论文信息 - Behavior of Long Fatigue Cracks in Cellular Box Beam

Behavior of Long Fatigue Cracks in Cellular Box Beam

The propagation of long cracks under constant amplitude cyclic loading is studied in complex welded box beams made of high strength low alloy (HSLA) steel. The 8 x 1 x 0.7 m box beams were designed to simulate the cellular structure of a double hull ship but the results of the experiments are equally applicable to other box systems such as bridges. These experiments were designed to evaluate the residual fatigue life after a significant fatigue crack has formed. After testing, residual stresses were measured on two box beams using the standardized strain gage hole-drilling method. The experiment results demonstrated the good crack tolerance of cellular structures. The residual life of a box beam (after a welded detail has failed) was significant. The crack driving force was evaluated using finite element modeling. Reasonable correlation between these large scale tests and the fatigue crack growth rate from small compact specimen was obtained only with models that included the effects of crack closure due to residual stresses. Linear elastic fracture mechanics proved to be sufficient to predict the behavior of long cracks in this case.

[1] N. Tebedge,et al. Residual-stress measurement by the sectioning method , 1973 .

[2] P. C. Paris,et al. A Critical Analysis of Crack Propagation Laws , 1963 .

[3] C. Ruud,et al. Nondestructive and Semidestructive Methods for Residual Stress Measurement , 1982 .

[4] E. W. C. Wilkins,et al. Cumulative damage in fatigue , 1956 .

[5] K. Chan,et al. Scaling laws for fatigue crack , 1993, Metallurgical and Materials Transactions A.

[6] H.L.J. Pang,et al. Linear elastic fracture mechanics benchmarks: 2D finite element test cases , 1993 .

[7] J. Schijve. Fatigue Crack Closure: Observations and Technical Significance , 1986 .

[8] M. Kanninen,et al. A finite element calculation of stress intensity factors by a modified crack closure integral , 1977 .

[9] J. Harvey Evans,et al. Ship structural design concepts , 1974 .

[10] Jerome P. Sikora,et al. A METHOD FOR ESTIMATING LIFETIME LOADS AND FATIGUE LIVES FOR SWATH AND CONVENTIONAL MONOHULL SHIPS , 1983 .

[11] J K Paik,et al. DETERMINISTIC AND PROBABILISTIC SAFETY EVALUATION FOR A NEW DOUBLE-HULL TANKER WITH TRANSVERSELESS SYSTEM , 1992 .

[12] Pedro Albrecht,et al. Fatigue and fracture of steel bridges , 2000 .

[13] T. Okamoto,et al. STRENGTH EVALUATION OF NOVEL UNIDIRECTIONAL-GIRDER-SYSTEM PRODUCT OIL CARRIER BY RELIABILITY ANALYSIS , 1985 .

[14] Anthony P. Parker,et al. Stress Intensity Factors, Crack Profiles, and Fatigue Crack Growth Rates in Residual Stress Fields , 1982 .