Numerical Simulation and Experimental Study on Energy Absorption of Foam-Filled Local Nanocrystallized Thin-Walled Tubes under Axial Crushing

Wei Wang; Yajing Wang; Zhen Zhao; Zhenzhen Tong; Xinsheng Xu; Chee Wah Lim

doi:10.3390/ma15165556

Numerical Simulation and Experimental Study on Energy Absorption of Foam-Filled Local Nanocrystallized Thin-Walled Tubes under Axial Crushing

Wei Wang, Yajing Wang, Zhen Zhao, Zhenzhen Tong, Xinsheng Xu^*, Chee Wah Lim^*

^*Corresponding author for this work

Department of Architecture and Civil Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

14 Citations (Scopus)

111 Downloads (CityUHK Scholars)

Abstract

A crashworthiness design of foam-filled local nanocrystallized thin-walled tubes (FLNTs) is proposed by using foam-filled structures and ultrasonic impact surface treatment. The crashworthiness and deformation modes of FLNTs are studied using an experiment and numerical analysis. A finite element numerical model of FLNTs is established, and the processing and test platform of FLNTs is set up to verify the numerical predication and analytical design. The results show that local nanocrystallization is an effective method to enhance crashworthiness for hexagonal FLNTs. The FLNTs with four circumferential continuous stripes of surface nanocrystallization exhibit a level of 47.12% higher specific energy absorption than the untreated tubes in numerical simulations for tubes with a 50% ratio of nanocrystallized area. Inspired by the strength mechanism, a novel nested foam-filled local surface nanocrystallization tube is further designed and studied in detail.

Original language	English
Article number	5556
Number of pages	21
Journal	Materials
Volume	15
Issue number	16
Online published	12 Aug 2022
DOIs	https://doi.org/10.3390/ma15165556
Publication status	Published - Aug 2022

Research Keywords

aluminium foam
axial loading
crashworthiness
energy absorption
local surface nanocrystallization
thin-walled tube
SURFACE NANOCRYSTALLIZATION
CRASHWORTHINESS DESIGN
STAINLESS-STEEL
ALUMINUM EXTRUSIONS
CYLINDRICAL-SHELLS
LIQUID NANOFOAM
FREE-VIBRATION
MULTICELL
BEHAVIOR
OPTIMIZATION

Publisher's Copyright Statement

This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Numerical Simulation and Experimental Study on Energy Absorption of Foam-Filled Local Nanocrystallized Thin-Walled Tubes under Axial Crushing",

abstract = "A crashworthiness design of foam-filled local nanocrystallized thin-walled tubes (FLNTs) is proposed by using foam-filled structures and ultrasonic impact surface treatment. The crashworthiness and deformation modes of FLNTs are studied using an experiment and numerical analysis. A finite element numerical model of FLNTs is established, and the processing and test platform of FLNTs is set up to verify the numerical predication and analytical design. The results show that local nanocrystallization is an effective method to enhance crashworthiness for hexagonal FLNTs. The FLNTs with four circumferential continuous stripes of surface nanocrystallization exhibit a level of 47.12% higher specific energy absorption than the untreated tubes in numerical simulations for tubes with a 50% ratio of nanocrystallized area. Inspired by the strength mechanism, a novel nested foam-filled local surface nanocrystallization tube is further designed and studied in detail.",

keywords = "aluminium foam, axial loading, crashworthiness, energy absorption, local surface nanocrystallization, thin-walled tube, SURFACE NANOCRYSTALLIZATION, CRASHWORTHINESS DESIGN, STAINLESS-STEEL, ALUMINUM EXTRUSIONS, CYLINDRICAL-SHELLS, LIQUID NANOFOAM, FREE-VIBRATION, MULTICELL, BEHAVIOR, OPTIMIZATION",

author = "Wei Wang and Yajing Wang and Zhen Zhao and Zhenzhen Tong and Xinsheng Xu and Lim, {Chee Wah}",

year = "2022",

month = aug,

doi = "10.3390/ma15165556",

language = "English",

volume = "15",

journal = "Materials",

issn = "1996-1944",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "16",

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T1 - Numerical Simulation and Experimental Study on Energy Absorption of Foam-Filled Local Nanocrystallized Thin-Walled Tubes under Axial Crushing

AU - Wang, Wei

AU - Wang, Yajing

AU - Zhao, Zhen

AU - Tong, Zhenzhen

AU - Xu, Xinsheng

AU - Lim, Chee Wah

PY - 2022/8

Y1 - 2022/8

N2 - A crashworthiness design of foam-filled local nanocrystallized thin-walled tubes (FLNTs) is proposed by using foam-filled structures and ultrasonic impact surface treatment. The crashworthiness and deformation modes of FLNTs are studied using an experiment and numerical analysis. A finite element numerical model of FLNTs is established, and the processing and test platform of FLNTs is set up to verify the numerical predication and analytical design. The results show that local nanocrystallization is an effective method to enhance crashworthiness for hexagonal FLNTs. The FLNTs with four circumferential continuous stripes of surface nanocrystallization exhibit a level of 47.12% higher specific energy absorption than the untreated tubes in numerical simulations for tubes with a 50% ratio of nanocrystallized area. Inspired by the strength mechanism, a novel nested foam-filled local surface nanocrystallization tube is further designed and studied in detail.

AB - A crashworthiness design of foam-filled local nanocrystallized thin-walled tubes (FLNTs) is proposed by using foam-filled structures and ultrasonic impact surface treatment. The crashworthiness and deformation modes of FLNTs are studied using an experiment and numerical analysis. A finite element numerical model of FLNTs is established, and the processing and test platform of FLNTs is set up to verify the numerical predication and analytical design. The results show that local nanocrystallization is an effective method to enhance crashworthiness for hexagonal FLNTs. The FLNTs with four circumferential continuous stripes of surface nanocrystallization exhibit a level of 47.12% higher specific energy absorption than the untreated tubes in numerical simulations for tubes with a 50% ratio of nanocrystallized area. Inspired by the strength mechanism, a novel nested foam-filled local surface nanocrystallization tube is further designed and studied in detail.

KW - aluminium foam

KW - axial loading

KW - crashworthiness

KW - energy absorption

KW - local surface nanocrystallization

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KW - CRASHWORTHINESS DESIGN

KW - STAINLESS-STEEL

KW - ALUMINUM EXTRUSIONS

KW - CYLINDRICAL-SHELLS

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KW - FREE-VIBRATION

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KW - BEHAVIOR

KW - OPTIMIZATION

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Numerical Simulation and Experimental Study on Energy Absorption of Foam-Filled Local Nanocrystallized Thin-Walled Tubes under Axial Crushing

Abstract

Research Keywords

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