Floating column mechanism experimental investigation in historic timber buildings subjected to decay for seismic resilience

Lingkun Chen, Chencheng Zhai, Qizhi Chen, Xiaolun Hu, Teng Wu, Liming Zhu, Xiaoming Huang
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Abstract

Traditional wooden structures are characterized by the presence of a column base that seems to be floated above the foundation stone. This study used pseudo-static experiments to assess the seismic performance of flat pendulum floating resting columns, focusing on the decay and repair of the wood frame (WF). First, an artificial method was used to simulate fungal decay damage of column-foot joints, and filling reinforcement was applied to the decayed column-foot joints, and second, according to the design method in the Sung dynasty architecture, the Ying-tsaofa-shih (building standards). This study presents the findings of pseudo-static tests that were conducted at Yangzhou University. Three 1:3.52 scaled specimen WFs with flat-pendulum-floating-shelf (FPFS)-typed (Ping-bai-fu-ge) columns, i.e., non-damaged WF (named after NT), considering the damaged WF (named after DF) and strengthening damaged WF (named after DR) with one-way straight mortise-tenon joints (OWSMT) joints were made and subjected to cyclic lateral loads during testing. The properties of the WFs with FPFS columns, such as the failure mode, hysteretic and envelope curves, strength and stiffness deterioration, and energy dissipation, have been studied. Finally, the effects of additional damage and reinforcement measures on the seismic performance of WFs are analyzed and compared with the finite element numerical simulation results. This research shows that damage to the column foot decreases the WF's seismic performance, although filler reinforcement may increase it. The foot and mortise joints are interconnected and interact in the wood frame's seismic stressing mechanism. Foot decay reduces the seismic performance of the foot joint, hence increasing the seismic energy dissipation activity of the mortise joints.
历史悠久的抗震木结构建筑中的浮柱机制实验研究
传统木结构的特点是柱基似乎漂浮在基石之上。本研究采用伪静力实验来评估平摆浮歇柱的抗震性能,重点关注木框架(WF)的腐朽和修复。首先,采用人工方法模拟柱脚接缝的真菌腐朽破坏,并对腐朽的柱脚接缝进行填充加固;其次,根据宋代建筑《营造法式》中的设计方法。本研究介绍了在扬州大学进行的伪静力试验的结果。本研究制作了三个 1:3.52 的平摆浮搁(FPFS)型(平白浮搁)柱 WF 试件,即未损坏 WF(以 NT 命名)、考虑损坏 WF(以 DF 命名)和采用单向直榫连接(OWSMT)加固损坏 WF(以 DR 命名),并在试验过程中承受了循环侧向荷载。研究了带有 FPFS 柱的 WF 的特性,如破坏模式、滞后和包络曲线、强度和刚度劣化以及能量耗散。最后,分析了附加破坏和加固措施对 WF 抗震性能的影响,并与有限元数值模拟结果进行了比较。研究结果表明,柱脚的损坏会降低 WF 的抗震性能,但填充加固可能会提高其抗震性能。柱脚和榫接在木框架的抗震应力机制中是相互关联和相互作用的。柱脚腐朽会降低柱脚接缝的抗震性能,从而增加榫接缝的抗震消能活动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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