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Numerical Study on Hysteretic Behaviour of Horizontal-Connection and Energy-Dissipation Structures Developed for Prefabricated Shear Walls

Limeng Zhu, Lingmao Kong, Chunwei Zhang

2020Applied Sciences95 citationsDOIOpen Access PDF

Abstract

This study proposed a developed horizontal-connection and energy-dissipation structure (HES), which could be employed for horizontal connection of prefabricated shear wall structural system. The HES consists of an external replaceable energy dissipation (ED) zone mainly for energy dissipation and an internal stiffness lifting (SL) zone for enhancing the load-bearing capacity. By the predicted displacement threshold control device, the ED zone made in bolted low-yielding steel plates could firstly dissipate the energy and can be replaced after damage, the SL zone could delay the load-bearing and the load-displacement curves of the HES would exhibit “double-step” characteristics. Detailed finite element models are established and validated in software ABAQUS. parametric analysis including aspect ratio, the shape of the steel plate in the ED zone and the displacement threshold in the SL zone, is conducted. It is found that the HES depicts high energy dissipation ability and its bearing capacity could be obtained again after the yielding of the ED zone. The optimized X-shaped steel plate in the ED zone exhibit better performance. The “double-step” design of the HES is a potential way of improving the seismic and anti-collapsing performance of prefabricated shear wall structures against large and super-large earthquakes.

Topics & Concepts

DissipationStructural engineeringShear wallStiffnessConnection (principal bundle)Displacement (psychology)Bearing capacityBearing (navigation)Parametric statisticsShear (geology)Materials scienceGeologyGeotechnical engineeringEngineeringComposite materialPhysicsThermodynamicsMathematicsAstronomyStatisticsPsychotherapistPsychologySeismic Performance and AnalysisStructural Analysis and OptimizationStructural Engineering and Vibration Analysis