TY - JOUR
T1 - FINITE ELEMENT ANALYSIS ON STRUCTURAL BEHAVIOUR OF GEOpOLYMER REINFORCED CONCRETE BEAM USING JOHNSON-COOK DAMAGE IN ABAQUS
AU - Mortar, Nurul Aida Mohd
AU - Abdullah, MMAB
AU - Hussin, Kamarudin
AU - Razak, Rafiza Abdul
AU - Hamat, Sanusi
AU - Hilmi, Ahmad Humaizi
AU - Shahedan, Noorfifi Natasha
AU - Li, Long Yuan
AU - Aziz, Ikmal Hakem A.
PY - 2022/11/23
Y1 - 2022/11/23
N2 - This paper details a finite element analysis of the behaviour of Si-Al geopolymer concrete beam reinforced steel bar under an impulsive load and hyper velocity speed up to 1 km/s created by an air blast explosion. The initial torsion stiffness and ultimate torsion strength of the beam increased with increasing compressive strength and decreasing stirrup ratio. The study involves building a finite element model to detail the stress distribution and compute the level of damage, displacement, and cracks development on the geopolymer concrete reinforcement beam. This was done in ABAQUS, where a computational model of the finite
element was used to determine the elasticity, plasticity, concrete tension damages, concrete damage plasticity, and the viability of the Johnson-Cook Damage method on the Si-Al geopolymer concrete. The results from the numerical simulation show that an increase in the load magnitude at the midspan of the beam leads to a percentage increase in the ultimate damage of the reinforced geopolymer beams failing in shear plastic deformation. The correlation between the numerical and experimental blasting results confirmed that the damage pattern accurately predicts the response of the steel reinforcement Si-Al geopolymer concrete beams,
concluded that decreasing the scaled distance from 0.298 kg/m3 to 0.149 kg/m3 increased the deformation percentage.
AB - This paper details a finite element analysis of the behaviour of Si-Al geopolymer concrete beam reinforced steel bar under an impulsive load and hyper velocity speed up to 1 km/s created by an air blast explosion. The initial torsion stiffness and ultimate torsion strength of the beam increased with increasing compressive strength and decreasing stirrup ratio. The study involves building a finite element model to detail the stress distribution and compute the level of damage, displacement, and cracks development on the geopolymer concrete reinforcement beam. This was done in ABAQUS, where a computational model of the finite
element was used to determine the elasticity, plasticity, concrete tension damages, concrete damage plasticity, and the viability of the Johnson-Cook Damage method on the Si-Al geopolymer concrete. The results from the numerical simulation show that an increase in the load magnitude at the midspan of the beam leads to a percentage increase in the ultimate damage of the reinforced geopolymer beams failing in shear plastic deformation. The correlation between the numerical and experimental blasting results confirmed that the damage pattern accurately predicts the response of the steel reinforcement Si-Al geopolymer concrete beams,
concluded that decreasing the scaled distance from 0.298 kg/m3 to 0.149 kg/m3 increased the deformation percentage.
KW - ABAQUS software
KW - finite element analysis
KW - Fly ash geopolymer
KW - geopolymer concrete
KW - Johnson cook damage
U2 - 10.24425/amm.2022.141061
DO - 10.24425/amm.2022.141061
M3 - Article
SN - 1733-3490
VL - 67
SP - 1349
EP - 1354
JO - Archives of Metallurgy and Materials
JF - Archives of Metallurgy and Materials
IS - 4
ER -