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Impact of SCB Specimen Size, Temperature, Loading Rate, and Loading Mode on Fracture Behavior of Asphalt Mixture Using Response Surface Method

Zahra Vaseghi, Sadjad Pirmohammad, Ramin Momeni

2024Fatigue & Fracture of Engineering Materials & Structures17 citationsDOIOpen Access PDF

Abstract

ABSTRACT This study aimed to investigate the influence of semicircular bend (SCB) specimen size ( R ), loading mode ( M e ), and loading rate ( Lr ) on fracture resistance indicators, namely, fracture work ( W f ), fracture energy ( G f ), and fracture strength ( K f ), of asphalt concrete at three different temperatures (−30°C, −20°C, and 10°C). Using Minitab software, response surface methodology (RSM) under central composite design (CCD) was employed to design experiments and develop predictive models for W f , G f , and K f in terms of R , M e , and Lr at each temperature. The results demonstrated that the RSM models accurately predicted the fracture test data for all temperatures. The analysis of variance (ANOVA) revealed that R , M e , and Lr significantly influenced W f , G f , and K f at each temperature, whereas the square terms R 2 , M e2 , and Lr 2 were not significant. The significance of two‐way interaction terms varied across different responses and temperatures. Overall, the experiments conducted at −30°C, −20°C, and 10°C indicated that varying R , Lr , and M e had notable effects on W f , G f , and K f . Increasing R and M e while decreasing Lr resulted in an increase in W f and G f . Furthermore, K f exhibited a direct relationship with R and Lr but an inverse relationship with M e .

Topics & Concepts

Materials scienceAsphaltComposite materialFracture (geology)Mode (computer interface)Structural engineeringEngineeringComputer scienceOperating systemAsphalt Pavement Performance EvaluationGeotechnical Engineering and Underground StructuresRock Mechanics and Modeling