This open access dissertation explores how manufacturing-induced residual stress states in fiber metal laminates (FMLs) affect a structural health monitoring (SHM) system. SHM is a promising technology for monitoring the structural integrity during operation. SHM systems using guided ultrasonic waves (GUWs) enable the detection of damage located inside a laminate and are, therefore, particularly suitable for FMLs due to their complex damage characteristics. Experimental methods for quantifying residual stresses in FMLs are developed and evaluated. This work shows that process strains can be measured throughout manufacturing with sensors integrated into the laminate. The strain measurements verify different modified cure cycles to change residual stress states in FMLs consisting of carbon-fiber-reinforced polymer (CFRP) and steel. To avoid complex sensor technology in industrial manufacturing processes, a robust method is additionally presented that derives a process-specific parameter, the stress-free temperature, from asymmetrical reference laminates. The quantified residual stress states in various CFRP-steel laminates allow the experimental investigation of the influence of stress on the propagation velocity of fundamental GUWs. With laser-scanning-vibrometry, dispersion diagrams for various FMLs over a wide frequency range are experimentally determined. The results show no significant influence of the residual stress states on the phase velocity of the fundamental symmetric and asymmetric GUW modes for the investigated FMLs. In contrast, comparative measurements under external tensile prestress show a considerable increase in phase velocity with increasing prestress for both fundamental GUW. Finally, fatigue tests are performed on CFRP-steel laminates to investigate the influence of different residual stress states on the residual life prediction capabilities of an SHM system. The results show that reducing residual stresses through modified cure cycles delays crack initiation, reduces crack propagation velocity, and, consequently, extends the fatigue life of the investigated FMLs.

This book is open access, which means that you have free and unlimited access Novel Residual Stress Measurement Technique Residual Stress Influence on Wave Propagation Broad Experimental Validation

Autorentext

The author is recognized for his extensive expertise in structural health monitoring and composite manufacturing, as evidenced by multiple publications in peer-reviewed journals. Over the years, he has broadened his knowledge by collaborating with leading research institutions in the United States and Canada, further developing his proficiency in these fields.

Klappentext

This open access dissertation investigates how manufacturing-induced residual stresses in fiber metal laminates (FMLs) affect structural health monitoring (SHM) systems. SHM using guided ultrasonic waves (GUWs) enables internal damage detection and suits FMLs due to their complex damage characteristics.

Experimental methods are developed to quantify residual stresses, including sensor-based strain measurements during manufacturing. These validate modified cure cycles aimed at influencing stress states in FMLs consisting of carbon-fiber-reinforced polymer and steel. A simplified method based on the stress-free temperature from asymmetrical reference laminates complements these measurements.

The measured residual stresses enable studying their effect on GUW propagation. Dispersion diagrams obtained via laser-scanning vibrometry show no significant influence of residual stress on the phase velocity of fundamental GUW modes. In contrast, external tensile prestress increases wave velocity, highlighting the need to account for such loads in SHM.

Fatigue tests show that reducing residual stresses through modified cure cycles delays crack initiation and slows propagation, improving fatigue life. Two key conclusions follow: First, while residual stresses have little effect on wave speed, external loads do and must be considered in SHM. Second, knowing the residual stress state enhances remaining service life predictions after damage detection. These findings advance SHM technology for FMLs by linking residual stress to SHM-relevant parameters.  

The Author

Johannes Wiedemann is recognized for his expertise in structural health monitoring and composite manufacturing, as evidenced by numerous peer-reviewed publications. His collaboration with leading research institutions worldwide deepened his proficiency in these fields.

Inhalt

Motivation.- Material Characteristics and Structural Health Monitoring of Fiber Metal Laminates.- Materials and Manufacturing.- Residual Stress Quantification Using Strain Gages.- Residual Stress Quantification Using Asymmetric Laminates.- Residual Stress Influence on Gueided Ultrasonic Wave Propagation.- Residual Stress Influence on Fatigue Life.- Conclusion and Outlook.