LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION.
Jabodebek Light Rail Transit (LRT) is a new public transportation in Indonesia. To ensure the safety of passengers, LRT carbody must satisfy the requirement of static and dynamic loading. The regulations used as a references in this study are PM 175 Tahun 2015, JIS E7105, and EN 12663. Base mode...
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id-itb.:569532021-07-22T20:29:12ZLRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. Rifdan Hananzah, Nauval Teknik (Rekayasa, enjinering dan kegiatan berkaitan) Indonesia Final Project LRT Carbody, Multi-cell, Taguchi’s Method, Static Load, Free Vibration. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/56953 Jabodebek Light Rail Transit (LRT) is a new public transportation in Indonesia. To ensure the safety of passengers, LRT carbody must satisfy the requirement of static and dynamic loading. The regulations used as a references in this study are PM 175 Tahun 2015, JIS E7105, and EN 12663. Base model used in this research is the carbody of Jabodebek LRT. This research was conducted to optimize the side sill components of LRT carbody using Taguchi method and Analysis of Variance (ANOVA) to obtain optimum deformation and mass. In this optimization process, there are 3 control factors that will be varied, which are multi-cell geometry, column thickness, and web thickness. The optimization results showed the most optimum configuration was the multi-cell geometry of single cruciform, column thickness of 9 mm, and web thickness of 7 mm. Then, the optimum structure of the carbody is analyzed under static loading and free vibration. The results of static loading simulations showed that the stress and deformation that occurred had met the requirements of the regulation, which are stress below 75% yield strength (multiply by 1.05 safety factor) and deformation below 11.5 mm. Free vibration tests have shown the bending modes and torsion modes along with the frequency. These modes can provide information about the response of the LRT carbody structure when it resonates. In addition, local bending modes on the end wall structure still occur at low frequencies. However, this local mode has little effect on the dynamic response of the carbody, so it can be simply ignored. text |
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Teknik (Rekayasa, enjinering dan kegiatan berkaitan) Rifdan Hananzah, Nauval LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| description |
Jabodebek Light Rail Transit (LRT) is a new public transportation in
Indonesia. To ensure the safety of passengers, LRT carbody must satisfy the
requirement of static and dynamic loading. The regulations used as a references in
this study are PM 175 Tahun 2015, JIS E7105, and EN 12663.
Base model used in this research is the carbody of Jabodebek LRT. This
research was conducted to optimize the side sill components of LRT carbody using
Taguchi method and Analysis of Variance (ANOVA) to obtain optimum deformation
and mass. In this optimization process, there are 3 control factors that will be
varied, which are multi-cell geometry, column thickness, and web thickness. The
optimization results showed the most optimum configuration was the multi-cell
geometry of single cruciform, column thickness of 9 mm, and web thickness of 7
mm. Then, the optimum structure of the carbody is analyzed under static loading
and free vibration. The results of static loading simulations showed that the stress
and deformation that occurred had met the requirements of the regulation, which
are stress below 75% yield strength (multiply by 1.05 safety factor) and
deformation below 11.5 mm. Free vibration tests have shown the bending modes
and torsion modes along with the frequency. These modes can provide information
about the response of the LRT carbody structure when it resonates. In addition,
local bending modes on the end wall structure still occur at low frequencies.
However, this local mode has little effect on the dynamic response of the carbody,
so it can be simply ignored.
|
| format |
Final Project |
| author |
Rifdan Hananzah, Nauval |
| author_facet |
Rifdan Hananzah, Nauval |
| author_sort |
Rifdan Hananzah, Nauval |
| title |
LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| title_short |
LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| title_full |
LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| title_fullStr |
LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| title_full_unstemmed |
LRT CARBODY, MULTI-CELL, TAGUCHIâS METHOD, STATIC LOAD, FREE VIBRATION. |
| title_sort |
lrt carbody, multi-cell, taguchiâs method, static load, free vibration. |
| url |
https://digilib.itb.ac.id/gdl/view/56953 |
| _version_ |
1822930331050704896 |