Your search keyword '"Industrial Electrolysis"' showing total 3 results

1. Coupling K convection-diffusion and Laplace equations in an open-source CFD model for tertiary current distribution calculations

Author

J. M. Bisang and A. N. Colli

Subjects

Coupling, Materials science, Current distribution, Laplace transform, Renewable Energy, Sustainability and the Environment, business.industry, HYDROCYCLONE, Mechanics, Computational fluid dynamics, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, tertiary current distribution, electrochemical reactors, purl.org/becyt/ford/2.4 [https], Open source, purl.org/becyt/ford/2 [https], Materials Chemistry, Electrochemistry, Industrial Electrolysis, OpenFOAM, business, Convection–diffusion equation

Abstract

A mathematical model to calculate tertiary current distributions in electrochemical reactors is presented taking into account the potential and concentration fields together with the hydrodynamics under laminar or turbulent conditions. Multiple reactions with different kinetic controls are considered at both electrodes. The computational algorithm solving the model was implemented in OpenFOAM. It allows the calculations for a given local potential at the working electrode, potentiostatic control, or for a fixed cell potential difference and also for a current flowing through the cell, galvanostatic operation. The model was validated by using the reduction of ferricyanide and the oxidation of ferrocyanide from dilute solutions as main test reactions and hydrogen and oxygen evolution as secondary ones, in a modified hydrocyclone. A close agreement between experimental and predicted current distributions was obtained. The hydrocyclone presents a promising electrochemical performance being the mass-transfer conditions in its cylindrical part better than in the conical region. The computational tool developed in this paper can be employed to optimize both cells stack design and system operation conditions. Likewise, the algorithm can also be used to check, when limiting current studies are needed, whether the desired reaction is under mass-transfer or charge-transfer control for a given geometric configuration. Fil: Colli, Alejandro Nicolás. Universidad Nacional del Litoral. Facultad de Ingeniería Química. Programa de Electroquímica Aplicada e Ingeniería Electroquímica; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Santa Fe; Argentina Fil: Bisang, Jose Maria. Universidad Nacional del Litoral. Facultad de Ingeniería Química. Programa de Electroquímica Aplicada e Ingeniería Electroquímica; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Santa Fe; Argentina

Published

2019

2. Polymer Electrolyte Water Electrolysis: Correlating Porous Transport Layer Structural Properties and Performance: Part I. Tomographic Analysis of Morphology and Topology

Author

Thomas J. Schmidt, Felix N. Büchi, Ruben De Bruycker, and Tobias Schuler

Subjects

polymer electrolyte water electrolysis, Morphology (linguistics), Materials science, porous transport layer, Electrolyte, Materials Chemistry, Electrochemistry, Surface roughness, Industrial Electrolysis, Porosity, Energy conversion, Energy Storage, membrane deformation, surface roughness, interface, Topology (chemistry), chemistry.chemical_classification, Electrolysis of water, Renewable Energy, Sustainability and the Environment, Polymer, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Chemical engineering, chemistry, Transport layer

Abstract

In the first paper of this series, the bulk, surface and transport properties of porous transport layer materials (PTL) for polymer electrolyte water electrolysis cells (PEWE) are characterized. A systematic PTL matrix of Ti fiber materials with 3 fiber diameters and 2 nominal porosities as well as a state of the art sintered powder material are investigated to get a better understanding of the governing parameters in electrolysis cells. X-ray tomographic microscopy analysis of ex situ PTL structures and post operando membrane electrode assemblies is performed. On the tomographic structures, bulk (porosity, pore/solid size distributions, fiber orientation), mass transport (diffusivity, permeability, conductivities) and surface parameters (roughness, membrane deformation, PTL surface area and interfacial contact area) are determined. The second paper of this series will correlate the structural parameters with in-depth electrochemical analysis. The new insights into the effect of PTL properties on PEWE performance allow to isolate governing key parameters. From know-how obtained on the fiber based materials fundamental design guidelines for optimization of PTL structures are deduced., Journal of the Electrochemical Society, 166 (4), ISSN:0013-4651, ISSN:1945-7111

Published

2019

3. Modeling the electrochemical conversion of carbon dioxide to formic acid or formate at elevated pressures

Author

Vincent van Beusekom, Thijs J. H. Vlugt, Andrew R. T. Morrison, Wiebren de Jong, Mahinder Ramdin, and Leo J. P. van den Broeke

Subjects

Materials science, Formic acid, High Pressure Electrolyzer, 020209 energy, CO2 electroreduction, Analytical chemistry, Electrochemical Engineering, 02 engineering and technology, Electrolyte, law.invention, Diffusion layer, chemistry.chemical_compound, law, 0202 electrical engineering, electronic engineering, information engineering, Materials Chemistry, Electrochemistry, Specific energy, Industrial Electrolysis, Formate, Partial current, Energy Conversion, Electrolysis, Renewable Energy, Sustainability and the Environment, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry, Simulation, Bar (unit)

Abstract

In this work a model of an elevated pressure CO2 electrolyzer producing primarily formate or formic acid is presented. It consists of three parts: A model of the bulk electrolyte, the diffusion layer, and the electrode surface. Data from the literature was used to validate both the bulk portion of the model, as well as the overall model. Results from the literature were further explored and explained by reference to the model and faradaic efficiency is predicted very well (R-Square of 0.99 for the fitted data, and 0.98 for the non-fitted data). The primary effect of increasing the pressure on a CO2 electrolyzer is seen to be increasing the maximum attainable partial current density, while the faradaic efficiency and specific energy of formation plateau at pressures above 10-20 bar, at 95% and of 3.7 kWh/kg, respectively. Unlike the efficiencies, the profitability of running a reactor increases with pressure, following a similar trend as partial current density, showing the importance of this quantity as a performance metric of a CO2 electrolyzer. In general this work shows the utility of a model of this sort in the design, evaluation and operation of CO2 electrolyzers.

Published

2019