“…22 Amirpasha Peyvandi at el 2013 reported that the concrete pipes that were made on an industrial scale to test the impact of discrete reinforcement of the graphite Nano platelet and microscale PVA fibre addition on vapor movement and persistence of concrete material. [23][24][25][26][27][28] Comsol multiphysics based on Finite element model ling (FEM) have been used by several research report to examine how the heat transfers through masonry hollow blocks. Because Al-Hazmy used FEM to study the heat transport through masonry hollow blocks and look into the impact of the cavities.…”
The objective of this research was to add nano/micro composites to red bricks in order to reduce costs while increasing strength. A finite element model (FEM COMSOL) was created to determine the best cavity design and placement in nano/micro composite bricks in order to decrease density and boost mechanical characteristics. Several nano/micro composite materials were used to broaden this red brick's mechanical, electrical, energy storage, and thermal uses. The development of a finite element model COMSOL for red brick blocks with the ideal cavity shape and location for analyzing mechanical characteristics was applied for the first time in the paper. The concrete blocks were produced and strengthened using two distinct types of nano/micro materials to further enhance the stretch of the red bricks' nanocomposites. The addition of Al2O3/ Graphite NPs influences the mechanical properties of clay bricks. A detached study of Al2O3/ Graphite nanoparticles affects the mechanical properties of clay bricks including compressive strength, water absorption, and density is reported. It also includes the comparison of traditional clay bricks with Al2O3/ Graphite NPs mixtures.
“…22 Amirpasha Peyvandi at el 2013 reported that the concrete pipes that were made on an industrial scale to test the impact of discrete reinforcement of the graphite Nano platelet and microscale PVA fibre addition on vapor movement and persistence of concrete material. [23][24][25][26][27][28] Comsol multiphysics based on Finite element model ling (FEM) have been used by several research report to examine how the heat transfers through masonry hollow blocks. Because Al-Hazmy used FEM to study the heat transport through masonry hollow blocks and look into the impact of the cavities.…”
The objective of this research was to add nano/micro composites to red bricks in order to reduce costs while increasing strength. A finite element model (FEM COMSOL) was created to determine the best cavity design and placement in nano/micro composite bricks in order to decrease density and boost mechanical characteristics. Several nano/micro composite materials were used to broaden this red brick's mechanical, electrical, energy storage, and thermal uses. The development of a finite element model COMSOL for red brick blocks with the ideal cavity shape and location for analyzing mechanical characteristics was applied for the first time in the paper. The concrete blocks were produced and strengthened using two distinct types of nano/micro materials to further enhance the stretch of the red bricks' nanocomposites. The addition of Al2O3/ Graphite NPs influences the mechanical properties of clay bricks. A detached study of Al2O3/ Graphite nanoparticles affects the mechanical properties of clay bricks including compressive strength, water absorption, and density is reported. It also includes the comparison of traditional clay bricks with Al2O3/ Graphite NPs mixtures.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.