Article | Proceedings of the 8th International Modelica Conference; March 20th-22nd; Technical Univeristy; Dresden; Germany | Modelling of a Chemical Reactor for Simulation of a Methanisation Plant Linköping University Electronic Press Conference Proceedings
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Title:
Modelling of a Chemical Reactor for Simulation of a Methanisation Plant
Author:
A. Bader: Technische Universität Bergakademie Freiberg, Department of Energy Process Engineering and Chemical Engineering, Germany S. Bauersfeld: Technische Universität Bergakademie Freiberg, Department of Energy Process Engineering and Chemical Engineering, Germany C. Brunhuber: Siemens AG, Energy Solutions, Germany R. Pardemann: Technische Universität Bergakademie Freiberg, Department of Energy Process Engineering and Chemical Engineering, Germany B. Meyer: Technische Universität Bergakademie Freiberg, Department of Energy Process Engineering and Chemical Engineering, Germany
DOI:
10.3384/ecp11063572
Download:
Full text (pdf)
Year:
2011
Conference:
Proceedings of the 8th International Modelica Conference; March 20th-22nd; Technical Univeristy; Dresden; Germany
Issue:
063
Article no.:
064
Pages:
572-578
No. of pages:
7
Publication type:
Abstract and Fulltext
Published:
2011-06-30
ISBN:
978-91-7393-096-3
Series:
Linköping Electronic Conference Proceedings
ISSN (print):
1650-3686
ISSN (online):
1650-3740
Publisher:
Linköping University Electronic Press; Linköpings universitet


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The chemical and physical modelling and transient simulation of a plant with chemical reactors can be useful within dimensioning; optimisation; operation studies and analysing of time critical processes. Therefore; a reactor model for thermodynamic equilibrium conditions has been implemented. The Model is based on the free Modelica Fluid library and contains correlations for heat and mass transfer and pressure drop. The model contains the components: H2; CO; CO2; H2O; CH4; N2

Keywords: chemical reactor; thermodynamic equilibrium; part load; CO2; CO; H2; CH4; H2O

Proceedings of the 8th International Modelica Conference; March 20th-22nd; Technical Univeristy; Dresden; Germany

Author:
A. Bader, S. Bauersfeld, C. Brunhuber, R. Pardemann, B. Meyer
Title:
Modelling of a Chemical Reactor for Simulation of a Methanisation Plant
DOI:
http://dx.doi.org/10.3384/ecp11063572
References:

[1] Haldor Topsoe: From solid fuels to substitute natural gas (SNG) using TREMP; http://www.topsoe.com

[2] Harms; H.; Höhlein; B.; Skov; A.; Methanisierung kohlenmonoxidreicher Gase beim Energietransport. In: Chemie.-Ing. Technik; (6) page 504-515; 1980.

[3] Anderlohr; A.; Untersuchung zu gleichzeitigen Methanisierung und Konvertierung von CO-reicher Gase in einer katalytischen Wirbelschicht. Karlsruhe; Germany: PhD thesis; Fakultät für Chemieingenieurwesen; Tech. Hochschule Karlsruhe; 1979.

[4] White; W.; Johnson; S.; Danzig; G.: Chemical Equilibrium in Complex Mixtures. In: The Journal of Chemical Physics 28(5); S. 751-755 (1958). doi: 10.1063/1.1744264.

Proceedings of the 8th International Modelica Conference; March 20th-22nd; Technical Univeristy; Dresden; Germany

Author:
A. Bader, S. Bauersfeld, C. Brunhuber, R. Pardemann, B. Meyer
Title:
Modelling of a Chemical Reactor for Simulation of a Methanisation Plant
DOI:
https://doi.org10.3384/ecp11063572
Note: the following are taken directly from CrossRef
Citations:
  • Stefan Rönsch, Jens Schneider, Steffi Matthischke, Michael Schlüter, Manuel Götz, Jonathan Lefebvre, Praseeth Prabhakara & Siegfried Bajohr (2016). Review on methanation – From fundamentals to current projects. Fuel, 166: 276. DOI: 10.1016/j.fuel.2015.10.111
  • C. C. Sreejith, P. Aru & C. Muraleedharan (2013). Thermochemical Analysis of Biomass Gasification by Gibbs Free Energy Minimization Model—Part: I (Optimization of Pressure and Temperature). International Journal of Green Energy, 10(3): 231. DOI: 10.1080/15435075.2011.653846
  • Hsiu Mei Chiu, Po Chuang Chen, Yau Pin Chyo & Ting Wang (2015). Efficiency Analysis of Gas Turbine Combined-Cycle Fed with Synthetic Natural Gas (SNG) and Mixture of Syngas and SNG. Key Engineering Materials, 656-657: 113. DOI: 10.4028/www.scientific.net/KEM.656-657.113


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