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应用数字图像相关系统监测三点弯曲试验中纤维增强混凝土开裂后耗散能力的估算

Estimation of Post-Cracking Dissipation Capabilities of Fiber Reinforced Concretes in Three Point Bending Test Monitored with Application of Digital Image Correlation System.

作者信息

Trinh-Duc Duyen, Piotrowski Andrzej, Ajdukiewicz Cezary, Woyciechowski Piotr, Gajewski Marcin

机构信息

Institute of Building Engineering, Warsaw University of Technology, Armii Ludowej 16, 00-637 Warsaw, Poland.

出版信息

Materials (Basel). 2021 Sep 6;14(17):5088. doi: 10.3390/ma14175088.

DOI:10.3390/ma14175088
PMID:34501178
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8434258/
Abstract

Concretes with dispersed reinforcement are increasingly used in structural engineering. The basic source of knowledge on their application and design are the Model-Code 2010 guidelines. These guidelines, however, apply mainly to steel rebar reinforcement and are not fully sufficient in the analysis of the load-bearing capacity of elements made of concrete with dispersed reinforcement. Therefore, scientific research in this field is carried out continuously. The main goal of our work is to provide experimental data for the calibration of constitutive models of the cracking mechanics of concrete with reinforcement in the form of steel and polypropylene fibers. This article shows the possibility of using the digital image correlation system (DIC) to achieve this goal. The method of sample preparation and the method of conducting the tests were modeled on the recommendations contained in the PN-EN 14651: 2007 standard. The tests were carried out on prismatic elements with a notch loaded in a three-point bending setup. The results of standard strength tests are presented in the form of column graphs and tables. As an extension, the results of calculations of energy dissipated in fracture process are given. Moreover, the experimentally obtained graphs of the relationship between the force, displacement and crack opening were presented, which were supplemented with the images of crack development obtained with the use of DIC. The development of the crack net is characterized not only qualitatively but also quantitatively as a function of deflection or crack mouth opening displacement. Conclusions concerning the adopted research methodology and the tested materials are presented at the end of the article.

摘要

具有分散增强材料的混凝土在结构工程中的应用越来越广泛。关于其应用和设计的基本知识来源是《2010 模型规范》指南。然而,这些指南主要适用于钢筋增强,在分析具有分散增强材料的混凝土构件的承载能力时并不完全充分。因此,该领域的科学研究一直在持续进行。我们工作的主要目标是提供实验数据,用于校准以钢纤维和聚丙烯纤维形式增强的混凝土开裂力学本构模型。本文展示了使用数字图像相关系统(DIC)实现这一目标的可能性。样品制备方法和试验方法是根据 PN - EN 14651: 2007 标准中的建议进行模拟的。试验在带有切口的棱柱形构件上进行,采用三点弯曲加载设置。标准强度试验结果以柱状图和表格形式呈现。作为扩展,给出了断裂过程中耗散能量的计算结果。此外,还展示了通过实验获得的力、位移和裂缝开口之间关系的图表,并辅以使用 DIC 获得的裂缝发展图像。裂缝网络的发展不仅从定性上进行了表征,还作为挠度或裂缝口张开位移的函数进行了定量表征。文章结尾给出了关于所采用的研究方法和测试材料的结论。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/97c2/8434258/a01f1f82c828/materials-14-05088-g014.jpg
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The Effect of Steel and Polypropylene Fibers on the Properties of Horizontally Formed Concrete.钢纤维和聚丙烯纤维对水平浇筑混凝土性能的影响
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