基于多重界面演变的持载损伤再生混凝土介质传输机理研究

Multiple interfacial properties are one of critical factors to determine the mechanical performance and durability of recycled aggregate concrete (RAC). The mechanical loading can cause the variation of matrix porosity and multiple interfaces of RAC, which significantly affects the properties of mass transport. However, the research on the correlative mechanism between the evolution of multiple interfaces and transport properties of RAC damaged by sustained loading has been still incomplete so far. The project investigates the character and mechanism of mass transport in the unsaturated RAC subjected to sustained loading by comparison of indoor accelerated test and in-situ long term exposure test, and the effect of recycled concrete aggregates preprocessed by the silane impregnation and nano-modification will be considered. The influential mechanism of multiple interface strengthening and microstructure damage evolution on mass transport of RAC under sustained loads will be explored. The theoretical model for mass transport speed in RAC based on the microstructure damage will be developed. The objective of the project is to reveal the correlative mechanism among sustained load-induced damage, interface strengthening and mass transport in RAC. Based on the theory of damage mechanics porous mass transport, the constitutive model of mass transport in RAC considering the effects of sustained load-induced damage and interfacial strengthening will be established. A numerical method for calculating the spatial and temporal distribution of water and chloride ion content in RAC under sustained load will be proposed. The research results of this project will be helpful to enrich the basic theory of durability of RAC and provide theoretical support for its service life prediction under the combined action of loads and chloride erosion environment.

再生混凝土多重界面性能是决定其力学性能及耐久性的关键因素。荷载作用会引起混凝土基体孔隙率及多重界面微结构的变化，显著影响再生混凝土介质传输性能，但目前针对持载损伤后多重界面演变与传输性能之间的关联机制研究还不完善。本项目通过室内短期加速与实海长期暴露对比试验，考虑再生骨料硅烷浸渍及纳米改性影响，研究持载下非饱和再生混凝土介质传输特性及机制；探究持载下再生混凝土多重界面微结构损伤演变对介质传输性能的影响机理，建立基于微结构损伤的再生混凝土介质传输速度模型，揭示再生混凝土持载损伤—界面强化—介质传输之间的内在关联机制；基于损伤力学和多孔介质传输理论，建立考虑持载损伤和界面强化影响的再生混凝土介质传输本构模型，提出持载下再生混凝土水分及氯离子含量时空分布的数值计算方法。研究成果将丰富再生混凝土耐久性基础理论，为荷载与氯盐侵蚀环境下再生混凝土服役寿命预测提供理论支持。

再生骨料初始缺陷损伤和薄弱的多重界面结构是决定再生混凝土介质传输特性的关键。实际服役阶段，荷载与环境因素双重作用促进了再生混凝土多重界面微结构的劣化，加速了水分及氯离子等有害介质侵入。为此，科学地揭示持载损伤改性再生混凝土介质传输规律，是从根本上解决实际使用环境下再生混凝土耐久性的关键。本项目基于再生混凝土持载损伤—介质传输—界面强化的研究思路，系统研究了持载损伤非饱和再生混凝土介质传输机理，探究了持载下再生混凝土多重界面微结构损伤演变规律及对介质传输性能的影响机理。本项目开展的具体研究如下：.（1）系统研究了轴向拉/压持载下非饱和再生混凝土介质传输规律，分析了再生骨料取代率、应力水平及干湿循环等因素对再生混凝土毛细吸水和氯离子传输性能的影响，揭示了再生混凝土持载损伤与介质传输性能的关联机制。.（2）研究了再生骨料硅烷浸渍及纳米改性强化对混凝土多重界面微结构性能提升机制，分析了持载与干湿循环耦合作用下改性再生混凝土氯盐侵蚀行为，揭示了再生混凝土界面强化对不同持载应力水平下介质传输的影响机理。.（3）对比分析了硅烷浸渍再生粗骨料和直接内掺纳米材料改性再生混凝土的介质传输性能，揭示了再生混凝土界面强化对水分与氯离子含量时空分布规律的影响机理。.（4）构建了基于多相结构的持载损伤再生混凝土介质传输本构模型，实现了持压荷载损伤再生混凝土水分和氯离子传输的细观仿真分析，提出了持载下再生混凝土介质含量时空分布的数值计算方法。. 综上成果，本研究丰富了氯盐侵蚀环境下再生混凝土耐久性基础理论，也为荷载与氯盐侵蚀环境下再生混凝土服役寿命预测提供理论支持，对再生混凝土实际应用具有重要的理论及科学意义。

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