A novel method for determining strain rate of concrete-like materials in SHPB experiment
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摘要: 由于混凝土类材料在SHPB实验中很难实现恒应变率加载,为了确定非恒应变率加载下的实验数据所对应的应变率,本文中针对不同强度(C20,C45,C70)和不同钢纤维含量(0%,0.75%,1.50%,4.50%)的混凝土进行了SHPB实验。对实验得到的30组恒应变率加载下的数据进行了分析总结,结果表明:实验数据所对应的恒应变率与全段平均应变率之间存在一定的比值关系,从而混凝土类材料SHPB实验数据所对应的应变率可以采用全段平均应变率的1.38倍来表征。通过对比非恒应变率加载和恒应变率加载下得到的应力应变曲线,验证了该确定应变率方法的合理性,并指出较短恒应变率加载下实验数据对应的应变率直接采用短平台段对应的应变率来表征是不合理的。Abstract: In this paper, we performed SHPB experiments on concrete-like materials with different strengths (C20, C45, C70) and different steel fiber contents (0%, 0.75%, 1.50%, 4.50%) and analyzed the data drawn. The results showed that the constant strain rate corresponding to the experimental data was co-related with the whole-stage average strain rate to a certain degree and therefore the former could be determined by the 1.38 times of the latter. This method was verified as rational by the comparative analysis of the experimental data of non-constant strain rate with the experimental data of constant strain rate. It was also found that, at the constant strain rate in a relatively short loading time, it is unreasonable to characterize the strain rate corresponding to the experimental data using the constant strain rate corresponding to the short platform stage. In this case, the method proposed in this paper offers a good choice.
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Key words:
- concrete /
- SHPB /
- strain rate effect /
- dynamic mechanical behavior
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图 2 不同强度和不同钢纤维含量的混凝土材料的典型波形
Figure 2. Typical waveforms for concrete-like materials with different strengths and different fiber contents
图 4 相近恒应变率加载下的应力应变曲线对比
Figure 4. Comparison of stress-strain curves under similar constant strain rate loading
图 6 恒应变率与半段(全段)平均应变率之比
Figure 6. Constant strain rate versus average strain rate of half and whole-stage
图 7 非恒应变率加载与相近恒应变率加载下的应力应变曲线对比
Figure 7. Comparison of stress-strain curves under non-constant strain rate loading (NCSRL) and similar constant strain rate loading (CSRL)
图 9 C45混凝土在不同加载情况下的应力应变曲线对比
Figure 9. Comparison of stress-strain curves of C45 concrete under different loading conditions
表 1 不同强度混凝土试件配合比
Table 1. Mixture ratio of concrete specimen with different strengths
混凝土 石子/(kg·m−3) 砂/(kg·m−3) 水/(kg·m−3) 水泥/(kg·m−3) 水灰比 外加剂/(kg·m−3) 28 d 抗压强度/MPa C20 1 100 725 205 350 0.586 7.5 23.05 C45 950 900 173 500 0.346 12.5 46.20 C70 1 150 600 150 600 0.250 16.0 70.06 
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表 2 不同钢纤维含量混凝土试件配合比
Table 2. Mixture ratio of steel fiber reinforced concrete specimen
混凝土 钢纤维体积含量/% 钢纤维/(kg·m−3) 石子/(kg·m−3) 砂/(kg·m−3) 水/(kg·m−3) 水泥/(kg·m−3) 水胶比 外加剂/(kg·m−3) C40 0 0 1 090 698 158 391 0.38 8.1 0.75 58.5 1 056 676 182 450 0.38 8.1 1.50 117.0 1 004 645 204 505 0.38 8.1 4.50 351.0 726 470 280 693 0.38 8.1
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表 3 恒应变率加载下的实验数据
Table 3. Experimental data at constant strain rate loading
实验 试件 恒应变率/s−1 半段平均应变率/s−1 全段平均应变率/s−1 η1 η2 1 C20 32.6 24.6 24.5 1.325 1.331 2 C20 44.2 34.4 31.9 1.285 1.386 3 C20 50.4 31.0 37.9 1.613 1.319 4 C20 51.2 28.6 45.1 2.182 1.384 5 C20 65.3 41.0 46.8 1.593 1.395 6 C20 77.2 55.1 54.9 1.401 1.406 7 C20 81.2 57.1 57.0 1.422 1.424 8 C45 37.3 23.9 25.8 1.561 1.446 9 C45 62.5 39.5 45.2 1.582 1.383 10 C45 70.3 51.4 51.5 1.368 1.365 11 C45 77.3 42.2 56.2 1.832 1.375 12 C45 80.7 60.1 62.5 1.343 1.291 13 C70 45.4 32.8 33.3 1.384 1.363 14 C70 53.6 38.7 41.8 1.385 1.282 15 C70 57.7 42.7 42.4 1.328 1.337 16 C70 69.4 56.1 50.2 1.237 1.382 17 C70 77.4 55.4 51.7 1.397 1.503 18 C70 87.1 60.1 65.6 1.449 1.328 19 C40 59.2 43.0 40.8 1.377 1.451 20 C40 66.8 33.0 49.5 2.024 1.349 21 C40 82.1 54.3 55.6 1.512 1.477 22 C40 (0.75%) 62.0 31.3 45.0 1.981 1.378 23 C40 (0.75%) 80.7 64.8 59.2 1.245 1.363 24 C40 (0.75%) 81.2 51.3 59.4 1.583 1.367 25 C40 (1.50%) 59.1 43.4 44.6 1.362 1.325 26 C40 (1.50%) 65.4 51.8 48.2 1.262 1.357 27 C40 (1.50%) 81.2 46.0 58.6 1.765 1.386 28 C40 (4.50%) 34.5 26.2 24.6 1.317 1.402 29 C40 (4.50%) 82.3 62.1 60.1 1.325 1.369 30 C40 (4.50%) 105.3 62.6 78.9 1.682 1.334
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