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Böckmann, M.Sc., Olaf

Olaf Böckmann, M.Sc.

Research associate in SFB1244
Chair of Energy Storage
Research group "Thermal Energy Storage Simulation"

Contact

+49 711 685 62678
Email

Pfaffenwaldring 31
70569 Stuttgart
Germany
Room: 4.424

Subject

Thermal Energy Storage by Adsorption

Publications

2024
1. Li, Q., Boeckmann, O., & Schaefer, M. (2024). Systematic screening and evaluation for an optimal adsorbent in a facade-integrated adsorption-based solar cooling system for high-rise buildings. Energy, 310, 133092. https://doi.org/10.1016/j.energy.2024.133092
  - BibTeX
  - Link
  BibTeX
  @article{Li_2024, author = {Li, Qiwei and Boeckmann, Olaf and Schaefer, Micha}, doi = {10.1016/j.energy.2024.133092}, issn = {0360-5442}, journal = {Energy}, month = {11}, pages = 133092, publisher = {Elsevier BV}, title = {Systematic screening and evaluation for an optimal adsorbent in a facade-integrated adsorption-based solar cooling system for high-rise buildings}, url = {http://dx.doi.org/10.1016/j.energy.2024.133092}, volume = 310, year = 2024 }
  Link
  http://dx.doi.org/10.1016/j.energy.2024.133092
2. Gschweng, M., Heidingsfeld, J. L., Böckmann, O., Schäfer, M., Böhm, M., & Sawodny, O. (2024). Evaporator Temperature Control of a Solar-Powered Adsorption Façade System. 2024 IEEE Conference on Control Technology and Applications (CCTA), 420–425. https://doi.org/10.1109/CCTA60707.2024.10666605
  - BibTeX
  BibTeX
  @inproceedings{10666605, abstract = {Rising global temperatures lead to an increasing cooling demand in residential buildings. Utilizing solar energy for air-conditioning can improve the CO2 balance of cooling systems. An adsorption façade system (AFS) provides cooling through direct use of solar power. The cooling potential is stored by dehydrating the adsorber and realized by connecting an evaporator with the adsorber. While switching between these different operational phases has to be realized using supervisory control, this paper focuses on the subordinate control algorithm to keep the evaporator temperature at the desired value within the cooling phase. Earlier works showed that a two point bang-bang control is not feasible for this application due to physical limitations. Therefore, this paper proposes a design modification in combination with a PI-control law for the cooling phase. This proposed controller respects comfort temperature limits and prevents condensation of air humidity, while achieving maximal cooling rates.}, author = {Gschweng, Melanie and Heidingsfeld, Julia L. and Böckmann, Olaf and Schäfer, Micha and Böhm, Michael and Sawodny, Oliver}, booktitle = {2024 IEEE Conference on Control Technology and Applications (CCTA)}, doi = {10.1109/CCTA60707.2024.10666605}, issn = {2768-0770}, month = {08}, pages = {420-425}, title = {Evaporator Temperature Control of a Solar-Powered Adsorption Façade System}, year = 2024 }
3. Dubies, T., Böckmann, O., & Schäfer, M. (2024). Material Study of a Facade-Integrated Adsorption System for Solar Cooling of Buildings. Proceedings of the International Renewable Energy Storage and Systems Conference (IRES 2023), 151--162. https://doi.org/10.2991/978-94-6463-455-6_16
  - BibTeX
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  BibTeX
  @inproceedings{dubies2024material, author = {Dubies, Tim and Böckmann, Olaf and Schäfer, Micha}, booktitle = {Proceedings of the International Renewable Energy Storage and Systems Conference (IRES 2023)}, doi = {10.2991/978-94-6463-455-6_16}, issn = {25894943}, pages = {151--162}, publisher = {Atlantis Press}, refid = {Dubies2024}, title = {Material Study of a Facade-Integrated Adsorption System for Solar Cooling of Buildings}, url = {https://doi.org/10.2991/978-94-6463-455-6_16}, year = 2024 }
  Link
  https://doi.org/10.2991/978-94-6463-455-6_16
4. Böckmann, O., Borschewski, D., Weber, S., & Schäfer, M. (2024). Simulation-based determination of system size and energy savings for a life cycle assessment of a facade-integrated adsorption system for solar cooling of buildings. Proceedings of BauSim 2024: 10th Conference of IBPSA-Germany and Austria, 10. https://doi.org/10.26868/29761662.2024.41
  - BibTeX
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  BibTeX
  @inproceedings{Boeckmann_2024, author = {Böckmann, Olaf and Borschewski, David and Weber, Simon and Schäfer, Micha}, booktitle = {Proceedings of BauSim 2024: 10th Conference of IBPSA-Germany and Austria}, collection = {BauSim 2024}, doi = {10.26868/29761662.2024.41}, issn = {2976-1662}, month = {09}, publisher = {IBPSA-Germany and Austria}, series = {BauSim 2024}, title = {Simulation-based determination of system size and energy savings for a life cycle assessment of a facade-integrated adsorption system for solar cooling of buildings}, url = {http://dx.doi.org/10.26868/29761662.2024.41}, volume = 10, year = 2024 }
  Link
  http://dx.doi.org/10.26868/29761662.2024.41
5. Boeckmann, O., Marmullaku, D., & Schaefer, M. (2024). Dynamic Modeling and Simulation of a Facade-Integrated Adsorption System for Solar Cooling of Lightweight Buildings. Energies, 17(7), Article 7. https://doi.org/10.3390/en17071706
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  BibTeX
  @article{en17071706, abstract = {Reductions of carbon dioxide emissions from the building sector are mandatory for climate protection. This calls for both a reduction of the construction material and energy as well as a reduction of the operational energy. Against this background, a novel facade-integrated adsorption system for solar cooling of lightweight buildings is proposed and theoretically investigated in this work. For this purpose, a detailed simulation model is developed to analyze both the processes in the single components as well as the overall system behavior. The proposed system consists of the three components adsorber, condenser and evaporator, which are connected vacuum-tight and are coupled by vapor transfer. The simulation results of a defined reference case yield cooling rates of 54 W per installed square meter of adsorber facade. The cooling power can be maintained for 12 h, confirming the applicability of the proposed system. Furthermore, a comprehensive parametric study is carried out in order to identify an optimum set of parameter values for maximum cooling rate under the assumed conditions. The results reveal that controlled constant cooling rates of 105 W per square meter of adsorber facade can be reached and a maximum peak power of 145 W per square meter of adsorber facade is possible.}, article-number = {1706}, author = {Boeckmann, Olaf and Marmullaku, Drin and Schaefer, Micha}, doi = {10.3390/en17071706}, issn = {1996-1073}, journal = {Energies}, number = 7, title = {Dynamic Modeling and Simulation of a Facade-Integrated Adsorption System for Solar Cooling of Lightweight Buildings}, url = {https://www.mdpi.com/1996-1073/17/7/1706}, volume = 17, year = 2024 }
  Link
  https://www.mdpi.com/1996-1073/17/7/1706
2022
1. Weber, S. O., Böckmann, O., Greiner, A., Park, S., & Schäfer, M. (2022). Optimal Conceptual Design of a Novel Façade-Integrated Adsorption Cooling System. Proceedings of EuroSun 2022 - ISES and IEA SHC International Conference on Solar Energy for Buildings and Industry. https://doi.org/10.18086/eurosun.2022.06.11
  - BibTeX
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  BibTeX
  @inproceedings{Weber_2022, author = {Weber, Simon O. and Böckmann, Olaf and Greiner, Andreas and Park, Sumee and Schäfer, Micha}, booktitle = {Proceedings of EuroSun 2022 - ISES and IEA SHC International Conference on Solar Energy for Buildings and Industry}, collection = {EuroSun 2022}, doi = {10.18086/eurosun.2022.06.11}, publisher = {International Solar Energy Society}, series = {EuroSun 2022}, title = {Optimal Conceptual Design of a Novel Façade-Integrated Adsorption Cooling System}, url = {http://dx.doi.org/10.18086/eurosun.2022.06.11}, year = 2022 }
  Link
  http://dx.doi.org/10.18086/eurosun.2022.06.11
2. Heidingsfeld, J. L., Böckmann, O., Schäfer, M., Böhm, M., & Sawodny, O. (2022). Low Order Hybrid Model for Control Design of an Adsorption Facade System for Solar Cooling. 2022 IEEE Conference on Control Technology and Applications (CCTA), 425–432. https://doi.org/10.1109/CCTA49430.2022.9965991
  - BibTeX
  BibTeX
  @inproceedings{9965991, abstract = {The building sector is responsible for a large share of the world's resource and energy consumption. A lot of energy is spend to climatize buildings, thus leading to high associated CO2 emissions. As a climate friendly solution, a solar driven facade-integrated system based on adsorption can be used to sustainably cool the interior. A hybrid model based on mass and energy balances is introduced, which describes the working phases of the adsorption facade system and the dynamics in each phase. The system runs in a daily cycle that starts with a regeneration phase in which solar radiation is used to charge the system for the cooling phase. Numerical simulations are conducted to analyze the behavior of the controlled system and give an outlook on control requirements for design and construction of the adsorption facade system.}, author = {Heidingsfeld, Julia L. and Böckmann, Olaf and Schäfer, Micha and Böhm, Michael and Sawodny, Oliver}, booktitle = {2022 IEEE Conference on Control Technology and Applications (CCTA)}, doi = {10.1109/CCTA49430.2022.9965991}, issn = {2768-0770}, month = {08}, pages = {425-432}, title = {Low Order Hybrid Model for Control Design of an Adsorption Facade System for Solar Cooling}, year = 2022 }
3. Greiner, A., Böckmann, O., Weber, S., Ostermann, M., & Schaefer, M. (2022). CoolSkin: A Novel Façade Design for Sustainable Solar Cooling by Adsorption. Journal of Facade Design and Engineering, 10(2), Article 2. https://doi.org/10.47982/jfde.2022.powerskin.3
  - BibTeX
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  BibTeX
  @article{Greiner_2022, author = {Greiner, Andreas and Böckmann, Olaf and Weber, Simon and Ostermann, Martin and Schaefer, Micha}, doi = {10.47982/jfde.2022.powerskin.3}, issn = {2213-302X}, journal = {Journal of Facade Design and Engineering}, month = {12}, number = 2, pages = {39–56}, publisher = {Stichting OpenAccess Foundation}, title = {CoolSkin: A Novel Façade Design for Sustainable Solar Cooling by Adsorption}, url = {http://dx.doi.org/10.47982/jfde.2022.powerskin.3}, volume = 10, year = 2022 }
  Link
  http://dx.doi.org/10.47982/jfde.2022.powerskin.3
2021
1. Schäfer, M., Marmullaku, D., & Böckmann, O. (2021). Facade-integrated adsorption system for solar cooling of lightweight buildings. 13th International Conference on Computational Heat Mass and Momentum Transfer, Paris.
  - BibTeX
  BibTeX
  @presentation{schafer2021facadeintegrated, author = {Schäfer, Micha and Marmullaku, Drin and Böckmann, Olaf}, eventtitle = {13th International Conference on Computational Heat Mass and Momentum Transfer}, title = {Facade-integrated adsorption system for solar cooling of lightweight buildings}, venue = {Paris}, year = 2021 }
2. Böckmann, O., & Schäfer, M. (2021). Modellierung und Simulation eines fassadenintegrierten Adsorptionssystems zur solaren Gebäudekühlung. DECHEMA Thermodynamik Kolloquium, Chemnitz.
  - BibTeX
  BibTeX
  @presentation{bockmann2021modellierung, author = {Böckmann, Olaf and Schäfer, Micha}, eventdate = {2021}, eventtitle = {DECHEMA Thermodynamik Kolloquium}, title = {Modellierung und Simulation eines fassadenintegrierten Adsorptionssystems zur solaren Gebäudekühlung}, venue = {Chemnitz}, year = 2021 }

Olaf Böckmann, M.Sc.

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2024

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Olaf Böckmann, M.Sc.

Contact

Subject

Publications

2024

BibTeX

Link

BibTeX

BibTeX

Link

BibTeX

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2022

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2021

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