Full-scale test on the mechanical behavior of longitudinal joints of NC-UHPC composite segments under compression-bending load

• Published in: Tunnelling and underground space technology Vol. 153; p. 105993
• Main Authors: Gao, Bin-Yong, Chen, Ren-Peng, Wu, Huai-Na, Zhang, Yang, Meng, Fan-Yan
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2024
• Subjects: Bending stiffness; Longitudinal joints; Mechanical response; Numerical model; UHPC; UHPC; Bending stiffness; Mechanical response; Longitudinal joints; Numerical model
• ISSN: 0886-7798
• DOI: 10.1016/j.tust.2024.105993

•A novel segment structure consisting of NC and UHPC composite.•The mechanical behavior of joints in NC-UHPC composite tunnel segments.•The NC-UHPC composite segments exhibit good toughness and ductility.•The NC-UHPC composite segments are more suitable for high axial loads. The performance of longitudinal joints in shield tunnel segments is crucial for ensuring structural stability and durability. This study presents an innovative segment structure combining normal concrete (NC) and ultra-high performance concrete (UHPC) (hereafter called NC-UHPC composite segment). Full-scale joint tests were conducted to analyze the mechanical response and failure characteristics of longitudinal joints in these segments. Compared to reinforced concrete (RC) segment joints, NC-UHPC composite segment joints exhibited a significant increase in initial cracking load by 197.93% under sagging moments and 435.3% under hogging moments. The ultimate load-bearing capacity increased by 55.71% and 67.10%, and the initial bending stiffness improved by 20.57% and 10.59% under sagging and hogging moments, respectively. Furthermore, NC-UHPC composite segment joints exhibited smaller crack distribution areas and fewer cracks, indicating superior crack resistance. No cracks or damage were observed at the NC-UHPC interface. Evaluation of joint toughness and ductility indices further highlighted the favorable performance of NC-UHPC composite segment joints. Finally, a refined numerical model was established to compare the deflection and bending stiffness of RC segment joints with NC-UHPC composite segment joints under varying axial forces. The findings suggest that NC-UHPC composite segments are more suitable for tunnel engineering with greater burial depth, higher water pressure, and larger axial forces.