Your search keyword '"Feiger, J"' showing total 2 results

1. Fatigue Crack Growth Thresholds of Deflected Mixed-Mode Cracks in PWA1484.

Author

Chan, K. S., Feiger, J., Lee, Y.-D., John, R., and Hudak Jr., S. J.

Subjects

*CRYSTALS, *MATERIAL fatigue, *STRENGTH of materials, *CRYSTALLOGRAPHY, *MATERIALS, *ENGINEERING, *FRACTURE mechanics

Abstract

The fatigue crack growth (FCG) behavior of PWA1484 single crystals was characterized in air under mixed-mode loading at 593°C as a function of crystallographic orientation using an asymmetric four-point bend test technique. Most mixed-mode fatigue cracks deflected from the symmetry plane and propagated as transprecipitate, noncrystallographic cracks, while self-similar fatigue crack growth occurred on the (111) planes in (111)/[011] and (111)/[112] oriented crystals. The local stress intensity factors and the crack paths of the deflected mixed-mode cracks were analyzed using the finite-element fracture mechanics code, FRANC2D/L. The results indicated that the deflected crack path was close to being normal to the maximum tensile stress direction where the Mode II component diminishes. Crystallographic analysis of the deflected crack paths revealed that the Mode I and the deflected induced-mode cracks were usually of different crystallographic orientations and could exhibit different Mode I FCG thresholds when the crystallography of the crack paths differed substantially. These results were used to identify the driving force and conditions for cracking mode transition. [ABSTRACT FROM AUTHOR]

Published

2005

2. Nonlinear ultrasonic measurements with EMATs for detecting pre-cracking fatigue damage.

Author

Cobb, A., Capps, M., Duffer, C., Feiger, J., Robinson, K., and Hollingshaus, B.

Subjects

*NONLINEAR acoustics, *ULTRASONICS, *FRACTURE mechanics, *MATERIAL fatigue, *DEFORMATIONS (Mechanics), *ELECTROACOUSTIC transducers, *RAYLEIGH waves

Abstract

This paper describes an approach for measuring material degradation using nonlinear acoustics. The importance of this measurement is that prior efforts have shown that the degree of acoustic nonlinearity increases as a function of fatigue damage accumulation. By exploiting this physical mechanism, there is the potential to develop methods for measuring the remaining life of critical components. The challenge with existing approaches for measuring acoustic nonlinearity is that primarily they have only been shown to be successful in a laboratory setting. This paper presents a potential approach for field measurement of acoustic nonlinearity that utilizes Rayleigh waves generated from electromagnetic acoustic transducers (EMATs). Rayleigh waves have unique advantages because the sound propagates along the surface, allowing for application on complex engineering structures. EMATs were used in place of traditional piezoelectric transducers because the sound is generated directly in the metallic structure, eliminating the need for sound coupling fluids that are a source of variability. Custom EMATs were developed and nonlinearity measurements were performed on 410 stainless steel specimens that were subjected to a fatigue process. Some experiments showed an increase in the acoustic nonlinearity of up to 500% compared to the unfatigued value. Other experiments had too much scatter and did not show this relationship consistently due to unanticipated challenges in producing repeatable measurements. Lessons learned from the project effort will be presented to potentially improve the repeatability of the measurement approach. If the scatter can be reduced, this EMAT-based technique could result in a field deployable prognosis tool. [ABSTRACT FROM AUTHOR]

Published

2012