TY - UNPB
T1 - Multi-scale flow, permeability, and heat transport in low-carbon and traditional building materials
AU - Menke, Hannah P.
AU - Hood, Katherine M.
AU - Singh, Kamaljit
AU - Medero, Gabriela M.
AU - Maes, Julien
PY - 2024/5/30
Y1 - 2024/5/30
N2 - Permeability and heat transport through building materials ultimately dictates their insulatory performance over a buildings service lifetime. Experiments combining XCT with numerical modelling are an accepted method of studying pore scale processes and have been used extensively in the oil and gas industry to study highly complex reservoir rocks. However, despite the obvious similarities in structure and application, these techniques have not yet been widely adopted by the building and construction industry. An experimental investigation was performed on the pore structure of several building materials, including conventional, historic, and innovative, using XCT and direct numerical simulation. Six samples were imaged at between a 4 and 15 micron resolution inside a micro-CT scanner. The porosity and connectivity were extracted with the grain, throat, and pore size distributions using image analysis. The permeability, velocity, and thermal conductivity were then investigated using GeoChemFoam, our highly-versatile and open source numerical solver. It was found that each material had a unique, heterogeneous and sometimes multi-scale structure that had a large impact on the permeability and thermal conductivity. Furthermore, it was found that the method of including sub-resolution porosity directly effected these bulk property calculations for both parameters, especially in the materials with high structural heterogeneity. This is the first multi-scale study of structure, flow and heat transport on building materials and this workflow could easily be adapted to understand and improve designs in other industries that use porous materials such as fuel cells and batteries technology, lightweight materials and insulation, and semiconductors.
AB - Permeability and heat transport through building materials ultimately dictates their insulatory performance over a buildings service lifetime. Experiments combining XCT with numerical modelling are an accepted method of studying pore scale processes and have been used extensively in the oil and gas industry to study highly complex reservoir rocks. However, despite the obvious similarities in structure and application, these techniques have not yet been widely adopted by the building and construction industry. An experimental investigation was performed on the pore structure of several building materials, including conventional, historic, and innovative, using XCT and direct numerical simulation. Six samples were imaged at between a 4 and 15 micron resolution inside a micro-CT scanner. The porosity and connectivity were extracted with the grain, throat, and pore size distributions using image analysis. The permeability, velocity, and thermal conductivity were then investigated using GeoChemFoam, our highly-versatile and open source numerical solver. It was found that each material had a unique, heterogeneous and sometimes multi-scale structure that had a large impact on the permeability and thermal conductivity. Furthermore, it was found that the method of including sub-resolution porosity directly effected these bulk property calculations for both parameters, especially in the materials with high structural heterogeneity. This is the first multi-scale study of structure, flow and heat transport on building materials and this workflow could easily be adapted to understand and improve designs in other industries that use porous materials such as fuel cells and batteries technology, lightweight materials and insulation, and semiconductors.
KW - cond-mat.mtrl-sci
U2 - 10.48550/arXiv.2405.19930
DO - 10.48550/arXiv.2405.19930
M3 - Preprint
BT - Multi-scale flow, permeability, and heat transport in low-carbon and traditional building materials
ER -