Electromechanical Behavior of Textile Reinforced Cementitious Composites Under Uniaxial Load

Jun Sik Cho; Tae Uk Kim; Dong Joo Kim

doi:10.22725/JSRP.2025.3.2.76

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2025 Vol.3, Issue 2 Preview Page Next Page

Research Article

Electromechanical Behavior of Textile Reinforced Cementitious Composites Under Uniaxial Load 일축 하중 하의 직조물 보강 시멘트 복합재료의 전기역학적 거동

31 December 2025. pp. 76-87

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Abstract

In this study, the electromechanical behavior of textile reinforced cementitious composites (TRCCs) reinforced by carbon and glass textiles (CT and GT) under uniaxial tension and compression was investigated using DC multimeter, aiming to develop an efficient strengthening and structural health monitoring technology for deteriorated concrete structures. Under tension, the fractional change in electrical resistivity (FCR) of the tensile specimens reinforced by CT (CT-T) varied significantly, ranging from –3.35 % to –94.47 % at the first-cracking point, and from –57.1 % to 15.33 % at the post-cracking point. These variations are attributed to the discontinuous changes in conductive pathways caused by the combined effects of telescopic pullout of carbon filaments, interfacial shear slip, and bridging effect of the textile as the tensile strain increased. Under compression, the FCR of CT specimens (CT-C) at failure (93.53 % to 475.00 %) also exhibited highly irregular behavior due to unstable fluctuations in the conductive network, resulting from local buckling and shear deformation of the filaments within the textile. In contrast, the specimens reinforced by GT (GT-T) showed a sharp increase in electrical resistivity only at failure under tension, as the glass textile had little influence on the conductive network within the matrix. In all cases, the electromechanical behavior of the specimens showed relatively consistent trends in response to external loading. The experimental results confirmed that the electromechanical behavior of TRCCs is significantly influenced by the electrical conductivity and interfacial behavior of the embedded textile, and that CTs are suitable for use as self-sensing materials. Moreover, further analysis of the electromechanical behavior of TRCCs is expected to enable identification of textile–matrix failure modes under external loading conditions.

Keywords

self-sensing cementitious composites

textile reinforced cementitious composites

carbon textile

glass textile

본 연구에서는 노후 콘크리트 구조물에 대한 효율적인 보강 및 건전성 모니터링 기술 개발을 목적으로, 카본(carbon textile, CT) 및 유리 섬유 직조물(glass textile, GT)이 보강된 직조물 보강 시멘트 복합재료(textile reinforced cementitious composites, TRCCs)의 일축 인장 및 압축 하중에 따른 전기역학적 거동을 조사하였다. 인장 하중 하에서 카본 섬유 직조물이 보강된 인장 시험체(CT-T)의 초기 및 최종 균열 시점 전기저항 변화율(fractional change in electrical resistivity, FCR)은 각각 –3.35%~–94.47% 그리고 –57.1%~15.33%로 편차가 크게 발생하였는데, 이는 인장 하중이 증가에 따라 카본 섬유 직조물 내 필라멘트들의 단계적 인발(telescopic pullout), 전단 인발(shear slip), 직조물의 가교 작용 등에 복합적으로 영향을 받으면서 전도성 경로가 불연속적으로 변형되었기 때문이다. 압축 하중 하에서도 CT의 파단 시점 FCR(93.53%~475.00%)은 직조물 내 필라멘트의 국부 좌굴 및 전단변형에 따른 전도성 네트워크가 불규칙한 변동으로 매우 불규칙한 거동을 나타냈다. 반면, 유리 섬유 직조물을 보강한 시험체(GT-T)는 유리 섬유 직조물이 매트릭스 내부 전도성 경로에 미치는 영향이 적어 인장 하중에 의해 파단될 때의 전기저항률 급증 거동만이 확인되었다. TRCCs의 전기역학적 거동은 보강된 직조물의 전기전도도 및 계면 거동에 따라 크게 변화하는 것이 실험을 통하여 확인되었으며 CT가 자가센싱 용도로 사용에 적합하였다. 추후 TRCCs의 전기역학적 거동 분석을 통하여 외부 하중 하에서 직조물-매트릭스 파괴 모드를 구분 가능할 것으로 기대된다.

키워드

자기감지 시멘트 복합재료

직조물 보강 시멘트 복합재료

카본 섬유 직조물

유리 섬유 직조물

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Information

Publisher :Korean Institute of Bridge and Structural Engineers
Publisher(Ko) :한국교량및구조공학회
Journal Title :Journal of Structure Research and Practice
Journal Title(Ko) :한국교량및구조공학회 논문집
Volume : 3
No :2
Pages :76-87
Received Date : 2025-11-03
Revised Date : 2025-11-28
Accepted Date : 2025-11-28
DOI :https://doi.org/10.22725/JSRP.2025.3.2.76

Journal of Structure Research and Practice ISSN:3022-4241(Print) 3022-7267(Online) 한국교량및구조공학회 논문집

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