-
应用霍普金森压杆(SHPB)实验装置,通过改变透射杆为钢杆和铝杆,对立方体PMMA试样和两种梯台PMMA试样进行动态压缩实验。利用高速摄影记录试样的压缩过程,并结合力位移曲线分析试样的破碎过程,探讨了冲击载荷作用下PMMA试样变形和广义扩散阻力的演化。结果表明:试样的破坏模式主要为接触端局部产生失效阵面,然后失效阵面向试样内部扩展。立方体试样在低速冲击下,失效阵面优先在透射端产生;在高速冲击下,阵面在入射端先产生。通过改变试样形状和透射杆材质后,阵面的产生存在明显的弛豫现象,并且失效阵面仅在入射端产生。梯台试样破碎前的压缩变形是非均匀的,试样内部应力状态和变形状态随着截面增加逐渐变小,并且呈线性扩散分布。通过应变分布结合剪切激活扩散方程,得到失效阵面扩散过程中的广义扩散阻力分布情况;失效阵面前后广义扩散阻力先增加后减小,阻力的幅值与局部应变能的释放有关。Dynamic compression experiments were carried out on cubic PMMA specimens and two kinds of trapezoid PMMA specimens by changing the transmission bars to steel and aluminum bar with the Loading device of split Hopkinson pressure bar (SHPB). The compression process of PMMA specimens was recorded by high-speed photography, and the breakage process of PMMA specimens was analyzed based on the force displacement curves and high-speed images. The evolution of deformation and diffusion resistance of PMMA specimens under impact loading was discussed. The results show that the failure of the sample is mainly caused by the partial failure front at the contact end, and then the failure front propagates to the inside of the sample and leads to the breakage of the sample. The failure front of cubic samples is preferentially generated at the transmission end under low speed impact and generated at the incident end under the higher speed impact. After changing the shape of the specimen and material of the transmission bar, the relaxation phenomenon is obvious, and the failure front only occurs at the incident end. The compressive deformation of the trapezoid sample before breakage is non-uniform, and the stress and strain in the sample gradually decrease with the increase of the cross section, and show a linear diffusion distribution. The strain distribution and shear activation diffusion equation were used to obtain the generalized diffusion resistance distribution of the failure front. The generalized diffusion resistance increases first in front of the failure front and decreases after the failure front and the amplitude of the generalized diffusion resistance is related to the release of local strain energy.
-
Keywords:
- Impact dynamics /
- stress-state adjustment /
- PMMA /
- stress diffusion
-
[1] Huang J, Xu S, Hu S 2013 Rock Mech. Rock Eng. 471727.
[2] Jiang H B, Xu S L, Shan J F, Wang D R, Liu Y G, Zhou L J, Wang P F 2019 Powder Technol. 353 359
[3] Shan J, Xu S, Liu Y G, Zhou L J, Wang P F 2018 Powder Technol. 330 317
[4] Potapov A V, Campbell C S 1997 Powder Technol. 93 13
[5] Rasorenov S V, Kanel G I, Fortov V E, Abasehov M M 1991 Int. J. High Pres. Res. 6 225
[6] Espinosa H D 1998 Mech. Mater. 29 219
[7] Anderson Jr C E, Bigger R P, Weiss C E 2014 Int. J. Appl. Glass Sci. 5 374
[8] Huang J Y, Li Y, Liu Q C, Zhou X M, Liu L W, Liu C L, Zhu H M, Luo S N 2015 Phys. Rev. B 92 144101
[9] Sheikh M Z, Atif M, Li Y L, Zhou F H, Raza M A, Dar U A, Gao G Z, Wang Y M 2021 Constr. Build. Mater. 288 123088
[10] 宋一平,苗春贺,单俊芳,王鹏飞,徐松林2022爆炸与冲击:1-15[2022-04-016]
Song Y P, Miao C H, Shan J F, Wang P F, Xu S L 2022 Explosion and Shock Waves 1-15[2022-04-16](in Chinese)
[11] Miao C H, Xu S L, Song Y P, Xie Y S, Yuan L Z, Wang P F 2022 Powder Technol. 397 117081
[12] Liu D, Shen L, Guillard F, Einav I 2016 Int. J. Impact Eng. 93 222
[13] Xing H Z, Zhang Q B, Braithwaite C H, Pan B, Zhao J 2017 Rock Mech. Rock Eng. 50 1611
[14] Zhou L, Xu S, Shan J, Liu Y, Wang P 2018 Mech. Mater. 123 1
[15] Grady D. 2017 Phys. Shock Impact, Vol.1 (London: IOP Publishing) pp2-57—2-68
[16] Mott N F 1947 Proc. R. Soc. Lon. Ser.-A 189 300.
[17] Feng R 2000 J. Appl. Phys. 87 1693
计量
- 文章访问数: 2390
- PDF下载量: 0
- 被引次数: 0
下载:
