盐冻融-荷载耦合作用下高性能混凝土试验及损伤模型研究

通过对掺加粉煤灰、硅粉及矿渣的高性能混凝土在盐冻融-荷载耦合作用下的试验研究,提出了考虑多因素作用下混凝土疲劳损伤度模型。试验结果表明:荷载显著的影响盐冻融循环次数和破坏形态;不同应力状态下混凝土试件的质量变化率无明显差别。质量损失率是反映盐冻融-荷载耦合循环次数的主要参数,而相对动弹性模量是反映荷载影响的主要参数。提出的盐冻融-荷载耦合作用下的混凝土损伤度模型,可以反映出混凝土所受应力、相对动弹性模量、混凝土抗拉强度及循环次数对损伤度的影响。当耦合影响因子β接近零时,混凝土趋近疲劳寿命;所预测的损伤特性与实际损伤情况符合较好。

动荷载-水-冻融共同作用下混凝土宏观裂缝扩展与演变的研究进展

混凝土是土木工程建设的重要材料。由于设计、施工、服役环境及其材料自身等原因,混凝土在投入使用时就存在部分非结构裂缝。工程实践发现,在长期动荷载作用下,混凝土裂缝会在长度、宽度和深度方向出现扩展和演变,而动荷载和环境共同作用将会加快裂缝的扩展,加速混凝土材料的劣化,导致混凝土力学和耐久性能降低,严重影响其结构安全。动荷载的长期作用将导致混凝土裂缝尖端附近的应力场和位移场出现复杂的变化,从而引起应力集中和应变能释放,当裂缝尖端应力强度因子大于材料断裂韧度时,裂缝将发生失稳扩展。动荷载对裂缝中的水产生动水压,动水压作用下水对裂缝内壁产生反复冲刷和溶蚀,导致裂缝内壁的集料和水化产物流失,从而加速了裂缝的扩展。低温冻融过程中,水在裂缝内壁反复结冰溶解,在裂缝内产生了冻胀应力,而动荷载作用使裂缝发生的体积变化增大了冻胀应力,同时冻融对裂缝内壁的集料和水化产物产生了剥蚀作用,加速了混凝土裂缝的扩展。动载-水-冻融共同作用对混凝土宏观裂缝的扩展演化更加复杂,目前尚无系统研究。本文归纳了目前对混凝土宏观裂缝在动载-水-冻融共同作用下扩展演变研究的最新进展,梳理了动荷载作用下水和冻融对裂缝扩展演化的加速机制、裂缝扩展与演化的计算方法和有效预测模型,并提出了该研究方向需要进一步解决的问题,以期为进一步掌握混凝土结构的长期服役性能、完善混凝土结构损伤理论及养护维修技术奠定基础。

冻融循环单轴压缩下不等长交叉裂隙砂岩变形破坏特征研究

为了探究冻融-荷载作用下含交叉裂隙砂岩力学特性及破坏机制,本文对不同冻融次数下交叉裂隙试样开展了单轴压缩试验,分析了冻融循环下交叉裂隙试样的物理性质劣化规律以及宏观力学特性,并基于PFC2D离散元软件采用水颗粒膨胀法对冻融循环全过程进行模拟,结合数值模拟与试验结果,进一步探究了冻融作用下试样的宏细观损伤机理.结果表明:冻融循环作用会使岩石的物理力学性质发生劣化,降低岩石的储能能力,与未冻融试样相比,冻融90次试样峰值强度、弹性模量、总能分别下降了32.1%、29.3%、56.77%;随着冻融循环次数的增加,试样的破坏模式由单纯剪切破坏逐步向张拉-剪切破坏过渡;试样均于主裂隙尖端处起裂,但扩展方向不同,未冻融试样沿着主裂隙45°方向扩展,而冻融后试样沿裂隙两端垂直扩展.

Experimental study of dynamic resilient modulus of subgrade soils under coupling of freeze–thaw cycles and dynamic load

Although the dynamic properties of subgrade soils in seasonally frozen areas have already been studied, few researchers have considered the influence of shallow groundwater during the freeze–thaw(F–T) cycles. So a multifunctional F–T cycle system was developed to imitate the groundwater recharge in the subgrade during the freezing process and a large number of dynamic triaxial experiments were conducted after the F–T cycles. Some significant factors including the F–T cycle number, compaction degree, confining pressure, cyclic deviator stress, loading frequency, and water content were investigated for the resilient modulus of soils. The experimental results indicated that the dynamic resilient modulus of the subgrade was negatively correlated with the cyclic deviator stress, F–T cycle number, and initial water content, whereas the degree of compaction, confining pressure, and loading frequency could enhance the resilient modulus. Furthermore, a modified model considering the F–T cycle number and stress state was established to predict the dynamic resilient modulus. The calculated results of this modified model were very close to the experimental results. Consequently, calculation of the resilient modulus for F–T cycles considering the dynamic load was appropriate. This study provides reference for research focusing on F–T cycles with groundwater supply and the dynamic resilient moduli of subgrade soils in seasonally frozen areas.