Finite element modeling and experimental validation of brick-and-mortar structures with mesoscale interlocking interfaces

IF 3.5 3区工程技术 Q1 MATHEMATICS, APPLIED

Finite Elements in Analysis and Design Pub Date : 2025-05-19 DOI:10.1016/j.finel.2025.104370

Manuel J. Carvajal Loaiza, Maria I. Vallejo Ciro, Vanessa Restrepo

{"title":"Finite element modeling and experimental validation of brick-and-mortar structures with mesoscale interlocking interfaces","authors":"Manuel J. Carvajal Loaiza, Maria I. Vallejo Ciro, Vanessa Restrepo","doi":"10.1016/j.finel.2025.104370","DOIUrl":null,"url":null,"abstract":"<div><div>Bioinspired composite materials, such as nacre, achieve exceptional mechanical performance through the strategic arrangement of stiff and soft components. Inspired by this natural architecture, this study presents a novel finite element modeling framework for simulating staggered composites with finite-thickness interfaces. Combining continuum and cohesive elements, the model accurately captures tension-compression asymmetry and interface degradation, as validated by mechanical characterization of a mechanical interlocking fastener under tension, compression, and shear loading. The methodology was applied to staggered brick-and-mortar structures, with numerical simulations replicating 3-point bending experiments and achieving less than 3 % deviation in predictions of maximum load and displacement. A comprehensive parametric analysis identified key design parameters, including interface tensile strength, brick length-to-thickness ratio, and overlap, that govern structural performance. Additionally, the framework was extended to incorporate potential-based cohesive elements for modeling non-linear interface behavior, as demonstrated with hook-and-loop fasteners. Experimental validation revealed that hook-and-loop interfaces significantly enhanced energy dissipation, increasing from 189 mJ to 508 mJ compared to mushroom fastener interfaces. These findings underscore the versatility of the proposed modeling approach in predicting real-world behavior and optimizing composite architectures. This work provides a robust tool for the design of bioinspired materials with tailored mechanical properties, suitable for applications requiring energy absorption, durability, and strength.</div></div>","PeriodicalId":56133,"journal":{"name":"Finite Elements in Analysis and Design","volume":"249 ","pages":"Article 104370"},"PeriodicalIF":3.5000,"publicationDate":"2025-05-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Finite Elements in Analysis and Design","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0168874X25000599","RegionNum":3,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS, APPLIED","Score":null,"Total":0}

引用次数: 0

Abstract

Bioinspired composite materials, such as nacre, achieve exceptional mechanical performance through the strategic arrangement of stiff and soft components. Inspired by this natural architecture, this study presents a novel finite element modeling framework for simulating staggered composites with finite-thickness interfaces. Combining continuum and cohesive elements, the model accurately captures tension-compression asymmetry and interface degradation, as validated by mechanical characterization of a mechanical interlocking fastener under tension, compression, and shear loading. The methodology was applied to staggered brick-and-mortar structures, with numerical simulations replicating 3-point bending experiments and achieving less than 3 % deviation in predictions of maximum load and displacement. A comprehensive parametric analysis identified key design parameters, including interface tensile strength, brick length-to-thickness ratio, and overlap, that govern structural performance. Additionally, the framework was extended to incorporate potential-based cohesive elements for modeling non-linear interface behavior, as demonstrated with hook-and-loop fasteners. Experimental validation revealed that hook-and-loop interfaces significantly enhanced energy dissipation, increasing from 189 mJ to 508 mJ compared to mushroom fastener interfaces. These findings underscore the versatility of the proposed modeling approach in predicting real-world behavior and optimizing composite architectures. This work provides a robust tool for the design of bioinspired materials with tailored mechanical properties, suitable for applications requiring energy absorption, durability, and strength.

查看原文本刊更多论文

具有中尺度联锁界面的砖混结构有限元建模与试验验证

仿生复合材料，如珠质，通过硬和软组件的策略性安排实现卓越的机械性能。受这种自然结构的启发，本研究提出了一种新的有限元建模框架，用于模拟具有有限厚度界面的交错复合材料。结合连续体和内聚元素，该模型准确捕获了拉压不对称和界面退化，并通过拉伸、压缩和剪切载荷下机械联锁紧固件的力学特性进行了验证。将该方法应用于交错的砖混结构，通过数值模拟复制三点弯曲实验，在最大载荷和位移的预测中实现了小于3%的偏差。综合参数分析确定了控制结构性能的关键设计参数，包括界面抗拉强度、砖长厚比和重叠。此外，该框架被扩展为包含基于潜在的内聚元素，用于建模非线性接口行为，如钩环紧固件所示。实验验证表明，与蘑菇扣界面相比，钩环界面显著提高了能量耗散，从189 mJ增加到508 mJ。这些发现强调了所提出的建模方法在预测现实世界行为和优化复合体系结构方面的多功能性。这项工作为设计具有定制机械性能的生物启发材料提供了一个强大的工具，适用于需要能量吸收，耐用性和强度的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Finite Elements in Analysis and Design 工程技术-力学

CiteScore

4.80

自引率

3.20%

发文量

审稿时长

27 days

期刊介绍： The aim of this journal is to provide ideas and information involving the use of the finite element method and its variants, both in scientific inquiry and in professional practice. The scope is intentionally broad, encompassing use of the finite element method in engineering as well as the pure and applied sciences. The emphasis of the journal will be the development and use of numerical procedures to solve practical problems, although contributions relating to the mathematical and theoretical foundations and computer implementation of numerical methods are likewise welcomed. Review articles presenting unbiased and comprehensive reviews of state-of-the-art topics will also be accommodated.