Analysis of Chinese ancient brick masonry characteristics under uniaxial compression fatigue loading

• Published in: Construction & building materials Vol. 392; p. 131874
• Main Authors: Xia, Qian, Yi, Tingliang, Li, Yiqing, Shen, Chunke, Huang, Daguan, Sun, Yuanqing
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 15.08.2023
• Subjects: Ancient brick masonry; Deformation characteristics; Fatigue life equation; Uniaxial compression fatigue test; Ancient brick masonry; Deformation characteristics; Uniaxial compression fatigue test; Fatigue life equation
• ISSN: 0950-0618; 1879-0526
• DOI: 10.1016/j.conbuildmat.2023.131874

•Evaluation of the fatigue performance of ancient brick masonry structures.•The curves of p–S–N fatigue equation based on Weibull distribution was established.•The fatigue stress–strain curve presented obvious three-stage development characteristics of sparse–dense–sparse.•The fatigue strain evolution curve showed a typical “S” structure with three distinct stages. Urban expansion and diversified traffic aggravate the damage and deterioration of ancient buildings. It is crucial to evaluate the long-term fatigue performance of ancient brick masonry structures for the safety and maintenance of ancient buildings. A series of indoor tests were conducted on the ancient brick masonry. The images for the whole process of the test were collected using VIC-3D technology. The relationship between the stress level and the number of failure cycles under compressive fatigue load and the stress–strain evolution under different stress levels were determined. A mathematical model of p-S-N fatigue life prediction based on probability was proposed, which comprehensively considered the maximum stress level, stress range, number of load cycles, and survival probability. The equivalent fatigue life of ancient brick masonry specimens under each failure probability obeys Weibull distribution, and then the fatigue life of masonry can be predicted at any expected confidence level. The test results provide reliable theoretical and data support for fatigue deterioration and life prediction of ancient masonry structures in service.