Markus Goldbrunner scite author profile

Markus Goldbrunner

4Publications

66Citation Statements Received

32Citation Statements Given

How they've been cited

How they cite others

100

Affiliations

Technische Hochschule Ingolstadt, Kraftanlagen (Germany), Klinikum Ingolstadt

Publications

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Modeling Mixing in Anaerobic Digesters with Computational Fluid Dynamics Validated by Experiments

et al. 2018

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To keep biogas production competitive against alternatives in the energy sector, operating costs of biogas plants must be reduced. Up to 50 % of the energy consumption in biogas plants is contributed by mixing of biomass slurry. Thus, optimization of the mixing system is a promising approach to increase the overall efficiency of biogas plants. Investigations to find the optimal conditions of mixing are challenging in full‐scale biogas digesters. Two main strategies to study biomass mixing in laboratories are to build a scale‐down digester using an artificial substrate to mimic biomass, and to develop a computational fluid dynamics (CFD) model to simulate the mixing process. In this paper, a combined approach is carried out: a CFD model is presented and verified experimentally.

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CFD Modelling of Biomass Mixing in Anaerobic Digesters of Biogas Plants

Conti

Saidi

Goldbrunner

2019

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Cut in greenhouse gas emissions, increment of energy from renewables and improvement in energy efficiency represent the three key targets for future energy systems. Among the available bioenergy technologies, biogas production via biodegradation and anaerobic digestion is a widely applied approach, not only to produce biofuels but also to manage industrial and domestic organic waste. Within the biogas production, a sufficient mixing of the organic mass is a crucial step to ensure high biogas yields by bacteria and enzymes. Measurements of the electric power consumption of biogas plants revealed that the electrical energy demand of the stirrer system has a high share of the total electricity consumption of a biogas plant. Investigations on real biogas digesters to optimize the mixing process are cost and time intensive. Therefore, laboratory prototypes and computational simulations represent promising alternatives to analyse and improve the efficiency of mixing systems. In this paper, a computational fluid dynamics (CFD) model is presented, which is applied to commercial stirring systems. The case of two propeller stirrers, located in diametrically opposite positions in a tank filled with ca. 1400 m3 of substrate is described in detail. For the simulation, the rheology of the fluid is adapted to a biomass with 12 wt % dry matter content and obeying the non-Newtonian generalized Ostwald-de Waele power law. The developed simulation procedure considers the rotation angle of each propeller and its height. A total of 441 mixing configurations are calculated and evaluated in terms of the technical benefit. The investigation reveals that locations of the rotors far away from the bottom and high rotational angles cause advantageous fluid dynamics.

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Monitoring the mixing of an artificial model substrate in a scale-down laboratory digester

et al. 2019

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Thermal behaviour of viscosity of aqueous cellulose solutions to emulate biomass in anaerobic digesters

et al. 2018

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