Rational processing of monitored ship voyage data for improved operation
This paper presents a method for the rational processing of ship voyage data for improved ship operation. The proposed approach is based on a physical modeling method, in which the ship resistance-propeller-engine model is first developed by using available ship information and basic hydrodynamics....
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sg-ntu-dr.10356-1547712022-01-07T07:05:59Z Rational processing of monitored ship voyage data for improved operation Liu, Shukui Loh, Meici Leow, Weichi Chen, Haoliang Shang, Baoguo Papanikolaou, Apostolos School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Propulsive Performance Analysis Mean Added Resistance in Short-Crested Waves This paper presents a method for the rational processing of ship voyage data for improved ship operation. The proposed approach is based on a physical modeling method, in which the ship resistance-propeller-engine model is first developed by using available ship information and basic hydrodynamics. For the analysis of operational scenarios in realistic environmental conditions, seaway data are retrieved from WaveWatchIII® hindcast (Tolman, 2002; WAVEWATCH, 2020). The added resistances due to wind is predicted using a standard method recommended by ITTC and the added resistance in waves using a newly developed semi-empirical method of Liu and Papanikolaou (2020). Then, the recorded speed-power data is projected to the calm water condition based on the resistance and thrust identity method. In a second step, we apply simple, yet rational, filtering criteria to filter out the data points polluted by ship's accelerations, the rate of change of course, as well as wave conditions. The developed processing and filtering method is applied to the analysis of the monitored data of three voyages of a chemical carrier and the obtained results are discussed. The prospects of extending the presented method to the study of a time-varying ship speed performance and fuel consumption analysis procedure, in which hull fouling can be studied, is briefly outlined. This study is partly conducted within the project of “Prediction of the added resistance of a ship in seaways for the rational determination of installed power” financially supported by the Sembcorp Marine Lab Fund. 2022-01-07T07:05:59Z 2022-01-07T07:05:59Z 2020 Journal Article Liu, S., Loh, M., Leow, W., Chen, H., Shang, B. & Papanikolaou, A. (2020). Rational processing of monitored ship voyage data for improved operation. Applied Ocean Research, 104, 102363-. https://dx.doi.org/10.1016/j.apor.2020.102363 0141-1187 https://hdl.handle.net/10356/154771 10.1016/j.apor.2020.102363 2-s2.0-85091674480 104 102363 en Applied Ocean Research © 2020 Elsevier Ltd. All rights reserved |
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Engineering::Mechanical engineering Propulsive Performance Analysis Mean Added Resistance in Short-Crested Waves |
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Engineering::Mechanical engineering Propulsive Performance Analysis Mean Added Resistance in Short-Crested Waves Liu, Shukui Loh, Meici Leow, Weichi Chen, Haoliang Shang, Baoguo Papanikolaou, Apostolos Rational processing of monitored ship voyage data for improved operation |
| description |
This paper presents a method for the rational processing of ship voyage data for improved ship operation. The proposed approach is based on a physical modeling method, in which the ship resistance-propeller-engine model is first developed by using available ship information and basic hydrodynamics. For the analysis of operational scenarios in realistic environmental conditions, seaway data are retrieved from WaveWatchIII® hindcast (Tolman, 2002; WAVEWATCH, 2020). The added resistances due to wind is predicted using a standard method recommended by ITTC and the added resistance in waves using a newly developed semi-empirical method of Liu and Papanikolaou (2020). Then, the recorded speed-power data is projected to the calm water condition based on the resistance and thrust identity method. In a second step, we apply simple, yet rational, filtering criteria to filter out the data points polluted by ship's accelerations, the rate of change of course, as well as wave conditions. The developed processing and filtering method is applied to the analysis of the monitored data of three voyages of a chemical carrier and the obtained results are discussed. The prospects of extending the presented method to the study of a time-varying ship speed performance and fuel consumption analysis procedure, in which hull fouling can be studied, is briefly outlined. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Liu, Shukui Loh, Meici Leow, Weichi Chen, Haoliang Shang, Baoguo Papanikolaou, Apostolos |
| format |
Article |
| author |
Liu, Shukui Loh, Meici Leow, Weichi Chen, Haoliang Shang, Baoguo Papanikolaou, Apostolos |
| author_sort |
Liu, Shukui |
| title |
Rational processing of monitored ship voyage data for improved operation |
| title_short |
Rational processing of monitored ship voyage data for improved operation |
| title_full |
Rational processing of monitored ship voyage data for improved operation |
| title_fullStr |
Rational processing of monitored ship voyage data for improved operation |
| title_full_unstemmed |
Rational processing of monitored ship voyage data for improved operation |
| title_sort |
rational processing of monitored ship voyage data for improved operation |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/154771 |
| _version_ |
1722355290528022528 |