Issue |
J. Phys. IV France
Volume 112, October 2003
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|
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Page(s) | 747 - 749 | |
DOI | https://doi.org/10.1051/jp4:2003990 |
J. Phys. IV France 112 (2003) 747
DOI: 10.1051/jp4:2003990
process during heat treatment on martensitic transformation in Ni-Ti and Ni-Ti-Cr alloys
J. Uchil, K.G. Kumara and K.K. MaheshDepartment of Materials Science, Mangalore University, Mangalagangotri, Mangalore 574199, India
Abstract
This paper presents the effect of cooling process during heat treatment on martensitic transformation
in 45% cold worked, Ti-rich, Ni-rich Ni-Ti and Ni-Ti-Cr shape memory alloys, annealed in the temperature
range of
C. Phase transformation in water quenched and fumace cooled samples is
studied in the range from
to
C, employing four-probe electrical resistivity
measurement technique. The heat treatment process has a distinct effect on the martensitic transformation
in these alloy systems. In the case of Ti-rich alloy two-stage martensitic transformation,
during cooling and M
A on heating, are observed in the as-received sample. For both the
quenched and the fumace cooled samples this behavior persists even after annealing at 420°C.
The process spreads over a temperature interval of 60°, above 0°C, whereas, after annealing
above 420°C only A
M transformation is observed. Ni-rich quenched alloy annealed
below 500°C exhibits a two-stage martensitic transformation, spreading over a wide temperature
interval of 150°, below +50°C. For that alloy annealed above 500°C, R-phase gradually
decays narrowing the transformation region. In the furnace cooled sample, R-phase region steadily narrows,
for annealing at temperatures up to 580°C, suddenly broadens for annealing above 580°C and persists
prominently thereafter. In the case of Ni-Ti-Cr, though for both the processes two-stage martensitic
transformation is exhibited, for quenched one, R-phase disappears for annealing temperatures above
600°C. Thus, fumace cooling is found to promote the intennediate R-phase in Ni-rich Ni-Ti and
Ni-Ti-Cr alloys annealed at higher temperature also.
© EDP Sciences 2003