Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide
Microwave sintering has become one of the well-known sintering processing methods used by researchers to replace the conventional sintering process. The use of microwave for sintering in powder metallurgy has promoted cost reduction and energy savings for the industries. Microwave sintering ha...
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my-upm-ir.696212019-07-03T07:42:13Z Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide 2018-08 Daud, Siti Nurul Adura Microwave sintering has become one of the well-known sintering processing methods used by researchers to replace the conventional sintering process. The use of microwave for sintering in powder metallurgy has promoted cost reduction and energy savings for the industries. Microwave sintering has also been studied to sinter various kinds of Metal Matrix Composites (MMCs). The latest technology had combined microwave and conventional sintering into microwave hybrid sintering. In this research, the use of microwave hybrid sintering has been studied in terms of its viability to sinter the metal matrix composite of iron and silicon carbide (Fe/SiC). Comparison of the sintering processes and performance, physical (relative density, shrinkage and microstructure) and mechanical (tensile strength and hardness) properties of Fe/SiC were made for the samples sintered by both sintering processes. In order to determine the relative density and the shrinkage, the direct measurements were taken using Vernier caliper while for microstructure analysis, the morphology tests were conducted using Field Emission Scanning Electron Microscope (FESEM). For physical properties, the Brazillian Disc Test was conducted to analyze the tensile strength and Rockwell Hardness Tester was used to analyze the hardness. Three different compositions of Fe/SiC which are pure Fe, Fe-10SiC and Fe-20SiC were studied. The sintering temperatures used for both sintering processes were fixed at 1000 oC, 1050 oC, 1100 oC and 1200 oC with a heating rate of 10 oC/min and soaking time of 45 minutes in argon atmosphere. Fe-10SiC and Fe-20SiC were found damaged when sintered using microwave hybrid sintering at temperature above 1050 oC. The overall results show that Fe/SiC sintered by microwave hybrid had a faster sintering time compared to conventional sintering and the best sintering temperature to sinter Fe/SiC using microwave hybrid sintering was 1000 oC. In addition, the results also show that relatively higher shrinkage and swelling occurred for samples sintered under microwave hybrid process. The addition of SiC led to the decrease in the relative densities of the sintered Fe/SiC samples. The tensile strength of the Fe/SiC samples decreased with the increased in the SiC content. Microwave hybrid sintering produced samples with relatively higher tensile strength values, especially for pure Fe and for 10 wt. % added SiC at 1050⁰C sintering temperature different compositions of Fe/SiC which are pure Fe, Fe-10SiC and Fe-20SiC were studied. The sintering temperatures used for both sintering processes were fixed at 1000 oC, 1050 oC, 1100 oC and 1200 oC with a heating rate of 10 oC/min and soaking time of 45 minutes in argon atmosphere. Fe-10SiC and Fe-20SiC were found damaged when sintered using microwave hybrid sintering at temperature above 1050 oC. The overall results show that Fe/SiC sintered by microwave hybrid had a faster sintering time compared to conventional sintering and the best sintering temperature to sinter Fe/SiC using microwave hybrid sintering was 1000 oC. In addition, the results also show that relatively higher shrinkage and swelling occurred for samples sintered under microwave hybrid process. The addition of SiC led to the decrease in the relative densities of the sintered Fe/SiC samples. The tensile strength of the Fe/SiC samples decreased with the increased in the SiC content. Microwave hybrid sintering produced samples with relatively higher tensile strength values, especially for pure Fe and for 10 wt. % added SiC at 1050⁰C sintering temperature. Sinter (Metallurgy) - Case studies Microwave heating Powder metallurgy 2018-08 Thesis http://psasir.upm.edu.my/id/eprint/69621/ http://psasir.upm.edu.my/id/eprint/69621/1/fk%202018%20111%20ir.pdf text en public masters Universiti Putra Malaysia Sinter (Metallurgy) - Case studies Microwave heating Powder metallurgy |
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| topic |
Sinter (Metallurgy) - Case studies Microwave heating Powder metallurgy |
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Sinter (Metallurgy) - Case studies Microwave heating Powder metallurgy Daud, Siti Nurul Adura Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| description |
Microwave sintering has become one of the well-known sintering processing methods
used by researchers to replace the conventional sintering process. The use of
microwave for sintering in powder metallurgy has promoted cost reduction and energy
savings for the industries. Microwave sintering has also been studied to sinter various
kinds of Metal Matrix Composites (MMCs). The latest technology had combined
microwave and conventional sintering into microwave hybrid sintering. In this
research, the use of microwave hybrid sintering has been studied in terms of its
viability to sinter the metal matrix composite of iron and silicon carbide (Fe/SiC).
Comparison of the sintering processes and performance, physical (relative density,
shrinkage and microstructure) and mechanical (tensile strength and hardness)
properties of Fe/SiC were made for the samples sintered by both sintering processes.
In order to determine the relative density and the shrinkage, the direct measurements
were taken using Vernier caliper while for microstructure analysis, the morphology
tests were conducted using Field Emission Scanning Electron Microscope (FESEM).
For physical properties, the Brazillian Disc Test was conducted to analyze the tensile
strength and Rockwell Hardness Tester was used to analyze the hardness. Three
different compositions of Fe/SiC which are pure Fe, Fe-10SiC and Fe-20SiC were
studied. The sintering temperatures used for both sintering processes were fixed at
1000 oC, 1050 oC, 1100 oC and 1200 oC with a heating rate of 10 oC/min and soaking
time of 45 minutes in argon atmosphere. Fe-10SiC and Fe-20SiC were found damaged
when sintered using microwave hybrid sintering at temperature above 1050 oC. The
overall results show that Fe/SiC sintered by microwave hybrid had a faster sintering
time compared to conventional sintering and the best sintering temperature to sinter
Fe/SiC using microwave hybrid sintering was 1000 oC. In addition, the results also
show that relatively higher shrinkage and swelling occurred for samples sintered under
microwave hybrid process. The addition of SiC led to the decrease in the relative
densities of the sintered Fe/SiC samples. The tensile strength of the Fe/SiC samples
decreased with the increased in the SiC content. Microwave hybrid sintering produced samples with relatively higher tensile strength values, especially for pure Fe and for
10 wt. % added SiC at 1050⁰C sintering temperature
different compositions of Fe/SiC which are pure Fe, Fe-10SiC and Fe-20SiC were
studied. The sintering temperatures used for both sintering processes were fixed at
1000 oC, 1050 oC, 1100 oC and 1200 oC with a heating rate of 10 oC/min and soaking
time of 45 minutes in argon atmosphere. Fe-10SiC and Fe-20SiC were found damaged
when sintered using microwave hybrid sintering at temperature above 1050 oC. The
overall results show that Fe/SiC sintered by microwave hybrid had a faster sintering
time compared to conventional sintering and the best sintering temperature to sinter
Fe/SiC using microwave hybrid sintering was 1000 oC. In addition, the results also
show that relatively higher shrinkage and swelling occurred for samples sintered under
microwave hybrid process. The addition of SiC led to the decrease in the relative
densities of the sintered Fe/SiC samples. The tensile strength of the Fe/SiC samples
decreased with the increased in the SiC content. Microwave hybrid sintering produced
samples with relatively higher tensile strength values, especially for pure Fe and for
10 wt. % added SiC at 1050⁰C sintering temperature. |
| format |
Thesis |
| qualification_level |
Master's degree |
| author |
Daud, Siti Nurul Adura |
| author_facet |
Daud, Siti Nurul Adura |
| author_sort |
Daud, Siti Nurul Adura |
| title |
Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| title_short |
Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| title_full |
Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| title_fullStr |
Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| title_full_unstemmed |
Process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| title_sort |
process performance and characterization of microwave hybrid and conventional sintering methods on iron/silicon carbide |
| granting_institution |
Universiti Putra Malaysia |
| publishDate |
2018 |
| url |
http://psasir.upm.edu.my/id/eprint/69621/1/fk%202018%20111%20ir.pdf |
| _version_ |
1747812714027155456 |