelorarbeit).
Entwicklung eines Stoffmodells für Wasserstoff unter überkritischen Bedingungen zur Analyse von Wasserstoffspeicherung im Untergrund. (2020). (Bachalorarbeit).
Untersuchung des lokalen thermischen Nicht-Gleichgewichts bei der thermochemischen Wärmespeicherung. (2020). (Projektarbeit). Universität Stuttgart.
Pumpversuche zur Bestimmung hydrogeologischer Parameter. (2018). (Bachelorarbeit).
Modeling fractures in a CaO/Ca(OH)2 thermo-chemical heat storage reactor. (2018). (Masterthesis).
Investigating turbulence in an indirect thermo-chemical heat storage reactor. (2018). (Bachelorarbeit).
Modeling heat transfer between porous medium and free flow. (2018). (Projektarbeit).
Auslegung einer Gebäudeheizung mit einem thermochemischen Wärmespeicher. (2017). (Bachelorarbeit).
Modellierung und experimentelle Untersuchung des Stoffsystems SrBr2/H2O zur thermochemischen Energiespeicherung. (2017). (Masterthesis).
Untersuchungen zu Möglichkeiten der Wärmespeicherung bei der adiabaten Druckluftspeicherung. (2015). (Bachelorarbeit).

Research projects

Completed research projects

DISS: Data-Integrated Simulation Science

Gabriele Seitz

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Vita

publications

(Journal-) Articles

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Abstract

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Theses

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PhDs

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posters

2019

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2017

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2015

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supervised student assignements

Research projects

Completed research projects

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Gabriele Seitz

Contact

Vita

publications

(Journal-) Articles

Abstract

BibTeX

Link

Abstract

BibTeX

Link

BibTeX

Link

BibTeX

BibTeX

Theses

BibTeX

BibTeX

PhDs

BibTeX

Link

posters

2019

BibTeX

Link

2017

BibTeX

Link

2015

BibTeX

Link

supervised student assignements

Research projects

Completed research projects

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