Mechanical Properties of Sandwiched Construction with Composite and Hybrid Core Structure

IF 2 4区工程技术 Q3 ENGINEERING, CHEMICAL

Advances in Polymer Technology Pub Date : 2024-01-19 DOI:10.1155/2024/3803199

Emad Kadum Njim, Hussam Raad Hasan, Muhsin J. Jweeg, Muhannad Al-Waily, Alaa Ali Hameed, Ahmed M. Youssef, Fahmi M. Elsayed

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Abstract

In the field of lighter substitute materials, sandwich plate models of composite and hybrid foam cores are used in this study. Three core structures: composite core structure and then the core is replaced by a structure of a closed and open repeating cellular pattern manufactured with 3D printing technology. It finally integrated both into one hybrid open-cell core filled with foam and employed the same device (WBW-100E) to conduct the three-point bending experiment. The test was conducted based on the international standard (ASTM-C 393-00) to perform the three-point bending investigation on the sandwich structure. Flexural test finding, with the hybrid polyurethane/polytropic acid (PUR/PLA) core, the ultimate bending load is increased by 127.7% compared to the open-cell structure core. In addition, the maximum deflection increased by 163.3%. The simulation results of three-point bending indicate that employing a hybrid combination of PUR-PLA led to an increase of 382.3%, and for PUR–TPU by 111.8%; however, the highest value recorded with PUR/PLA, which has the slightest stress error among the tests. Also, it is reported that when the volume fraction of reinforced aluminum particles is increased, the overall deformation becomes more sufficient, and the test accuracy improves; for example, rising from 0.5% to 3%, the midspan deflection of composite (foam-Al) is increased by 40.34%. There were noticeable improvements in mechanical properties in the 2.5% composite foam-Al.

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采用复合材料和混合芯材结构的夹层结构的力学性能

在轻型替代材料领域，本研究采用了复合材料和混合泡沫芯材的夹层板模型。三种芯材结构：复合芯材结构，然后用三维打印技术制造的封闭式和开放式重复蜂窝模式结构取代芯材。最后将二者整合为一个填充泡沫的混合开孔芯材，并采用同一设备（WBW-100E）进行三点弯曲实验。测试依据国际标准（ASTM-C 393-00）对夹层结构进行三点弯曲研究。挠曲试验结果表明，与开孔结构芯材相比，聚氨酯/聚丙烯酸（PUR/PLA）混合芯材的极限弯曲载荷增加了 127.7%。此外，最大挠度增加了 163.3%。三点弯曲的模拟结果表明，采用 PUR-PLA 混合组合可提高 382.3%，PUR-TPU 可提高 111.8%；然而，PUR/PLA 记录的数值最高，是所有测试中应力误差最小的。另据报道，当增强铝颗粒的体积分数增加时，整体变形会变得更充分，测试精度也会提高；例如，从 0.5% 增加到 3%，复合材料（泡沫-铝）的中跨挠度增加了 40.34%。2.5% 的泡沫-铝复合材料的机械性能有明显改善。

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来源期刊

Advances in Polymer Technology 工程技术-高分子科学

CiteScore

5.50

自引率

0.00%

发文量

审稿时长

9 months

期刊介绍： Advances in Polymer Technology publishes articles reporting important developments in polymeric materials, their manufacture and processing, and polymer product design, as well as those considering the economic and environmental impacts of polymer technology. The journal primarily caters to researchers, technologists, engineers, consultants, and production personnel.