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摘要: 电磁霍普金森(E-Hopkinson)杆实验技术是利用电磁驱动的方式替代了传统霍普金森杆中子弹撞击加载杆来产生应力波, 是电磁驱动技术与霍普金森杆实验技术相结合而发展起来的一种新的动态加载技术. 本文综述了E-Hopkinson杆实验技术在单轴单向/双向及动态双轴对称压缩/拉伸、复合材料的层间断裂、金属动态包辛格效应等领域的应用现状, 涵盖了实验研究, 理论分析及数值模拟等, 最后对该实验技术未来发展方向进行了展望.Abstract: The e-Hopkinson bar test technology is a new dynamic loading technology developed by combining the electromagnetic drive technology with the Hopkinson bar test technology, which replaces the traditional Hopkinson bar with the bullet hitting the loading bar to generate stress waves. In this paper, the application status of e-Hopkinson bar test technology in uniaxial unidirectional/biaxial and dynamic biaxial symmetric compression/tension, interlaminar fracture of composites, dynamic bauschinger effect and other fields are reviewed, including experimental research, theoretical analysis and numerical simulation. Finally, the future development direction of e-Hopkinson bar test technology is prospected.
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图 1 Kolsky提出的实验装置示意图(Kolsky 1949)
图 2 用于分离式Hopkinson压杆装置的电磁驱动装置原理图(Liu et al. 2014)
图 3 微型双脉冲串联加载SHPB实验装置原理图(Huang et al. 2019)
图 4 基于电磁加载的拉压杆集成装置原理图(Chen et al. 2014)
图 5 单轴单向E-Hopkinson杆加载装置原理图(Nie et al. 2018a, 2018b)
图 17 (a)单向压缩实验的原始波形及(b)试样两端应力、应变率及应力平衡系数, R(t)-时间曲线(江斌等 2020)
图 18 (a)动态双向压缩实验的原始波形及(b)试样两端应力、应变率及应力平衡系数, R(t)-时间曲线(江斌 等 2020)
图 21 (a)动态DCB实验入射波与反射波, (b)试样加载过程中I型和II型能量释放率变化曲线(Liu et al. 2018)
图 28 Ohtake等(1999)提出的三种十字型试样的夹持臂出现断裂失效而提出了三种解决方案. (a)切除部分区域, (b)减小测试区厚度, (c)试样臂上加工狭缝
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