The effect of lamellar morphology on tensile and high-cycle fatigue behavior of orthorhombic Ti-22Al-27Nb alloy

The room-temperature tensile and high-cycle fatigue (HCF) behavior of orthorhombic Ti-22AI-27Nb alloy with varying lamellar morphology was investigated. Varying lamellar morphology was produced by changing the cooling rate after annealing in the single B2 phase region. A slower cooling rate of 0.003...

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Bibliographic Details
Published in:Metallurgical and materials transactions. A, Physical metallurgy and materials science Physical metallurgy and materials science, 2004-07, Vol.35 (7), p.2161-2170
Main Authors: HAGIWARA, Masuo, ARAOKA, Aya, SEUNG JIN YANG, EMURA, Satoshi, SOO WOO NAM
Format: Article
Language:English
Subjects:
Alloys
Cross-disciplinary physics: materials science
rheology
Exact sciences and technology
Fatigue, corrosion fatigue, embrittlement, cracking, fracture and failure
Fatigue, embrittlement, and fracture
Heat treating
Materials science
Metal fatigue
Microstructure
Physics
Tensile strength
Treatment of materials and its effects on microstructure and properties
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Summary:The room-temperature tensile and high-cycle fatigue (HCF) behavior of orthorhombic Ti-22AI-27Nb alloy with varying lamellar morphology was investigated. Varying lamellar morphology was produced by changing the cooling rate after annealing in the single B2 phase region. A slower cooling rate of 0.003 K/s, for example, resulted in several large packets or colonies of similarly aligned O-phase lamellae and a nearly continuous massive [alpha]^sub 2^ phase at the prior B2 grain boundaries, while a faster cooling rate of 0.1 K/s led to the refinement of colony sixes and the O-phase lamellae. The interface of O-phase lamellae and B2 phases was semicoherent. Water quenching produced a very fine tweed-like microstructure with a thin continuous O phase at the prior B2 grain boundaries. The 0.2 pet yield stress, tensile strength, and HCP strength increased with increasing cooling rate. For example, the tensile strength and HCF strength at 10^sup 7^ cycles of 0.003 and 0.1 K/s-cooled were 774 and 450 MPa, and 945 and 620 MPa, respectively. Since the fatigue ratio, which is the ratio of HCF strength at 10^sup 7^ cycles to tensile strength, did not show a constant value, but instead increased with increasing cooling rate, part of the fatigue improvement was the result of improved resistance to fatigue associated with the microstructural refinement of the lamellar morphology. Fatigue failure occurred by the subsurface initiation, and every initiation site was found to contain a flat facet. Concurrent observation of the fatigue initiation facet and the underlying microstructure revealed that the fatigue crack initiated in a shear mode across the colony, irrespective of colony size, indicating that the size of the initiation facet corresponded to that of the colony. Therefore, the colony size is likely a major controlling factor in determining the degree of fatigue improvement due to the microstructural refinement of lamellar morphology. For the water-quenched specimens, fatigue crack initiation appeared to he associated with shear cracking along the boundary between the continuous grain boundary O phase and the adjacent prior B2 grain. [PUBLICATION ABSTRACT]
ISSN:1073-5623
1543-1940
DOI:10.1007/s11661-004-0164-y