In-Plane Crushing of Square Honeycomb Cores, Part II: Energy Absorption and Cushioning Optimization

De Qiang Sun; Zu Yong Jiang; Yan Bin Wei

doi:10.4028/www.scientific.net/AMM.170-173.3237

Paper Titles

Analysis of Cracks in Concrete Beam Impacted by Construction Technology
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In-Plane Crushing of Square Honeycomb Cores, Part I: Mechanical Behaviors
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Numerical Simulation of Shock Wave Caused by Underwater Blasting
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Reasearch on Titanium Plate and Steel Plate in Explosive Welding Process Engineering
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In-Plane Crushing of Square Honeycomb Cores, Part II: Energy Absorption and Cushioning Optimization
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The Construction Technology and Numerical Simulation on Tunnels Throughing Fault Fracture Zone with Rich Water
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Numerical Simulation Study on Hydraulic Blasting Based on LS-DYNA
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Failure Law of Supporting Part of Reinforced Concrete Chimney by Blasting Demolition
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A Key Technique for Cement Concrete Pavement Joint Filler Construction in Chilly Regions
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 170-173In-Plane Crushing of Square Honeycomb Cores, Part...

In-Plane Crushing of Square Honeycomb Cores, Part II: Energy Absorption and Cushioning Optimization

Abstract:

The finite element (FE) model designed in Part I is used to obtain the cushioning mechanical parameters of square honeycomb cores (SHCs) under in-plane dynamic loadings. A simplified energy absorption model is proposed to evaluate the energy absorption performance of SHCs, which shows that the optimal energy absorption per unit volume is related to dynamic plateau stress and dynamic densification strain that are affected by configuration parameters and impact velocity. The optimal energy absorption efficiency is the reciprocal of dynamic densification strain. The dynamic plateau stress has been discussed in Part I. For SHCs, the dynamic densification strain is independent of impact velocity and determined by configuration parameters. The empirical formulas of cushioning mechanical parameters are derived from physical analysis of FE results. Based on these empirical formulas, the practical cushioning optimization algorithm is presented.