EFFECT OF CU ADDITION ON STACKING FAULT ENERGY, MICROSTRUCTURE, AND MECHANICAL PROPERTIES OF COCRWNI ALLOY FOR BIOMEDICAL APPLICATION
The effect of Cu on the stacking fault, microstructure, and mechanical properties of Haynes 25 CoCrWNi alloy has been studied to develop an alloy for cardiac stent biomedical applications. Cobalt alloys have disadvantage of poor formability. The addition of Cu to the CoCrWNi alloy can increase th...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/73230 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The effect of Cu on the stacking fault, microstructure, and mechanical properties
of Haynes 25 CoCrWNi alloy has been studied to develop an alloy for cardiac
stent biomedical applications. Cobalt alloys have disadvantage of poor
formability. The addition of Cu to the CoCrWNi alloy can increase the value of
stacking fault energy, biocompatibility, and formability. This research studies
the microstructure, mechanical properties, and stacking fault energy of the
CoCrWNi alloy with the addition of Cu. CoCrWNi alloy was added with Cu
using argon arc melting in an argon atmosphere with a concentration of 1.5-
4.5% weight percentage and homogenized in a horizontal tube furnace at 1000
oC for 8 hours. The XRD test showed that the addition of Cu up to 4.5% weight
percentage stabilized the fcc-? phase and suppressed the formation of the hcp-?
phase in the CoCrWNi alloy. Microstructural observations of the CoCrWNi
alloy indicated that there was twinning in the alloy without the addition of Cu.
CoCrWNi alloy with the addition of Cu produces a dendritic-shaped
microstructure. The hardness and compressive test mechanical properties of the
CoCrWNi alloy decreased after the addition of Cu. The addition of Cu can
prevent the formation of stacking faults in the microstructure. CoCrWNi alloy
without the addition of Cu which has uniaxial hardness and stress values of
455.3 HV and 728.08 MPa. Whereas the CoCrWNi alloy with the addition of 4.5
wt.% Cu alloy produced the lowest values of hardness and uniaxial compressive
stress, 270.2 HV and 141.97 MPa. The CoCrWNi-Cu alloy samples that
experienced deformation after the compression test experienced an increase in
hardness values. This is the effect of strain induced martensitic transformation
(SIMT) in encouraging the formation of martensite and reduction of grain size.
The CoCrWNi-Cu alloy can be calculated for the value of the stacking fault
energy using the XRD, first-principle, and thermodynamic analysis methods.
The addition of Cu alloying elements can increase the value of the stacking fault
energy of the CoCrWNi alloy. The stacking fault energy values affect the
mechanical properties of the CoCrWNi-xCu alloy. A higher stacking fault
energy value indicates a lower stacking fault probability, so it tends to be more
difficult to form a stacking fault. |
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