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Experimental Research on the Shear Performance of RSM Integrated Walls Considering Self-Tapping Screw Spacing
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摘要: 聚氨酯泡沫-钢框-金属面板一体化(RSM)集成墙体是一种新型的集成剪力墙,具有优异的抗剪性能和节能效果。然而,关于自攻螺钉间距对其性能影响的系统研究较少。通过试验和数值模拟相结合,探讨自攻螺钉间距对RSM墙体抗剪性能的影响,为工程应用提供设计指导。基于ABAQUS软件建立了有限元模型,并制作了自攻螺钉间距为75 mm和150 mm的墙体,进行了单调加载和低周往复加载试验,采集了荷载-位移及荷载-滞回曲线数据。通过对比试验与模拟结果,验证了模型的准确性,并扩展研究了50,75,100,125,150 mm螺钉间距下的性能变化。结果表明:减小螺钉间距显著提高了墙体的初始刚度、抗剪承载力和耗能能力,加密螺钉连接增强了薄金属板与钢框架的结合,延缓了金属板撕裂。随着螺钉间距减小,墙体刚度退化减缓,延塑性增强;但钢板破坏后承载力迅速下降;墙体耗能能力与螺钉间距呈负相关,等效阻尼系数随位移增大先增后减。即加密螺钉间距优化了板框连接性能,显著提升墙体的抗剪能力和初始刚度,为RSM集成墙体的优化设计提供了理论依据。Abstract: The RSM integrated wall, consisting of a steel frame encased by double-sided thin steel plates and filled with rigid polyurethane foam, represents a novel type of shear wall. However, current literature lacks comprehensive research on the shear performance of RSM integrated walls, especially concerning the impact of self-tapping screw spacing on performance. This paper aims to investigate the influence of self-tapping screw spacing on the shear performance of RSM integrated walls through experimental testing and numerical simulation, providing scientific insights and design guidance for practical engineering applications. To thoroughly examine the shear performance of RSM integrated walls, a finite element model was developed using ABAQUS software. To validate this model, two RSM wall specimens with different self-tapping screw spacings (75 mm and 150 mm) were subjected to monotonic loading and quasi-static loading tests. Experimental data, including load-displacement curves and load-lateral hysteresis curves, were collected to evaluate the walls’ behavior. By comparing finite element simulation results with experimental data, the model’s accuracy was preliminarily validated. Subsequently, this study was extended to include five different self-tapping screw spacings (50 mm, 75 mm, 100 mm, 125 mm, and 150 mm) to explore their influence on the shear performance of RSM walls. Findings from both experiments and simulations showed that reducing the self-tapping screw spacing significantly improved the initial stiffness, shear capacity, and energy dissipation capability of RSM walls. Comparative analysis revealed that smaller screw spacing strengthened the connection between thin metal plates and the steel frame, delaying tearing at self-tapping screws and allowing better performance of the thin metal plates. As the screw spacing decreased, the bearing capacity degradation coefficient increased, and the stiffness degradation curve became more gradual, indicating enhanced ductility. However, when the steel plates were damaged, the frame could not fully bear horizontal loads, leading to a rapid decrease in wall bearing capacity. Additionally, energy dissipation capacity was negatively correlated with screw spacing, while the equivalent viscous damping coefficient increased initially and then decreased as displacement grew, indicating minimal impact from changes in screw spacing. The findings suggest that reduced self-tapping screw spacing enhances the connectivity between thin metal plates and the steel frame, effectively delaying the rupture of the thin metal plates. This significantly improves the shear strength and initial stiffness of the wall. These results establish a theoretical foundation for optimizing the design of RSM integrated walls and hold significant value for engineering applications.
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