Abstract
This work experimentally investigates the effect of layered structure on the static and impact response of a new layered syntactic foam developed for impact energy absorption. The layered syntactic foam had the same density of 1.6 g/cm3 and the same components of 50% large spheres (L) and 50% small spheres (S) with different structures from two layers to five layers. The impact response and energy absorption were investigated by drop-weight impact tests. Under static loading, more layers led to higher yield stress and lower energy absorption. There were three types of progressive failures of layered syntactic form under impact loading. The failure propagation was examined and found to be dependent on the layer number and impact energy. Interestingly, layered syntactic foam absorbed more energy than both of its components in terms of ductility. The ductility of layered syntactic foam decreased with the increase in layer number. The peak stress of layered syntactic foam increased with the increase in layer number. Two-layered syntactic foam LS had the highest ductility under 60 J/g impact, as well as an energy absorption of 35 J/g, compared to other layered syntactic foams. Specifically, its component L had a ductility under 70 J/g and an energy absorption of 25 J/g, while component S had a ductility under 10 J/g and an energy absorption of 10 J/g.
Highlights
Aluminum matrix syntactic foams (AMSFs) are novel lightweight composites, which consist of an aluminum matrix embedded with ceramic microballoons such as alumina cenospheres [1,2]
The aluminum matrix syntactic foams (AMSFs) samples were produced by infiltration casting using 6082 Al alloy and a hollow ceramic microsphere (CM) powder supplied by Envirospheres Pty Ltd. (Sydney, Australia)
The homogeneous AMSF specimens were designated as L and S, and the layered AMSFs were designed with 2–5 layers, as LS, LSL, SLS, and LSLSL
Summary
Aluminum matrix syntactic foams (AMSFs) are novel lightweight composites, which consist of an aluminum matrix embedded with ceramic microballoons such as alumina cenospheres [1,2]and fly ash [3,4]. The microballoons are used to introduce porosity in order to form hollow particles inside the AMSFs. The microballoons are used to introduce porosity in order to form hollow particles inside the AMSFs These lightweight materials can offer superior specific stiffness, strength, and damage tolerance due to their mechanical energy absorption capabilities. AMSFs with a wide range of applications such as cores in sandwich structures, crash protection, and damping panels [5]. It is possible to design specific syntactic foams to meet application demands with different hollow spheres, which can be varied with different densities and sizes using flotation methods and sieves [6]
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