A New Multiaxial Fatigue Testing Method for Variable-Amplitude Loading and Stress Ratio-Reference-Cited by-同舟云学术

A New Multiaxial Fatigue Testing Method for Variable-Amplitude Loading and Stress Ratio

Published:2006-09-18 Issue:4 Volume:128 Page:857-864
ISSN:0742-4795
Container-title:Journal of Engineering for Gas Turbines and Power
language:en
Short-container-title:

Author:

George Tommy J.¹,Shen M.-H. Herman¹,Nicholas Theodore²,Cross Charles J.²

Affiliation:

1. Department of Aerospace Engineering and Aviation, The Ohio State University, Columbus, OH 43210

2. Air Force Research Laboratory, Wright-Patterson AFB, OH 45433

Abstract

A new vibration-based multiaxial fatigue testing methodology for assessing high-cycle turbine engine material fatigue strength at various stress ratios is presented. The idea is to accumulate fatigue energy on a base-excited plate specimen at high-frequency resonant modes and to complete a fatigue test in a much more efficient way at very low cost. The methodology consists of (1) a topological design procedure, incorporating a finite element model, to characterize the shape of the specimens for ensuring the required stress state/pattern, (2) a vibration feedback empirical procedure for achieving the high-cycle fatigue experiments with variable-amplitude loading, and finally (3) a yielding procedure for achieving various uniaxial stress ratios. The performance of the methodology is demonstrated by the experimental results from mild steel, 6061-T6 aluminum, and Ti-6Al-4V plate specimens subjected to fully reversed bending for both uniaxial and biaxial stress states.

Publisher

ASME International

Subject

Mechanical Engineering,Energy Engineering and Power Technology,Aerospace Engineering,Fuel Technology,Nuclear Energy and Engineering

Link

http://asmedigitalcollection.asme.org/gasturbinespower/article-pdf/128/4/857/5670391/857_1.pdf

Reference8 articles.

1. Goodman, J., 1899, Mechanics Applied to Engineering, Longmans, Green, and Co., London.

2. Nicholas, T., and Zuiker, J. R., 1996, “On the Use of the Goodman Diagram for High Cycle Fatigue Design,” Int. J. Fract., 80, pp. 219–235.

3. Nicholas, T., and Maxwell, D. C., 2002, “Mean Stress Effects on the High Cycle Fatigue Limit Stress in Ti-6Al-4V,” Fatigue and Fracture Mechanics: Vol. 33, ASTM STP 1417, Reuter, W. G., and Piascik, R. S., eds., American Society for Testing and Materials, West Conshohocken, PA, pp. 476–492.

4. Shen, M.-H. H., Seidt, J., George, T., Cross, C., Whaley, P. W., and Nicholas, T., 2001, “Development of A Novel Method for Evaluating Material Behavior under Turbine Engine Operating Conditions, Part I: Design of Accelerated HCF Testing Procedures,” 6th National Turbine Engine High Cycle Fatigue Conference, Jacksonville, FL, March 5-8.

5. Shen, M.-H. H., George, T., Seidt, J., Nicholas, T., and Cross, C., 2001, “Development of A Novel Method for Evaluating Material Behavior under Turbine Engine Operating Conditions, Part II: An Empirical Vibration-Based Fatigue Assessment Framework,” 6th National Turbine Engine High Cycle Fatigue Conference, Jacksonville, FL, March 5-8.

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