Study on Reciprocating Loading Tests and Moment-Rotation Theory of Straight-Tenon Joints in Traditional Wooden Structures

• Published in: Forests Vol. 14; no. 12; p. 2424
• Main Authors: Yu, Shibin, Pan, Wen, Su, Hexian, Ye, Liaoyuan
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.12.2023
• Subjects: Cultural heritage; Deformation; Deformation effects; Design and construction; Dynamic testing; Earthquake engineering; Energy consumption; Energy dissipation; Equilibrium conditions; Friction; Geometry; Hysteresis; hysteresis curve; Hysteresis loops; Materials; Mechanical properties; moment-rotation model; mortise and tenon joint; Performance indices; Process controls; reciprocating loading tests; Rotation; Seismic activity; Seismic analysis; Seismic response; Static equilibrium; Stiffness; Strain gauges; Stress relaxation; Testing; Timber joints; Viscous damping; Wooden structures; China
• ISSN: 1999-4907; 1999-4907
• DOI: 10.3390/f14122424

For the study of the mechanical properties of straight-tenon joints in traditional wooden structures, three specimens of T-shaped straight-tenon joints were made according to actual structures and subjected to reciprocating loading tests. The variation rules of different seismic performance indexes such as moment-rotation hysteresis curve, skeleton curve, stiffness, and energy dissipation capacity of the specimens were analyzed through tests. Based on the geometric deformation and static equilibrium conditions, the moment-rotation theoretical model of straight-tenon joints is derived and compared with the experimental results. The studies show that the hysteresis curve of joints under reciprocating loading consists of four stages: ascending, stress relaxation, descending, and sliding. The moment capacity of joints increases gradually with the rotational deformation, but the internal gap of the joints increases synchronously, resulting in a serious attenuation of the stiffness. Tenon and mortise plastic extrusion deformation and friction can dissipate energy, as the rotational deformation increases energy consumption, while the hysteresis loop “pinch” effect is more serious, and the equivalent viscous damping coefficient is gradually reduced. The prediction results of the joint moment-rotation theoretical model are closer to the experimental results, which can provide a theoretical basis for the overall seismic analysis of traditional wooden structures.