Numerical Simulation Analysis of Auxiliary-Rod Force for Tower

Mei Li; Xiao Jun Jin; Yan Hui Li

doi:10.4028/www.scientific.net/AMR.671-674.722

Paper Titles

Introduction of the Application of Strut-and-Tie Model in Concrete Deep Beams
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Local Buckling Behaviors of Built-Up Box Columns Fabricated with High-Performance Steel under Concentric Axial Loading
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Mechanism and Theoretical Calculations of Buttress Anti-Slide Pile
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Nonlinear Analysis on Static Behaviors of New All-Bolted Beam-to-Column Connections for Concrete-Fillled Square Steel Tube
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Numerical Simulation Analysis of Auxiliary-Rod Force for Tower
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Numerical Simulation of One-Way Reinforced Concrete Slabs Subjected to Blast Loadings
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Performance of Different Corrosion Ratio RC Beams under Fatigue Load
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Primary Analysis of Concrete-Filled Steel Tubular Slender Columns with Elliptical Section under Axial Compression
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Probabilistic Model of Corrosion in Reinforced Concrete Structures Considering Coupling Effects of Influence Factors
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Numerical Simulation Analysis of Auxiliary-Rod Force for Tower

Abstract:

Based on nonlinear FEA software ANSYS, thirty-six numerical simulation tower-models that have different initial bend state, bend deflection and intersegment of main-rod were established. Analysis results indicate: Initial bend state of main-rod has influence to force of horizontal auxiliary-rod greatly. With increasing initial bend deflection of main-rod, force of each horizontal auxiliary-rod presents to enlarge trend and is unequal. Force of each horizontal auxiliary-rod is less than 0.015 times endogen force of main-rod, total of each force for horizontal auxiliary-rod is less than 0.06 times endogen force of main-rod. With increasing intersegment of main-rod, total of each force for horizontal auxiliary-rod presents to enlarge trend.