Touiserkani, Mohammad Mahdi, Heydari Meybodi, Mahdi (2025). Experimental Assessment of Fracture in Rigid Nanocomposite Foams Weakened by a Pre-Crack in Mixed-Mode I/II. , 25(11), 717-724. doi: 10.48311/mme.2025.96909.0
Mohammad Mahdi Touiserkani; Mahdi Heydari Meybodi. "Experimental Assessment of Fracture in Rigid Nanocomposite Foams Weakened by a Pre-Crack in Mixed-Mode I/II". , 25, 11, 2025, 717-724. doi: 10.48311/mme.2025.96909.0
Touiserkani, Mohammad Mahdi, Heydari Meybodi, Mahdi (2025). 'Experimental Assessment of Fracture in Rigid Nanocomposite Foams Weakened by a Pre-Crack in Mixed-Mode I/II', , 25(11), pp. 717-724. doi: 10.48311/mme.2025.96909.0
Touiserkani, Mohammad Mahdi, Heydari Meybodi, Mahdi Experimental Assessment of Fracture in Rigid Nanocomposite Foams Weakened by a Pre-Crack in Mixed-Mode I/II. , 2025; 25(11): 717-724. doi: 10.48311/mme.2025.96909.0

Experimental Assessment of Fracture in Rigid Nanocomposite Foams Weakened by a Pre-Crack in Mixed-Mode I/II

مهندسی مکانیک مدرس
Volume 25, Issue 11, August 1404, Pages 717-724    PDF (1.16 M)
Document Type: مقاله پژوهشی
DOI: 10.48311/mme.2025.96909.0
Authors
Mohammad Mahdi Touiserkani1; Mahdi Heydari Meybodi* 2
1Department of Mechanical Engineering, Yazd University, Yazd, Iran.
2Department of Mechanical Engineering, Yazd University, Yazd, Iran
Abstract
Rigid nanocomposite foams reinforced with nanoclay have low density and high mechanical strength. Additionally, they offer improved thermal and fracture properties, making them attractive for advanced structural applications. This study, examines the effect of nanoclay content (0, 1, 2, and 3 wt%) on the mechanical and fracture behavior of rigid Polyurethane (PUR) foams under mixed-mode I/II loading. The samples are produced using ultrasonic dispersion and subjected to uniaxial tensile and fracture experiments with Asymmetric Edge Notch Disc Bend (AENDB) specimens. Fracture toughness and stress intensity factors are analyzed using Finite Element Modeling (FEM). The results show that adding up to 2 wt% of nanoclay enhances tensile and fracture resistance, while 3 wt% reduces strength due to nanoparticle agglomeration. Significantly, the specimen with 2 wt% of nanoclay shows the best performance, with about 35% increase in tensile strength, 25% in fracture displacement, and up to 32% improvement in fracture load under Mixed-Mode I/II conditions. In contrast, the 3 wt% sample exhibits reductions of about 18% in tensile properties and 16% in mixed-mode fracture load. These findings highlight the importance of optimizing nanoclay concentration to achieve superior fracture performance in rigid PUR foams
Keywords
Nanocomposite; Nanoclay; PUR Foam; Mixed-Mode I/II Fracture; Finite Element Modeling
References
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