Abstract
The purpose of the work was the effect of metal volume fraction of fiber metal laminates on damage after dynamic loads based upon the example of innovative hybrid titanium–carbon composite laminates. The subject of the study was metal–fiber hybrid titanium–carbon composite laminates. Four types of hybrid titanium–carbon laminates were designed with various metal volume fraction coefficient but constant thickness. Based on the results, it can be stated that changes in the metal volume fraction coefficient in the range of 0.375–0.6 in constant thickness titanium–carbon composite laminates do not significantly affect their resistance to impacts in the energy range of 5–45 J. It was concluded that there were no significant differences in maximum force values, total contact time, and damage range. Some tendency towards a reduction in the energy accumulation capacity was observed with an increase in thickness of the metal part in relation to the total thickness of the laminate, especially in the lower impact energy range. This can result in the lower bending stiffness of laminates with lower metal content and potential elastic strain of the composite part before the initiation of the fiber damage process.
Highlights
Fiber metal laminates (FML) are a group of hybrid materials composed of alternating layers of metal and polymer-fiber composites [1]
Based on the analysis of the chart of the relation between maximum force and metal volume fraction in hybrid evaluatedtitanium–carbon the laminates withcomposite laminates (HTCL) under different impact energies, we found that the maximum force values do not change significantly depending on changes in the laminate MVF
The objective of the present work was to evaluate the influence of metal volume fractions to low-velocity impact resistance
Summary
Fiber metal laminates (FML) are a group of hybrid materials composed of alternating layers of metal and polymer-fiber composites [1] They are characterized by their favorable strength properties, notably high fatigue resistance [2], superior impact resistance [3,4], corrosion resistance [5], and fire resistance [1]. An improvement in the impact behavior of an FML obtained by using new types of metal alloys can be beneficial even if the costs are higher in comparison to the classic solutions (such as aluminum-based FML). This phenomenon is caused by the extra advantages of the new type of Materials 2020, 13, 103; doi:10.3390/ma13010103 www.mdpi.com/journal/materials
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