STUDY OF HEATING RATE EFFECT ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF TITANIUM COPPER ALLOYS USING SPARK PLASMA SINTERING METHOD
The number of Indonesia bone problems cases in 2010 reached 43,003 cases caused by traffic accidents and injuries during activities. This number will continue to grow because Indonesia's population is estimated to reach 273.65 million people with an estimated life expectancy of 73.7 years in...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/61510 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The number of Indonesia bone problems cases in 2010 reached 43,003 cases caused
by traffic accidents and injuries during activities. This number will continue to grow
because Indonesia's population is estimated to reach 273.65 million people with an
estimated life expectancy of 73.7 years in 2025. One of the solution that can be use
to overcome bone problems is bone implants. Titanium alloy has high strength,
elastic modulus that close to human bone, good biocompatibility, and good
corrosion resistance. The spark plasma sintering method is a technology that can
be used to produce high density bulk from the constituent powders.
In this study, spark plasma sintering was carried out on a titanium copper alloy.
The titanium alloy products of SPS then characterized to determine the effects in
microstructure and mechanical properties. The variables in this experiment were
the addition of 1, 3, and 5 wt% copper composition and heating rates of 25, 50, and
100°C/minute. The XRD analysis, relative density, grain size, SEM-EDS, hardness
properties, and compressive strength were compared for each variation.
The results showed that SPS can increase the value of crystal plane spacing,
increase the lattice parameters, decrease the crystallite size, and cause of different
crystal orientations. The higher the copper composition, the lower the relative
density in each variation of the heating rate. The highest relative density was
obtained at 50°C/min for each copper composition variation. The higher the
heating rate, the smaller the grain size. The optimum hardness value was achieved
at 50°C/min. The highest increase in hardness and compressive strength values was
obtained in Ti-1%Cu alloy. The factor that most influences the hardness value is
relative density. |
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