Very high cycle fatigue assessment of thermoplastic-based hybrid fiber metal laminate by using a high-frequency resonant testing system
Selim Mrzljak, Maik Trautmann, Guntram Wagner, Frank Walther
Abstract
• For the first time, a 1,000 Hz high-frequency resonance testing system is used to establish a timely efficient characterization methodology for fiber metal laminates. • A novel approach offers the advantages of load-controlled testing while enabling short test duration and maintaining comparability to results gathered on conventional testing systems (like servo-hydraulics). • Fatigue evolution analysis using high-speed cameras enables the distinction between high and very high cycle fatigue-related damage in fiber metal laminates. • Thermoplastic-based fiber metal laminate is a possible material candidate for more sustainable long-term fatigue applications. The prolonged fatigue lifetime of fiber metal laminates (FML) compared to monolithic metals is a key aspect for safety-relevant components, where detailed knowledge about the fatigue properties up to the very high cycle fatigue (VHCF) regime is necessary. For thermoplastic-based FMLs, offering formability, recyclability, and mass production due to short consolidation cycle times, this knowledge needs to be established. In this study, FML containing AA6082 sheets and unidirectional glass and carbon fiber-reinforced polyamide 6 was investigated. Fatigue tests up to max. 10 9 cycles were conducted on a servo-hydraulic and a high-frequency resonant fatigue testing system with frequencies of 10 Hz and 1,000 Hz. Frequency-induced self-heating was evaluated and limited using air-cooling to maintain the matrix properties. Fatigue progress was monitored through high-speed optical deformation analysis. Compared to HCF loads, VHCF loads lead to reduced crack and delamination occurrence. Changes in microstructure are dominated by singular crack initiation and propagation within the aluminum. The FML’s S-N curve shows a significant flattening from the HCF to the VHCF regime, simplifying the predictability of the fatigue life. By using post-stretching, the VHCF strength can be increased by over 60 %, making this thermoplastic-based FML a considerable competitor in the field of FML.