Numerical Determination of Two-Phase Material Parameters of a Gas Diffusion Layer Using Tomography Images

Becker, J.; Schulz, Volker P.; Wiegmann, Andreas

doi:10.1115/1.2821600

Cited by 81 publications

(85 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…on the heat treatment of the fibers. This may explain the apparent discrepancy between the results for structural models of carbon paper by (Becker et al, 2008) and where thermal conductivity values of 17 W/ m K and 130 W/ m K were used, respectively.…”

Section: Computation Of Thermal Conductivity Of Gas Diffusion Layersmentioning

confidence: 90%

“…A carbon cloth is shown as sample X-ray computed tomography (Ostadi et al, 2008;Pfrang et al, 2010) as well as synchrotron based tomography (Becker et al, 2008;Becker et al, 2009) have been used for imaging of gas diffusion layers at resolutions below 1 µm. Also membranes and membrane electrode assemblies (Garzon et al, 2007;Pfrang et al, 2011) have been imaged by X-ray computed tomography and even functioning fuel cells have been imaged by synchrotron-based methods and soft X-ray radiography e.g.…”

Section: Fig 2 Principle Of X-ray Computed Tomography (Ct)mentioning

confidence: 99%

“…As more accurate thermal conductivity data is required, one further approach is the computation based on 3D structure data (Becker et al, 2008;Pfrang et al, 2010;Zamel et al, 2010). Fig.…”

Section: Computation Of Thermal Conductivity Of Gas Diffusion Layersmentioning

confidence: 99%

See 2 more Smart Citations

Computation of Thermal Conductivity of Gas Diffusion Layers of PEM Fuel Cells

Pfrang¹,

Veyret²,

Tsotridis³

2011

Convection and Conduction Heat Transfer

View full text Add to dashboard Cite

Section: Computation Of Thermal Conductivity Of Gas Diffusion Layersmentioning

confidence: 90%

Section: Fig 2 Principle Of X-ray Computed Tomography (Ct)mentioning

confidence: 99%

See 1 more Smart Citation

Computation of Thermal Conductivity of Gas Diffusion Layers of PEM Fuel Cells

Pfrang¹,

Veyret²,

Tsotridis³

2011

Convection and Conduction Heat Transfer

View full text Add to dashboard Cite

“…The latest laboratory-based X-ray nano-tomography can achieve a resolution of 400 nm with detectability of 100-200 nm (McNulty et al, 1995;Warwick et al, 1998;Cai et al, 2000;Parkinson and Sasov, 2008). Recently, X-raymicro-tomography has been used to quantify liquid water saturation distribution in porous GDLs and determining the Q1 two-phase material parameters with a sub 10 mm resolution (Becker et al, 2008;Sinha et al, 2006). The latest report suggests that nano-tomography (Nano XCT, US: Xradia Corp.) can be used to reconstruct the porous catalyst layer (CL) of fuel cells at sub-micron resolution in order to study the changes in membranes after transient operation (Garzon et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Influence of threshold variation on determining the properties of a polymer electrolyte fuel cell gas diffusion layer in X-ray nano-tomography

Ostadi

Rama

Liu

et al. 2010

Chemical Engineering Science

View full text Add to dashboard Cite

Morphological parameters of a 3D binary image of a porous carbon gas diffusion layer (GDL) for polymer electrolyte fuel cells (PEFC) reconstructed using X-ray nano-tomography scanning have been obtained, and influence of small alterations in the threshold value on the simulated flow properties of the reconstructed GDL has been determined. A range of threshold values with 0.4% increments on the greyscale map have been applied and the gas permeability of the binary images have been calculated using a single-phase lattice Botlzmann model (LBM), which is based on the treatment of nineteen velocities in the three dimensional domain (D3Q19). The porosity, degrees of anisotropy and the mean pore radius have been calculated directly from segmented voxel representation. A strong relationship between these parameters and threshold variation has been established. These findings suggest that threshold selection can significantly affect some of the flow properties and may strongly influence the computational simulation of micro and nano-scale flows in a porous structure.

show abstract

“…The macroscale model was based on Darcy's law and mass conservation, where the permeability and capillary pressure must be calculated as a function of saturation level from a microscopic model. On that level, instead of directly solving the two-phase flow problem, a pore morphology model was used [13]. The pore morphology model determined the fluid-gas interface geometry by inserting different sizes of spheres in the porous media and thus provides the capillary pressure through the Young-Laplace equation.…”

Section: Introductionmentioning

confidence: 99%

Microfluidics of imbibition in random porous media

Wiklund

Uesaka

2013

Phys. Rev. E

View full text Add to dashboard Cite

A free-energy lattice Boltzmann approach has been used to perform simulations of liquid penetration into random porous media. We focus our study on the effects of microstructures, particularly microtopography, on liquid penetration driven by capillary force and external pressure. For this purpose we set up a model structure that consists of a network of interconnected capillaries with varying pore geometries. The results showed that the discontinuities in the solid-surface curvature, as are present as corners on the capillary surfaces, have strong influences on liquid penetration through their pinning effects and interactions with local geometry.

show abstract

Numerical Determination of Two-Phase Material Parameters of a Gas Diffusion Layer Using Tomography Images

Cited by 81 publications

References 11 publications

Computation of Thermal Conductivity of Gas Diffusion Layers of PEM Fuel Cells

Computation of Thermal Conductivity of Gas Diffusion Layers of PEM Fuel Cells

Influence of threshold variation on determining the properties of a polymer electrolyte fuel cell gas diffusion layer in X-ray nano-tomography

Microfluidics of imbibition in random porous media

Contact Info

Product

Resources

About