Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013.
Gas Turbines which is used in industries, especially for power generating, must be working optimal and efficient as high as possible. Therefore, the reability and availability of the gas turbine shall have a high value. In the end of 2009, GTG Kujang 1B had a catastrophic failure due to first sta...
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id-itb.:407952019-07-12T10:29:29ZFailure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. Fendy Pratama, Arfianto Indonesia Final Project Gas Turbine, GTG, TIT, creep, reability. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/40795 Gas Turbines which is used in industries, especially for power generating, must be working optimal and efficient as high as possible. Therefore, the reability and availability of the gas turbine shall have a high value. In the end of 2009, GTG Kujang 1B had a catastrophic failure due to first stage turbine nozzle had been sustained creep-low cycle fatigue. In January 2013, GTG Kujang 1B experienced failure by similar modus therefore failure analysis must be conducted to find the root cause, so we could prevent it from failure in the future. Reability analysis has to be done to obtain information whether the operation and maintenance of the Gas Turbine Generator (GTG) Kujang 1B is doing well or not. Before the calculation of reability paramaters begins, GTG downtime datas must be classified to two type of time (shutdown time and breakdown time). This happens due to receive more accurate results. To get perfomance paramaters of GTG Kujang 1B, particularly turbine inlet temperatur (TIT) and combustion process. These calculations are used to assist in conducting failure analysis of GTG. GTG’s failure occured because of the turbine nozzles in the first stage had failed. This nozzle had been failed by creep due to the combustion gases flew continually with high temperature. The damaged nozzle which was being degraded because its toughness had been weaken was causing FOD to lower stage of the turbine. text |
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Gas Turbines which is used in industries, especially for power generating,
must be working optimal and efficient as high as possible. Therefore, the reability
and availability of the gas turbine shall have a high value. In the end of 2009,
GTG Kujang 1B had a catastrophic failure due to first stage turbine nozzle had
been sustained creep-low cycle fatigue. In January 2013, GTG Kujang 1B
experienced failure by similar modus therefore failure analysis must be conducted
to find the root cause, so we could prevent it from failure in the future.
Reability analysis has to be done to obtain information whether the
operation and maintenance of the Gas Turbine Generator (GTG) Kujang 1B is
doing well or not. Before the calculation of reability paramaters begins, GTG
downtime datas must be classified to two type of time (shutdown time and
breakdown time). This happens due to receive more accurate results.
To get perfomance paramaters of GTG Kujang 1B, particularly turbine
inlet temperatur (TIT) and combustion process. These calculations are used to
assist in conducting failure analysis of GTG.
GTG’s failure occured because of the turbine nozzles in the first stage had
failed. This nozzle had been failed by creep due to the combustion gases flew
continually with high temperature. The damaged nozzle which was being
degraded because its toughness had been weaken was causing FOD to lower stage
of the turbine. |
| format |
Final Project |
| author |
Fendy Pratama, Arfianto |
| spellingShingle |
Fendy Pratama, Arfianto Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| author_facet |
Fendy Pratama, Arfianto |
| author_sort |
Fendy Pratama, Arfianto |
| title |
Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| title_short |
Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| title_full |
Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| title_fullStr |
Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| title_full_unstemmed |
Failure Analysis of Gas Turbine Generator (GTG) 14.25 MW Case Study: GTG Kujang 1Bâs Failure at January 19th 2013. |
| title_sort |
failure analysis of gas turbine generator (gtg) 14.25 mw case study: gtg kujang 1bâs failure at january 19th 2013. |
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https://digilib.itb.ac.id/gdl/view/40795 |
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