沥青混凝土界面相互作用的纳米力学建模:牵引和剪切破坏研究

IF 1 Q4 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS Journal of Multiscale Modelling Pub Date : 2019-05-08 DOI:10.1142/S1756973718410044
Yang Lu, Linbing Wang
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引用次数: 5

摘要

外荷载作用下沥青混凝土的界面粘结强度对其性能的影响至关重要。为了准确预测沥青混凝土的性能,需要对载荷传递机制进行透彻的理解,将纳米尺度的界面细节与宏观尺度的特性联系起来。本研究提出了一种多尺度的界面行为建模分析方法,通过原子尺度的相互作用来评估材料的性能,强调了在各种加载模式下复杂的剪切和分离机制。基于沥青与骨料紧密结合界面的多尺度实验表征,建立了具有代表性的模型体系。通过界面载荷传递和破坏研究,探讨了拉伸和压缩对剪切模式分离的影响。对各加载模式下的黏结区模型参数,如峰值牵引力和分离能进行了评估。采用不同的边界条件,得到了代表体元(RVE)及其与连续体能级性质的联系。结果表明,根据不同的加载模式,纳米级界面体系的破坏可能发生在沥青相内部或界面处。这些结果为连续统长度尺度的微观力学模型奠定了基础,该模型可用于确定包含界面现象的大块材料响应。本文的研究结果与以往的研究结果一致,并扩展了对沥青混凝土界面分子结构与组合剪切分离破坏特性之间关系的理解。
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Nanomechanics Modeling of Interface Interactions in Asphalt Concrete: Traction and Shearing Failure Study
The interface bonding strength is critical for asphalt concrete performance under external load applications. A thorough understanding of the load transfer mechanism bridging the nanoscale interfacial details and the macroscale properties is required to accurately predict the performance of asphalt concrete. This research presents a multiscale analysis procedure for the modeling of interface behaviors, in which material properties are evaluated by atomic scale interactions, emphasizing the complex shearing and separation mechanisms under various loading modes. The representative model system was established based on multiscale experimental characterization of the tight-bonding interface between asphalt and aggregate. Interfacial load transfer and failure studies were conducted for investigating the effect of tension and compression on shearing mode separation. The cohesive zone model parameters, such as peak traction and energy of separation were evaluated for each loading mode. Different boundary conditions were applied to obtain the representative volume element (RVE) and connection to continuum level properties. Results indicated that depending on the various loading modes, the failure of the nanoscale interface system may occur within the asphalt phase or at the interface. These results set the basis for continuum length-scale micromechanical models which may be used to determine the bulk material response, incorporating interfacial phenomena. The findings presented in this paper are consistent with observations reported in previous studies and expand on the understanding of the relationship between molecular structures and combined shearing separation failure properties of asphalt concrete interfaces.
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来源期刊
Journal of Multiscale Modelling
Journal of Multiscale Modelling MATHEMATICS, INTERDISCIPLINARY APPLICATIONS-
CiteScore
2.70
自引率
0.00%
发文量
9
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