Experimental investigation on the anti-detonation performance of composite structure containing foam geopolymer backfill material

IF 5.1 2区 工程技术 Q1 Engineering
Hang Zhou, Hujun Li, Zhen Wang, Dongming Yan, Wenxin Wang, Guokai Zhang, Zirui Cheng, Song Sun, Mingyang Wang
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Abstract

The compression and energy absorption properties of foam geopolymers increase stress wave attenuation under explosion impacts, reducing the vibration effect on the structure. Explosion tests were conducted using several composite structure models, including a concrete lining structure (CLS) without foam geopolymer and six foam geopolymer composite structures (FGCS) with different backfill parameters, to study the dynamic response and wave dissipation mechanisms of FGCS under explosive loading. Pressure, strain, and vibration responses at different locations were synchronously tested. The damage modes and dynamic responses of different models were compared, and how wave elimination and energy absorption efficiencies were affected by foam geopolymer backfill parameters was analyzed. The results showed that the foam geopolymer absorbed and dissipated the impact energy through continuous compressive deformation under high strain rates and dynamic loading, reducing the strain in the liner structure by 52% and increasing the pressure attenuation rate by 28%. Additionally, the foam geopolymer backfill reduced structural vibration and liner deformation, with the FGCS structure showing 35% less displacement and 70% less acceleration compared to the CLS. The FGCS model with thicker, less dense foam geopolymer backfill, having more pores and higher porosity, demonstrated better compression and energy absorption under dynamic impact, increasing stress wave attenuation efficiency. By analyzing the stress wave propagation and the compression characteristics of the porous medium, it was concluded that the stress transfer ratio of FGCS-ρ-579 was 77% lower than that of CLS, and the transmitted wave energy was 90% lower. The results of this study provide a scientific basis for optimizing underground composite structure interlayer parameters.
含泡沫土工聚合物回填材料的复合结构抗爆性能实验研究
泡沫土工聚合物的压缩和吸能特性增加了爆炸冲击下的应力波衰减,降低了对结构的振动影响。利用几种复合结构模型(包括不含泡沫土工聚合物的混凝土衬砌结构(CLS)和六种具有不同回填参数的泡沫土工聚合物复合结构(FGCS))进行了爆炸试验,以研究爆炸荷载下泡沫土工聚合物复合结构的动态响应和消波机制。对不同位置的压力、应变和振动响应进行了同步测试。比较了不同模型的破坏模式和动态响应,分析了泡沫土工聚合物回填参数对消波和能量吸收效率的影响。结果表明,在高应变率和动态加载条件下,泡沫土工聚合物通过连续压缩变形吸收和消散了冲击能量,使衬垫结构的应变降低了 52%,压力衰减率提高了 28%。此外,泡沫土工聚合物回填减少了结构振动和衬垫变形,与 CLS 相比,FGCS 结构的位移减少了 35%,加速度减少了 70%。FGCS 模型的泡沫土工聚合物回填材料更厚、密度更低、孔隙更多和孔隙率更高,在动态冲击下具有更好的压缩和能量吸收能力,提高了应力波衰减效率。通过分析应力波的传播和多孔介质的压缩特性,得出结论:FGCS-ρ-579 的应力传递比比 CLS 低 77%,传递的波能低 90%。该研究结果为优化地下复合结构夹层参数提供了科学依据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Defence Technology
Defence Technology Engineering-Computational Mechanics
CiteScore
7.50
自引率
7.80%
发文量
1248
审稿时长
22 weeks
期刊介绍: Defence Technology, sponsored by China Ordnance Society, is published quarterly and aims to become one of the well-known comprehensive journals in the world, which reports on the breakthroughs in defence technology by building up an international academic exchange platform for the defence technology related research. It publishes original research papers having direct bearing on defence, with a balanced coverage on analytical, experimental, numerical simulation and applied investigations. It covers various disciplines of science, technology and engineering.
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