The penetration and perforation performance of glass-reinforced plastic(GRP)plates containing 20% sand filler has been investigated via quasi-static indentation tests using a sharp-tip(30°)indenter.Two sizes of sand filler(75 and 600 mu m)were incorporated in the composite plates to investigate the sensitivity of filler size towards loading system.Also, composite plates were subjected to perforation tests at 5 and 500 mm/min load rates.The investigation successfully used load-displacement behaviours during penetration and perforation by the sharp-tip indenter as a measure for assessing the low-velocity impact performance.The results indicated the clear role played by coarse-sized sand filler as a secondary reinforcement in terms of higher energy absorption.The residual frictional load was up to 45% of maximum perforation load, a considerable gain also due to sand filler incorporation.Composite plates containing coarse-sized filler showed higher energy absorption compared with fine-sized fillers.Higher energy absorption was obtained for plates under high loading rate(500 mm/ min).Fibre and matrix fracture constituted the major damage mode in the composite plates tested, followed by delamination.The test results also showed diminishing effectiveness associated with the specific energy absorption of these plates.
展开▼
机译:通过使用尖头(30°)压头进行准静态压痕测试,研究了含20%砂填充物的玻璃钢(GRP)板的渗透和穿孔性能。两种尺寸的砂填充物(75和600μm) )被加入到复合板中以研究填料尺寸对加载系统的敏感性。此外,复合板还以5和500 mm / min的加载速率进行了穿孔测试,该研究成功地利用了穿透和穿孔过程中的载荷位移行为。锋利的压头作为评估低速冲击性能的一种方法。结果表明,粗砂填充物在提高能量吸收方面起到了辅助补强的作用,残余摩擦载荷高达45%最大的射孔载荷,也由于砂填料的加入而获得了可观的收益。含有粗粒填料的复合板比细粒填料具有更高的能量吸收d填料。在高加载速率(500 mm / min)下,板的能量吸收更高;纤维和基体断裂是测试的复合板的主要破坏模式,随后分层。测试结果还显示,与复合材料相关的有效性降低。这些板的比能量吸收。
展开▼
