通过离散元素法探索有无防潮层 (DPC) 防水卷材的加固墙体的循环行为

IF 2.7 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Infrastructures Pub Date : 2024-01-06 DOI:10.3390/infrastructures9010011
B. Pulatsu, R. Wilson, José V. Lemos, N. Mojsilović
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引用次数: 0

摘要

非加固砌体(URM)墙是大多数现有建筑物中常见的承重结构构件,由砌体单元(砖块)和砂浆接缝组成。在受到不同因素(如预压缩荷载和边界条件等)的影响下,它们在承受压缩-剪切组合荷载时表现出高度非线性和复杂的行为,这使得预测其结构响应具有挑战性。为此,本研究提供了一种基于离散元素法(DEM)的非连续建模策略,用于研究有无防潮层(DPC)膜的 URM 面板在不同垂直压力下的平面内循环响应。所采用的建模策略将 URM 墙体表示为一组离散的刚性砌块系统,通过接触点沿其边界相互作用。在已实施的基于非连续性的建模框架内,采用了一个新颖的接触构成模型,以解决单元-砂浆界面的弹性软化应力-位移行为以及拉伸-压缩状态下的相关刚度退化问题。建议的建模策略通过比较最近的实验活动进行了验证,在实验活动中获得了有关几何特征、材料特性和加载历史的重要数据。结果表明,虽然所提出的计算建模策略能够准确捕捉无 DPC 膜的 URM 墙体的滞后响应,但可能会低估有 DPC 膜的 URM 墙体的承载能力。
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Exploring the Cyclic Behaviour of URM Walls with and without Damp-Proof Course (DPC) Membranes through Discrete Element Method
Unreinforced masonry (URM) walls are common load-bearing structural elements in most existing buildings, consisting of masonry units (bricks) and mortar joints. They indicate a highly nonlinear and complex behaviour when subjected to combined compression–shear loading influenced by different factors, such as pre-compression load and boundary conditions, among many others, which makes predicting their structural response challenging. To this end, the present study offers a discontinuum-based modelling strategy based on the discrete element method (DEM) to investigate the in-plane cyclic response of URM panels under different vertical pressures with and without a damp-proof course (DPC) membrane. The adopted modelling strategy represents URM walls as a group of discrete rigid block systems interacting along their boundaries through the contact points. A novel contact constitutive model addressing the elasto-softening stress–displacement behaviour of unit–mortar interfaces and the associated stiffness degradation in tension–compression regimes is adopted within the implemented discontinuum-based modelling framework. The proposed modelling strategy is validated by comparing a recent experimental campaign where the essential data regarding geometrical features, material properties and loading histories are obtained. The results show that while the proposed computational modelling strategy can accurately capture the hysteric response of URM walls without a DPC membrane, it may underestimate the load-carrying capacity of URM walls with a DPC membrane.
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来源期刊
Infrastructures
Infrastructures Engineering-Building and Construction
CiteScore
5.20
自引率
7.70%
发文量
145
审稿时长
11 weeks
期刊最新文献
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