材料科学
复合材料
抗弯强度
极限抗拉强度
烧蚀
复合数
转移模塑
体积分数
分层(地质)
纤维
剪切(地质)
弯曲
复合材料层合板
堆积
抗剪强度(土壤)
胶粘剂
造型(装饰)
质量分数
纤维增强复合材料
剪应力
作者
Zeynep N. Akyazici,Burak Selamet,Muhammed E. Kilinc,Mustafa Baysal,Seher Eken,Ceyhun Tola,Mehmet Kahraman
摘要
This study aims to prevent delamination of high silica-based phenolic ablative composite by needle punch technique and silica felt structure. Conventional laminate and needle-punched (NP) configurations were both experimentally investigated for their mechanical response and torch-ablation behavior in high-silica (HS) fiber reinforced phenolic composites. A series of HS fabric–felt preforms with different fabric/felt layer ratios and fiber volume fractions were manufactured using a laboratory needle-punching set-up, impregnated with phenolic resin by vacuum assisted resin transfer molding (VARTM) and consolidated by hot pressing. For each configuration, tensile, short-beam shear, and three-point bending tests were performed, together with oxy-propane torch tests to determine linear and mass ablation rates. Compared with the baseline laminate reference, the needle-punched configurations exhibited a 25–60% reduction in tensile strength and up to about 25% lower flexural strength, whereas the interlaminar shear strength obtained from short-beam tests increased by as much as 40–50% due to the improved through-thickness fiber bridging. In parallel, the non-needle-punched silica fabric–silica felt configuration showed only a modest decrease in tensile and flexural strength compared with the reference laminate while maintaining a relatively high interlaminar shear capacity, suggesting that this simpler, more easily manufactured configuration can be considered a practical alternative when processing robustness and cost are prioritized over maximum delamination resistance. According to ablation measurements, the laminate displayed the strongest ply-by-ply separation and the highest linear ablation rate. While maintaining similar tensile and flexural performance, an optimized needle-punched configuration with a balanced fabric/felt stacking sequence and a fiber volume fraction of roughly 60–65% decreased the mass ablation rate by roughly 40–50% and the linear ablation rate by roughly 90% in comparison to the laminated reference. Needle-punched composites produced a more stable char layer and considerably reduced delamination during extreme heat loading, according to post-test inspections. Overall, the results demonstrate that appropriately designed needle-punched HS/phenolic composites offer a substantial improvement in delamination resistance and ablative performance without sacrificing mechanical properties, making them strong candidates for thermal-protection components in aerospace applications.
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