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Abstract

The effects of pore density and matrix on the quasi-static and dynamic compressive behaviours of the high porosity open-cell aluminium foams were examined. The results show that pore density has little effect on the collapse strength of the samples under quasi-static conditions. However, as the strain rate increases, the collapse strength decreases with increasing pore density. The different matrix material also shows distinct strain rate response characteristics, which is related to their respective microstructures. The strain-rate sensitivity is mainly attributed to the micro-inertia effect caused by the larger aspect ratio of the cell edges, which was verified by the more transverse elongation of the dynamic compression samples. Moreover, the energy absorption capacity is also discussed in the present paper.

Keywords

High porosity open-cell aluminium foam compression behaviour strain rate sensitivity energy absorption

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References

Gibson

Ashby

MF.

Cellular solids: structure and properties. Second edition Cambridge: Cambridge University Press; 1997.

Banhart

Manufacture, characterization and application of cellular metals and metal foams. Prog Mater Sci. 2001; 46(6):559–632.

Deshpande

Fleck

NA.

High strain rate compressive behaviour of aluminium alloy foams. Int J Impact Eng. 2000; 24(3):277–298.

Dannemann

Lankford

High strain rate compression of closed-cell aluminium foams. Mater Sci Eng A. 2000; 293(1–2):157–164.

Mukai

Miyoshi

Nakano

Compressive response of a closed-cell aluminum foam at high strain rate. Scr Mater. 2006; 54(4):533–537.

Wang

, Ma

, Zhao

, Studies on the dynamic compressive properties of open-cell aluminum alloy foams. Scr Mater. 2006; 54(1):83–87.

Irausquín

Pérez-Castellanos

Miranda

Evaluation of the effect of the strain rate on the compressive response of a closed-cell aluminium foam using the split Hopkinson pressure bar test. Mater Des. 2013; 47:698–705.

Lankford

Dannemann

KA.

Strain rate effects in porous materials. Mat Res Soc Symp Proc. 1998; 521:103–108.

Wang

Huang

Jia

Effect of grain size on the mechanical properties of Mg foams. J Mater Sci Technol. 2020; 58:46–54.

10.

Májlinger

NorbertOrbulov

Characteristic compressive properties of hybrid metal matrix syntactic foams. Mater Sci Eng A. 2014; 606:248–256.

11.

Szlancsik

Orbulov

IN.

Compressive properties of metal matrix syntactic foams in uni- and triaxial compression. Mater Sci Eng A. 2021; 827:142081.

12.

Movahedi

Vesenjak

Krstulović-Opara

Dynamic compression of functionally-graded metal syntactic foams. Compos Struct. 2021; 261:113308.

13.

Alvandi-Tabrizi

Whisler

Kim

High strain rate behavior of composite metal foams. Mater Sci Eng A. 2015; 631:248–257.

14.

Yang

Liu

High strain rate dynamic compressive properties and deformation behavior of Al matrix composite foams reinforced by in-situ grown carbon nanotubes. Mater Sci Eng A. 2018; 729:487–495.

15.

Zhang

Lin

Quasi-static and high strain rates compressive behavior of aluminum matrix syntactic foams. Compos B Eng. 2016; 98:288–296.

16.

Yadav

Muchhala

Sriram

Study on activation energy and strain rate sensitivity of closed-cell aluminium hybrid composite foam. J Alloys Compd. 2020; 832:154860.

17.

Sun

Burgueño

Vanderklok

Compressive behavior of aluminum/copper hybrid foams under high strain rate loading. Mater Sci Eng A. 2014; 592:111–120.

18.

Yamada

Shimojima

Sakaguchi

Effects of heat treatment on compressive properties of AZ91Mg and SG91A Al foams with open-cell structure. Mater Sci Eng A. 2000; 280(1):225–228.

19.

Wen

Hodgson

Investigation of cell shape effect on the mechanical behaviour of open-cell metal foams. Comp Mater Sci. 2012; 55:1–9.

20.

Yang

Liu

Elevated temperature compressive properties and energy absorption response of in-situ grown CNT-reinforced Al composite foams. Mater Sci Eng A. 2017; 690:294–302.

Effect of pore density on the compressive response of open-cell Al foams

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