Study on the low-velocity impact response of foam-filled multi-cavity composite panels

Jiye Chen; Lu Zhu; Hai Fang; Juan Han; Ruili Huo; Peng Wu

doi:10.1016/j.tws.2022.108953

Study on the low-velocity impact response of foam-filled multi-cavity composite panels

Jiye Chen, Lu Zhu, Hai Fang, Juan Han, Ruili Huo, Peng Wu

School of Civil Engineering

Nanjing Tech University

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

This paper investigates the influence of lattice-web layout on the low-velocity impact performance of foam-filled multi-cavity composite panels (FMCPs). The effect of impact velocity has been explored to demonstrate the impact resistance property and energy absorption capacity. Due to the light weight and great energy absorption capacity, the FMCP with double-layer dislocation webs can be used as a good energy buffer device. An energy balance model, based on the energy absorption during impacts, was developed to predict the peak loads of the FMCPs. Numerical models were established and parametric analysis was conducted on the GFRP thickness and foam density.

Original language	English
Article number	108953
Journal	Thin-Walled Structures
Volume	173
DOIs	https://doi.org/10.1016/j.tws.2022.108953
State	Published - Apr 2022

Keywords

Composite sandwich structures
Energy absorption
Foam-filled multi-cavity
Impact resistance
Numerical simulation

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10.1016/j.tws.2022.108953

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title = "Study on the low-velocity impact response of foam-filled multi-cavity composite panels",

abstract = "This paper investigates the influence of lattice-web layout on the low-velocity impact performance of foam-filled multi-cavity composite panels (FMCPs). The effect of impact velocity has been explored to demonstrate the impact resistance property and energy absorption capacity. Due to the light weight and great energy absorption capacity, the FMCP with double-layer dislocation webs can be used as a good energy buffer device. An energy balance model, based on the energy absorption during impacts, was developed to predict the peak loads of the FMCPs. Numerical models were established and parametric analysis was conducted on the GFRP thickness and foam density.",

keywords = "Composite sandwich structures, Energy absorption, Foam-filled multi-cavity, Impact resistance, Numerical simulation",

author = "Jiye Chen and Lu Zhu and Hai Fang and Juan Han and Ruili Huo and Peng Wu",

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T1 - Study on the low-velocity impact response of foam-filled multi-cavity composite panels

AU - Chen, Jiye

AU - Zhu, Lu

AU - Fang, Hai

AU - Han, Juan

AU - Huo, Ruili

AU - Wu, Peng

PY - 2022/4

Y1 - 2022/4

N2 - This paper investigates the influence of lattice-web layout on the low-velocity impact performance of foam-filled multi-cavity composite panels (FMCPs). The effect of impact velocity has been explored to demonstrate the impact resistance property and energy absorption capacity. Due to the light weight and great energy absorption capacity, the FMCP with double-layer dislocation webs can be used as a good energy buffer device. An energy balance model, based on the energy absorption during impacts, was developed to predict the peak loads of the FMCPs. Numerical models were established and parametric analysis was conducted on the GFRP thickness and foam density.

AB - This paper investigates the influence of lattice-web layout on the low-velocity impact performance of foam-filled multi-cavity composite panels (FMCPs). The effect of impact velocity has been explored to demonstrate the impact resistance property and energy absorption capacity. Due to the light weight and great energy absorption capacity, the FMCP with double-layer dislocation webs can be used as a good energy buffer device. An energy balance model, based on the energy absorption during impacts, was developed to predict the peak loads of the FMCPs. Numerical models were established and parametric analysis was conducted on the GFRP thickness and foam density.

KW - Composite sandwich structures

KW - Energy absorption

KW - Foam-filled multi-cavity

KW - Impact resistance

KW - Numerical simulation

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DO - 10.1016/j.tws.2022.108953

M3 - 文章

AN - SCOPUS:85124037172

SN - 0263-8231

VL - 173

JO - Thin-Walled Structures

JF - Thin-Walled Structures

M1 - 108953

ER -

Study on the low-velocity impact response of foam-filled multi-cavity composite panels

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Keywords

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