第 46 卷          高    矗，等： 剪切增强和应变率效应对混凝土类材料状态方程的影响                              第 2 期

               [30]   YANKELEVSKY  D  Z,  KARINSKI  Y  S,  ZHUTOVSKY  S,  et  al.  High-pressure  uniaxial  confined  compression  tests  of
                    mortars [J]. Construction and Building Materials, 2018, 165: 523–532. DOI: 10.1016/j.conbuildmat.2018.01.057.
               [31]   WANG Z H, WEN H M, ZHENG H, et al. Dynamic increase factors of concrete-like materials at very high strain rates [J].
                    Construction and Building Materials, 2022, 345: 128270. DOI: 10.1016/j.conbuildmat.2022.128270.
               [32]   KOHEES  M,  SANJAYAN  J,  RAJEEV  P.  Stress-strain  relationship  of  cement  mortar  under  triaxial  compression  [J].
                    Construction and Building Materials, 2019, 220: 456–463. DOI: 10.1016/j.conbuildmat.2019.05.146.
               [33]   FENG M Y, WANG Z, WU L C. Experimental study on high-strength concrete, ultrahigh-strength concrete and corresponding
                    mortar under triaxial compression [J]. Arabian Journal for Science and Engineering, 2021, 46(11): 11179–11194. DOI: 10.
                    1007/s13369-021-05663-y.
               [34]   GEBBEKEN N, GREULICH S, PIETZSCH A. Equation of state data for concrete determined by full-scale experiments and
                    flyer-plate-impact tests [C] // European Conference on Computational Mechanics. Cracow Poland, 2001.
               [35]   RIEDEL  W,  WICKLEIN  M,  THOMA  K.  Shock  properties  of  conventional  and  high  strength  concrete:  experimental  and
                    mesomechanical analysis [J]. International Journal of Impact Engineering, 2008, 35(3): 155–171. DOI: 10.1016/j.ijimpeng.
                    2007.02.001.
               [36]   XU  H,  WEN  H  M.  Semi-empirical  equations  for  the  dynamic  strength  enhancement  of  concrete-like  materials  [J].
                    International Journal of Impact Engineering, 2013, 60: 76–81. DOI: 10.1016/j.Ijimpeng.2013.04.005.
               [37]   HUANG X P, KONG X Z, CHEN Z Y, et al. A computational constitutive model for rock in hydrocode [J]. International
                    Journal of Impact Engineering, 2020, 145: 103687. DOI: 10.1016/j.ijimpeng.2020.103687.
               [38]   YANG  S  B,  KONG  X  Z,  WU  H,  et  al.  Constitutive  modelling  of  UHPCC  material  under  impact  and  blast  loadings  [J].
                    International Journal of Impact Engineering, 2021, 153: 103860. DOI: 10.1016/j.ijimpeng.2021.103860.
               [39]   XU S L, WU P, LI Q H, et al. Experimental investigation and numerical simulation on the blast resistance of reactive powder
                    concrete subjected to blast by embedded explosive [J]. Cement and Concrete Composites, 2021, 119: 103989. DOI: 10.1016/
                    j.cemconcomp.2021.103989.
               [40]   YUAN P C, XU S C, LIU J, et al. Experimental and numerical study of blast resistance of geopolymer based high performance
                    concrete sandwich walls incorporated with metallic tube core [J]. Engineering Structures, 2023, 278: 115505. DOI: 10.1016/j.
                    engstruct.2022.115505.
               [41]   ZHOU L, WEN H M. A new dynamic plasticity and failure model for metals [J]. Metals, 2019, 9(8): 905. DOI: 10.3390/
                    met9080905.
               [42]   LACINA D, NEEL C, DATTELBAUM D. Shock response of poly[methyl methacrylate] (PMMA) measured with embedded
                    electromagnetic gauges [J]. Journal of Applied Physics, 2018, 123(18): 185901. DOI: 10.1063/1.5023230.
               [43]   TANG J J, KONG X Z, FANG Q, et al. An efficient three-dimensional damage-based nonlocal model for dynamic tensile
                    failure in concrete [J]. International Journal of Impact Engineering, 2021, 156: 103965. DOI: 10.1016/j.ijimpeng.2021.103965.
               [44]   KONG X Z, FANG Q, WU H, et al. A comparison of strain-rate enhancement approaches for concrete material subjected to
                    high strain-rate [J]. International Journal of Protective Structures, 2017, 8(2): 155–176. DOI: 10.1177/2041419617698320.
               [45]   KARINSKI Y S, ZHUTOVSKY S, FELDGUN V R, et al. An experimental study on the equation of state of cementitious
                    materials using confined compression tests [J]. Key Engineering Materials, 2016, 711: 830–836. DOI: 10.4028/www.scientific.
                    net/KEM.711.830.
               [46]   MEYERS M A, MURR L E. Shock waves and high-strain-rate phenomena in metals: concepts and applications [M]. New
                    York: Plenum Press, 1981: 417.
               [47]   经福谦. 实验物态方程导引 [M]. 2   版. 北京: 科学出版社, 1999: 222–227.
               [48]   张江跃, 谭华, 虞吉林. 双屈服法测定      93W  合金的屈服强度 [J]. 高压物理学报, 1997, 11(4): 254–259. DOI: 10.11858/
                    gywlxb.1997.04.004.
                    ZHANG J Y, TAN H, YU J L. Determination of the yield strength of 93W alloys by using AC techniques [J]. Chinese Journal
                    of High Pressure Physics, 1997, 11(4): 254–259. DOI: 10.11858/gywlxb.1997.04.004.
               [49]   HAO H, HAO Y F, LI Z X. Numerical quantification of factors influencing high-speed impact tests of concrete material [M]//
                    HAO H, LI Z X. Advances in Protective Structures Research. London: CRC Press, 2012: 97–130. DOI: 10.1201/b12768-5.
               [50]   LIU F, LI Q M. Strain-rate effect of polymers and correction methodology in a SHPB test [J]. International Journal of Impact
                    Engineering, 2022, 161: 104109. DOI: 10.1016/j.ijimpeng.2021.104109.
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