环境及疲劳荷载作用下碳纳米管水泥基复合材料压敏性能研究

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摘要 The effects of environment and fatigue on the electrical resistance and piezoresistivity of the carbon nanotube/cement composite is investigated under a service environment using a four-probe method. The main influencing factors include temperature (20, 30, 40℃, and 50℃), water content (0%-6.4%), temperature and water content coupling, and number of fatigue cycles (20, 40, 60, 110, 160, and 240×10³). Test results showed that environment and fatigue considerably affected resistivity and piezoresistivity. The resistivity of the composite decreased as water content increased. When water content changed from 1.3% to 5.8%, resistivity was reduced 43%. By contrast, piezoresistivity and change in resistance initially increased and then decreased as water content increased. Temperature substantially affected resistivity and piezoresistivity. As temperature increased, resistivity decreased but piezoresistivity increased. Electrical resistance and change in resistivity exhibited a strong linear relationship with temperatures ranging from 20℃ to 50℃ with an R2 of over 0.99. As temperature increased from 20℃ to 50℃, resistivity decreased 35% and change in resistivity increased 84%, thereby indicating improved piezoresistivity. Piezoresistive sensitivity to temperature demonstrated a strong negative linear relationship with water content with an R2 of 0.915. Electrical resistance and piezoresistivity increased as the number of cycles increased. The major causes of changes in resistivity and piezoresistivity are a change in tunneling conduction and the development of micro-cracks.

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	李金路
	冯子强
	吴佳杰
	魏姗姗
	葛智

关键词 ： road engineering, electrical resistance, piezoresistivity, four-electrode method, carbon nanotube/cement composite, electrical resistivity, coupling effect of temperature and water content, fatigue

Abstract：The effects of environment and fatigue on the electrical resistance and piezoresistivity of the carbon nanotube/cement composite is investigated under a service environment using a four-probe method. The main influencing factors include temperature (20, 30, 40℃, and 50℃), water content (0%-6.4%), temperature and water content coupling, and number of fatigue cycles (20, 40, 60, 110, 160, and 240×10³). Test results showed that environment and fatigue considerably affected resistivity and piezoresistivity. The resistivity of the composite decreased as water content increased. When water content changed from 1.3% to 5.8%, resistivity was reduced 43%. By contrast, piezoresistivity and change in resistance initially increased and then decreased as water content increased. Temperature substantially affected resistivity and piezoresistivity. As temperature increased, resistivity decreased but piezoresistivity increased. Electrical resistance and change in resistivity exhibited a strong linear relationship with temperatures ranging from 20℃ to 50℃ with an R2 of over 0.99. As temperature increased from 20℃ to 50℃, resistivity decreased 35% and change in resistivity increased 84%, thereby indicating improved piezoresistivity. Piezoresistive sensitivity to temperature demonstrated a strong negative linear relationship with water content with an R2 of 0.915. Electrical resistance and piezoresistivity increased as the number of cycles increased. The major causes of changes in resistivity and piezoresistivity are a change in tunneling conduction and the development of micro-cracks.

Key words： road engineering electrical resistance piezoresistivity four-electrode method carbon nanotube/cement composite electrical resistivity coupling effect of temperature and water content fatigue

收稿日期: 2017-08-04

基金资助:Supported by the National Natural Science Foundation of China (No.51108247)

通讯作者: LI Jin-lu E-mail: ljl7103@163.com

引用本文:

李金路, 冯子强, 吴佳杰, 魏姗姗, 葛智. 环境及疲劳荷载作用下碳纳米管水泥基复合材料压敏性能研究[J]. Journal of Highway and Transportation Research and Development, 2018, 12(3): 16-21.
LI Jin-lu, FENG Zi-qiang, WU Jia-jie, WEI Shan-shan, GE Zhi. Effects of Environment and Fatigue on the Piezoresistivity of Carbon Nanotube/Cement Composite. Journal of Highway and Transportation Research and Development, 2018, 12(3): 16-21.

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