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1. Piezoresistivity properties of copper-plated steel fiber reinforced ultra high performance concrete with ceramic waste powders.

Author

ZHANG Liqing, BIAN Mingqiang, XIAO Zhenrong, WANG Yunyang, PAN Yannian, XU Kaicheng, and HUANG Hong

Abstract

The copper-plated steel fiber has the characteristics of good electrical, mechanical and high conductivity, and the ceramic waste powders has the advantages of pozzolanic internal curing and low carbon properties. It is easy to form a good andchemically stable strengthening, toughening and conductive network by synergistic action. Therefore, the piezoresistivity properties of copper-plated steel fiber content and loading conditions on copper-plated steel reinforced fiber ultra high performance concrete with ceramic waste powders were studied by using uniform sieving method. The research shows that the copper-plated steel fiber can improve the piezoresistivity of ultra high performance concrete with ceramic tile waste powders with different content of copper-plated steel fibers under different load amplitudes and different loading rates. Compared with plain samples, the fractional change in resistivity and stress/strain sensitivity of 2.50 vol% content of copper-plated steel fibers reinforced ultra high performance concrete with ceramic waste powders are increased by 650.0%, 614.3% and 1 223.0%, respectively. Moreover, it can be seen that the loading amplitude has the greatest influence on the piezoresistivity performance among copper-plated steel fibers and loading rates. The stress-electricity model shows that the relationship between the fractional change in resistivity and stress/strain sensitivity of ultra high performance concrete with ceramic waste powders is exponential function under cyclic load, and the fitting degree is above 0.90. Therefore, the stress/strain monitoring of concrete structures can be realized by testing the resistivity of copper-plated steel fiber reinforced ultra high performance concrete with ceramic waste powders. [ABSTRACT FROM AUTHOR]

Published

2023