Energy absorption parameters of multi-cell thin-walled structure with various thicknesses under lateral loading

Kazemi, Mohammad; Serpoush, J

doi:10.1177/1464420720973686

Cited by 4 publications

(2 citation statements)

References 21 publications

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“…The dent depth and the mass of the BIH sandwich structure are represented by U and M , respectively. The response surface method [ 43 , 44 , 45 ] is used to optimize the design of the BIH sandwich panel. The expression of the optimization problem can be described as follows:

…”

Section: Optimization Designmentioning

confidence: 99%

Mechanical Behavior of Bio-Inspired Honeycomb–Core Composite Sandwich Structures to Low-Velocity Dynamic Loading

Tao,

Li,

et al. 2024

Materials

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In order to improve the impact resistance of sandwich panels under low-velocity impact, the lotus leaf vein is selected as a biological prototype to design a bio-inspired honeycomb (BIH) sandwich panel. ABAQUS is used to establish and effectively verify the finite element (FE) model of the BIH sandwich panel. To systematically compare and study the mechanical properties of BIH and conventional hexagonal honeycomb sandwich panels under low-velocity impact, the maximum displacement of face-sheets, the deformation mode, the plastic energy consumption and the dynamic response curve of the impact end are presented. At the same time, the performance differences between them are revealed from the perspective of an energy absorption mechanism. Furthermore, the influence of the circumscribed circle diameter ratio of the BIH trunk to branch (γ), the thickness ratio of the trunk to branch (K) and the impact angle (θ) on impact resistance is studied. Finally, the BIH sandwich panel is further optimized by using the response surface method. It can be concluded that, compared to conventional hexagonal honeycomb sandwich panels, the addition of walls in the BIH sandwich panel reduces the maximum deformation of the rear face-sheet by 10.29% and increases plastic energy consumption by 8.02%. Properly adjusting the structural parameters can effectively enhance the impact resistance of the BIH sandwich panel.

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…”

Section: Optimization Designmentioning

confidence: 99%

Mechanical Behavior of Bio-Inspired Honeycomb–Core Composite Sandwich Structures to Low-Velocity Dynamic Loading

Tao,

Li,

et al. 2024

Materials

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“…The effect of thickness on energy absorption performance was studied when multi-cell metal thin-walled structures were subjected to transverse compression in Ref. [46], and the results demonstrate that the uneven distribution of thickness in the configuration has a significant impact on the overall deformation mode. As previously discussed, the stiffness of the inner and outer structures plays a significant role in the energy absorption capacity of the two-stage configuration footpad with variable stiffness.…”

Section: Influence Of Thickness Parametersmentioning

confidence: 99%

A Footpad Structure with Reusable Energy Absorption Capability for Deep Space Exploration Lander: Design and Analysis

Dou,

Qiu,

Xiong

et al. 2023

Chin. J. Mech. Eng.

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The footpad structure of a deep space exploration lander is a critical system that makes the initial contact with the ground, and thereby plays a crucial role in determining the stability and energy absorption characteristics during the impact process. The conventional footpad is typically designed with an aluminum honeycomb structure that dissipates energy through plastic deformation. Nevertheless, its effectiveness in providing cushioning and energy absorption becomes significantly compromised when the structure is crushed, rendering it unusable for reusable landers in the future. This study presents a methodology for designing and evaluating structural energy absorption systems incorporating recoverable strain constraints of shape memory alloys (SMA). The topological configuration of the energy absorbing structure is derived using an equivalent static load method (ESL), and three lightweight footpad designs featuring honeycomb-like Ni-Ti shape memory alloys structures and having variable stiffness skins are proposed. To verify the accuracy of the numerical modelling, a honeycomb-like structure subjected to compression load is modeled and then compared with experimental results. Moreover, the influence of the configurations and thickness distribution of the proposed structures on their energy absorption performance is comprehensively evaluated using finite element simulations. The results demonstrate that the proposed design approach effectively regulates the strain threshold to maintain the SMA within the constraint of maximum recoverable strain, resulting in a structural energy absorption capacity of 362 J/kg with a crushing force efficiency greater than 63%.

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Effect of Welding Process on Energy Absorption Parameters of a Square Tube with Emphasis on the Number and Position of Welding Lines

Kazemi,

Ahmadi

2024

Trans Indian Inst Met

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Energy absorption parameters of multi-cell thin-walled structure with various thicknesses under lateral loading

Cited by 4 publications

References 21 publications

Mechanical Behavior of Bio-Inspired Honeycomb–Core Composite Sandwich Structures to Low-Velocity Dynamic Loading

Mechanical Behavior of Bio-Inspired Honeycomb–Core Composite Sandwich Structures to Low-Velocity Dynamic Loading

A Footpad Structure with Reusable Energy Absorption Capability for Deep Space Exploration Lander: Design and Analysis

Effect of Welding Process on Energy Absorption Parameters of a Square Tube with Emphasis on the Number and Position of Welding Lines

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