Carbon Black Engineered Cementitious Composites - Mechanical and Electrical Characterization

SP-292: Structural Health Monitoring Technologies Pub Date : 2013-10-02 DOI:10.14359/51686287

Mo Li, V. Lin, J. Lynch, V. Li

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引用次数: 17

Abstract

Synopsis: The protection and health monitoring of deteriorating concrete infrastructure requires a new generation of self-sensing structural materials that possess intrinsic damage tolerance but offer self-sensing capabilities that are tailored to diagnose states of cracking. Engineered Cementitious Composites (ECC) doped with carbon black (CB) nano-particles are proposed as highly damage-tolerant materials whose electrical properties can be correlated to strain and cracking. This study investigated the effect of CB dosage on the CB-ECC rheological, mechanical and electrical properties. By incorporating CB nano-particles into the ECC system while simultaneously controlling the rheological properties of the fresh mix, the fully cured CB-ECC elements achieved close-to-uniform PVA fiber and carbon black dispersion, reduced bulk resistivity by an order of magnitude, strain hardening behavior with tensile strain capacity of 0.26 to 1.38%, and reduced crack widths of 30 to 40 m during tensile loading. Furthermore, all of the CB-ECC specimens exhibited prominent piezoresistive behavior with resistivity increasing in tandem with applied tensile strain, thereby indicating the potential of CB-ECC for strain and damage sensing.

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炭黑工程胶凝复合材料。机械和电气特性

摘要:老化混凝土基础设施的保护和健康监测需要新一代的自感知结构材料，这种材料不仅具有固有的损伤容忍度，而且具有定制的自感知能力，可以诊断开裂状态。摘要掺杂炭黑纳米颗粒的工程胶凝复合材料(ECC)是一种高损伤耐受性材料，其电学性能与应变和开裂相关。研究了炭黑用量对CB- ecc流变性能、力学性能和电性能的影响。通过将CB纳米颗粒加入到ECC体系中，同时控制新鲜混合料的流变特性，完全固化的CB-ECC元件实现了PVA纤维和炭黑的接近均匀分散，体电阻率降低了一个数量级，应变硬化行为，拉伸应变容量为0.26 ~ 1.38%，拉伸加载时裂缝宽度减小了30 ~ 40m。此外，所有CB-ECC试件均表现出明显的压阻行为，电阻率随外加拉伸应变的增加而增加，从而表明CB-ECC具有应变和损伤传感的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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SP-292: Structural Health Monitoring Technologies

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