https://doi.org/10.11112/jksmi.2026.30.3.28
윤창호(Chang-Ho Yun) ; 박종건(Jong-Gun Park) ; 허광희(Gwang-Hee Heo)
This study investigated the effect of enhanced electrical and mechanical properties of three-phase composite conductive concrete with multi-walled carbon nanotubes (MWCNT), carbon fiber (CF), and steel fiber (SF). Accordingly, a specimen was prepared by varying the mixing contents of MWCNT, CF, and SF as experimental variables, and electrical and mechanical properties were evaluated through electrical resistance measurement, flow table test, and strength test. In addition, the microstructure of the three-phase composite conductive concrete was analyzed through scanning electron microscope (SEM) and energy-dispersive X-ray spectroscopy (EDS). The experimental results confirmed that the fluidity of the PC mixture was 215 mm, and when only MWCNT was mixed, there was a slight increase, whereas the fluidity decreased as the mixing contents of CF and SF increased. Meanwhile, in the case of three-phase composite conductive concrete mixed with MWCNT, CF, and SF, it was found that the conductive network was effectively formed, resulting in a significant reduction in electrical resistance and improved electrical properties. In addition, the mechanical properties were found to contribute to the improvement of flexural strength by enhancing crack control and load transfer capabilities through the incorporation of CF and SF. Furthermore, SEM-EDS analysis confirmed the formation of multi-scale conductive pathways in the cement matrix, which are considered to play a significant role in the simultaneous improvement of electrical and mechanical properties. Therefore, the three-phase composite conductive concrete developed in this study is expected to have high potential for use as a multifunctional construction material capable of self-heating and smart infrastructure applications.