Jens Bremer scite author profile

Utilizing volatile renewable energy sources (e.g., solar, wind) for chemical production systems requires a deeper understanding of their dynamic operation modes. Taking the example of a methanation reactor in the context of power-togas applications, a dynamic optimization approach is used to identify control trajectories for a time optimal reactor start-up avoiding distinct hot spot formation. For the optimization, we develop a dynamic, two-dimensional model of a fixed-bed tube reactor for carbon dioxide methanation which is based on the reaction scheme of the underlying exothermic Sabatier reaction mechanism. While controlling dynamic hot spot formation inside the catalyst bed, we prove the applicability of our methodology and investigate the feasibility of dynamic carbon dioxide methanation.

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Operation range extensionviahot-spot control for catalytic CO₂methanation reactors

Bremer

Sundmacher

2019

React. Chem. Eng.

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Porosity and Structure of Hierarchically Porous Ni/Al2O3 Catalysts for CO2 Methanation

et al. 2020

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CO2 methanation is often performed on Ni/Al2O3 catalysts, which can suffer from mass transport limitations and, therefore, decreased efficiency. Here we show the application of a hierarchically porous Ni/Al2O3 catalyst for methanation of CO2. The material has a well-defined and connected meso- and macropore structure with a total porosity of 78%. The pore structure was thoroughly studied with conventional methods, i.e., N2 sorption, Hg porosimetry, and He pycnometry, and advanced imaging techniques, i.e., electron tomography and ptychographic X-ray computed tomography. Tomography can quantify the pore system in a manner that is not possible using conventional porosimetry. Macrokinetic simulations were performed based on the measures obtained by porosity analysis. These show the potential benefit of enhanced mass-transfer properties of the hierarchical pore system compared to a pure mesoporous catalyst at industrially relevant conditions. Besides the investigation of the pore system, the catalyst was studied by Rietveld refinement, diffuse reflectance ultraviolet-visible (DRUV/vis) spectroscopy, and H2-temperature programmed reduction (TPR), showing a high reduction temperature required for activation due to structural incorporation of Ni into the transition alumina. The reduced hierarchically porous Ni/Al2O3 catalyst is highly active in CO2 methanation, showing comparable conversion and selectivity for CH4 to an industrial reference catalyst.

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Optimal catalyst particle design for flexible fixed-bed CO2 methanation reactors

Zimmermann

Bremer

Sundmacher

2020

Chemical Engineering Journal

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Jens Bremer

CO₂ methanation: Optimal start‐up control of a fixed‐bed reactor for power‐to‐gas applications

Operation range extensionviahot-spot control for catalytic CO₂methanation reactors

Porosity and Structure of Hierarchically Porous Ni/Al2O3 Catalysts for CO2 Methanation

Optimal catalyst particle design for flexible fixed-bed CO2 methanation reactors

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About

Jens Bremer

CO2 methanation: Optimal start‐up control of a fixed‐bed reactor for power‐to‐gas applications

Operation range extensionviahot-spot control for catalytic CO2methanation reactors

Porosity and Structure of Hierarchically Porous Ni/Al2O3 Catalysts for CO2 Methanation

Optimal catalyst particle design for flexible fixed-bed CO2 methanation reactors

Contact Info

Product

Resources

About

CO₂ methanation: Optimal start‐up control of a fixed‐bed reactor for power‐to‐gas applications

Operation range extensionviahot-spot control for catalytic CO₂methanation reactors