This study aims to achieve a better understanding of the thermal behavior of concrete masonry systems, focusing not only on standard units but also on special thermally efficient unit configurations. In this context, sophisticated numerical models are generated to predict the thermal performance of masonry units. The validation of these numerical models follows a rigorous process that includes comparisons against experiments in the laboratory. The validated models are then used to evaluate the effect of material properties, geometry, and insulated materials on the heat flow path, distribution of temperatures, and air velocities within the units. The results show the importance of including the three heat transfer mechanisms of conduction, convection, and radiation within an effective numerical model and the equal importance of considering the influence of air flow within the cells of the masonry units.

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numerical models concrete masonry heat transfer mechanisms radiation heat flow path distribution of temperatures and air velocities thermal performance cells insulated thermally efficient unit conduction convection

Nathaniel Huygen,Marcos Martínez, John Sanders, Sez Atamturktur,.Thermo-fluid dynamic analysis of concrete masonry units via experimental testing and numerical modeling. 19 (0),.

Nathaniel Huygen, et al."Thermo-fluid dynamic analysis of concrete masonry units via experimental testing and numerical modeling" 19

Nathaniel Huygen,Marcos Martínez, John Sanders, Sez Atamturktur,"Thermo-fluid dynamic analysis of concrete masonry units via experimental testing and numerical modeling"