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Susceptibility to delayed fracture of alpha–beta titanium alloy in fluoride solutions
- Source :
- Corrosion Science. 47:1778-1793
- Publication Year :
- 2005
- Publisher :
- Elsevier BV, 2005.
-
Abstract
- The susceptibility to delayed fracture of the alpha–beta titanium alloy Ti–6Al–4V has been investigated in acidic and neutral fluoride solutions at room temperature. The time to fracture decreased with increasing applied stress in 2.0% and 0.2% acidulated phosphate fluoride (APF) solutions at pH 5.0. The time to fracture in the 2.0% APF solution was shorter than that in the 0.2% APF solution, although at an applied stress higher than 1000 MPa, the times to fracture were almost the same in both the solutions. For immersion in the 0.2% APF solution, when the applied stress was lower than 700 MPa, delayed fracture did not occur within 1000 h. The fracture surface of specimens immersed in the 2.0% APF solution exhibited brittleness associated with hydrogen absorption, while that in the 0.2% APF solution was ductile and characterized macroscopically as having a cup–cone morphology. The amounts of hydrogen absorbed in 2.0% and 0.2% APF solutions for 24 h were approximately 200 and 30 mass ppm, respectively. As the immersion time increased, the amount of hydrogen absorbed in the 2.0% APF solution increased, whereas that in the 0.2% APF solution hardly increased. In neutral 2.0% and 0.2% NaF solutions, the delayed fracture did not occur within 1000 h, although general corrosion was observed. These results indicate that the susceptibility to delayed fracture of alpha–beta titanium alloy, compared with those of the alpha titanium and beta titanium alloy reported previously, is low in acidic and neutral fluoride solutions.
- Subjects :
- Materials science
Hydrogen
General Chemical Engineering
Metallurgy
chemistry.chemical_element
Titanium alloy
General Chemistry
Corrosion
chemistry.chemical_compound
Acidulated Phosphate Fluoride
Brittleness
chemistry
Fracture (geology)
General Materials Science
Fluoride
Nuclear chemistry
Titanium
Subjects
Details
- ISSN :
- 0010938X
- Volume :
- 47
- Database :
- OpenAIRE
- Journal :
- Corrosion Science
- Accession number :
- edsair.doi...........0ff84a3e3b2bf65b4cab06dd090512f0