基础设施监测用自传感胶凝涂层界面粘结效果研究

MATEC Web of Conferences Pub Date : 2023-01-01 DOI:10.1051/matecconf/202337805006

C. Vlachakis, Yen-Fang Su, A. Al-Tabbaa

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引用次数: 0

摘要

在结构健康监测领域，自传感胶凝粘合剂由于其高传感性能和耐久性而在过去几十年中受到了广泛的关注。特别是，自传感胶凝涂层由于其与混凝土结构的高相容性以及在使用少量材料和较低成本的情况下监测现有基础设施的能力而受到越来越多的关注。地聚合物涂层由于其固有的电性能和与混凝土结构的高结合强度而显示出有利的特性。尽管对自传感涂层进行了研究，但尚未研究涂层与基体之间的界面键对涂层传感性能的影响。两种材料之间的不良结合可能导致低质量的传感测量和数据误读。在本文中，我们的目的是研究键合效应对自传感地聚合物涂层传感性能的影响。本研究将粉煤灰-偏高岭土地聚合物涂料应用于混凝土基底;采用三种不同的表面处理方法对混凝土表面进行处理:机械刷刷、化学处理和未处理的浇筑表面。采用劈裂拉伸键合试验对各制备工艺的粘结强度进行了测定，并对重复加载条件下地聚合物涂层的传感响应进行了表征。通过正确理解胶凝材料之间的界面，可以相应地定制传感涂料，以实现高传感性能，从而实现民用基础设施的高质量监测和主动维护。

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Investigation of the interfacial bonding effect on self-sensing cementitious coatings for infrastructure monitoring

In the field of structural health monitoring, self-sensing cementitious binders have gained great attention over the past decades due to their high sensing performance and durability. In particular, self-sensing cementitious coatings have seen increased interest due to their high compatibility with concrete structures and their ability to monitor existing infrastructure while using low amounts of material and at lower costs. Geopolymer coatings display favorable characteristics for this application due to their innate electrical properties and high bond strength with concrete structures. Despite the research that has been carried out on self-sensing coatings, the effect of the interfacial bond between the coating and substrate on the coating’s sensing performance has not been investigated. Poor bonding between the two materials can lead to low-quality sensing measurements and data misinterpretation. In this paper, we aim to investigate the bonding effect on the sensing performance of self-sensing geopolymer coatings. For this study fly ash-metakaolin geopolymer coatings were applied onto concrete substrates; the concrete surfaces were treated by employing three different surface preparation methods: mechanical brooming, chemical treatment and the untreated cast surface. The bond strength for each preparation technique was measured with the splitting tensile bond test and the sensing response for the geopolymer coatings under repeated loading was also characterized. Through proper understanding of the interface between cementitious materials, sensing coatings can be tailored accordingly to achieve high sensing performance and thus allowing high-quality monitoring and proactive maintenance in civil infrastructure.

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来源期刊

MATEC Web of Conferences

自引率

0.00%

发文量

342

审稿时长

6 weeks

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