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Ships and Offshore Structures Volume 18, 2023 - Issue 7
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Articles

Operability analysis of traditional small fishing boats in Indonesia with different loading conditions

Muhammad Iqbala Department of Naval Architecture, Ocean and Marine Engineering, Henry Dyer Building, University of Strathclyde, Glasgow, UK;b Department of Naval Architecture, Diponegoro University, Semarang, IndonesiaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0003-3762-3757
ORCID Icon,
Momchil Terzieva Department of Naval Architecture, Ocean and Marine Engineering, Henry Dyer Building, University of Strathclyde, Glasgow, UKORCID Iconhttps://orcid.org/0000-0002-1664-6186
ORCID Icon,
Tahsin Tezdogana Department of Naval Architecture, Ocean and Marine Engineering, Henry Dyer Building, University of Strathclyde, Glasgow, UKORCID Iconhttps://orcid.org/0000-0002-7032-3038
ORCID Icon &
Atilla Incecika Department of Naval Architecture, Ocean and Marine Engineering, Henry Dyer Building, University of Strathclyde, Glasgow, UKORCID Iconhttps://orcid.org/0000-0001-6584-6320
ORCID Icon
Pages 1060-1079 | Received 14 Mar 2022, Accepted 26 Jul 2022, Published online: 04 Aug 2022

References

  • Baitis AE, Holcombe F, Conwell S, Crossland P, Colwell J, Pattison J, Strong R. 1995. Motion Induced Interruption (MII) and Motion Induced Fatigue (MIF) Experiments at the Naval Biodynamics Laboratory.
  • Bappenas. 2010. Presidential Regulation No. 5 of 2010 concerning the National Medium-Term Development Plan (in Indonesian).
  • Beck RF, Liapis S. 1987. Transient motions of floating bodies at zero forward speed. J Ship Res. 31:164–176.
  • Caamaño LS, Galeazzi R, Nielsen UD, González MM, Casás VD. 2019. Real-time detection of transverse stability changes in fishing vessels. Ocean Eng. 189:106369.
  • Caamaño LS, González MM, Casás VD. 2018. On the feasibility of a real time stability assessment for fishing vessels. Ocean Eng. 159:76–87.
  • Datta R, Rodrigues JM, Soares CG. 2011. Study of the motions of fishing vessels by a time domain panel method. Ocean Eng. 38:782–792. doi:10.1016/j.oceaneng.2011.02.002.
  • Davis B, Colbourne B, Molyneux D. 2019. Analysis of fishing vessel capsizing causes and links to operator stability training. Saf Sci. 118:355–363.
  • Deakin B. 2005. An experimental evaluation of the stability criteria of the HSC Code, in: International Conference on Fast Sea Transportation, FAST.
  • Deakin B. 2006. Developing simple safety guidance for fishermen, In: 9th International Conference on Stability of Ships and Ocean Vehicles, Rio de Janeiro, Brasil.
  • Djatmiko EB. 2012. Behavior and operability of marine buildings on random waves (in Indonesian). Surabaya. Indones: ITS-Press.
  • Domeh V, Obeng F, Khan F, Bose N, Sanli E. 2021. Risk analysis of man overboard scenario in a small fishing vessel. Ocean Eng. 229:108979.
  • Eriksen JH, Nona RA, Mas C. 2000. Common procedures for seakeeping in the ship design process. STANAG 4154, 2000.
  • FAO. 2000. The State of World Fisheries and Aquaculture Part 2: Selected Issues Facing Fishers and Aquaculturists, the State of World Fisheries and Aquaculture. Food & Agriculture Org.
  • Fonseca N, Soares CG. 2002. Sensitivity of the expected ships availability to different seakeeping criteria, in: International Conference on Offshore Mechanics and Arctic Engineering. pp. 595–603.
  • Ghaemi MH, Olszewski H. 2017. Total ship operability –review, concept and criteria. Pol Marit Res. 24:74–81.
  • González MM, Sobrino PC, Álvarez RT, Casás VD, López AM, Peña FL. 2012. Fishing vessel stability assessment system. Ocean Eng. 41:67–78.
  • Gutsch M, Sprenger F, Steen S. 2017. Design parameters for increased operability of offshore crane vessels, in: International Conference on Offshore Mechanics and Arctic Engineering. p. V009T12A029.
  • Gutsch M, Steen S, Sprenger F. 2020. Operability robustness index as seakeeping performance criterion for offshore vessels. Ocean Eng. 217:107931.
  • Hasselmann K, Barnett TP, Bouws E, Carlson H, Cartwright DE, Enke K, Ewing JA, Gienapp A, Hasselmann DE, Kruseman P, Meerburg A. 1973. Measurements of wind-wave growth and swell decay during the Joint North Sea Wave Project (JONSWAP). Ergaenzungsh. zur Dtsch. Hydrogr. Zeitschrift, R. A.
  • He G, Kashiwagi M. 2014. A time-domain higher-order boundary element method for 3D forward-speed radiation and diffraction problems. J Mar Sci Technol. 19:228–244.
  • Himeno Y. 1981. Prediction of ship roll damping-state of the art. Univ. Michigan, Coll. Eng. Dep. Nav. Archit. Mar. Eng. USA, Rep. No. 239.
  • Ikeda Y. 1979. On roll damping force of ship-effect of hull surface pressure created by bilge keels. Univ. Osaka Pref. Dep. Nav. Archit. Japan, Rep. No. 00402, Publ. J. Soc. Nav. Archit. Japan, No. 165, 1979.
  • Ikeda Y, Himeno Y, Tanaka N. 1977. On eddy making component of roll damping force on naked hull. J Soc Nav Archit Japan. 1977:54–64.
  • IMO. 2008. International Code on Intact Stability (IS Code).
  • ISSC. 1964. Proceedings of the 2nd International Ship Structures Congress. Delft, The Netherlands.
  • ITTC. 2002. Final report and recommendations to the 23rd ITTC. Proceeding 23rd ITTC Spec. Comm. Waves.
  • Jin D, Thunberg E. 2005. An analysis of fishing vessel accidents in fishing areas off the northeastern United States. Saf Sci. 43:523–540.
  • Kato H. 1957. On the frictional resistance to the rolling of ships. J Zosen Kiokai. 1957:115–122.
  • Liapis SJ, Beck R. 1985. Seekeeping computations using time-domain analysis, in: Proceeding of the Fourth International Symposium on Numerical Hydrodynamics. pp. 34–54.
  • Liu PC. 1971. Normalized and equilibrium spectra of wind waves in lake michigan. J Phys Oceanogr. 1:249–257.
  • Liu W, Demirel YK, Djatmiko EB, Nugroho S, Tezdogan T, Kurt RE, Supomo H, Baihaqi I, Yuan Z, Incecik A. 2019. Bilge keel design for the traditional fishing boats of Indonesia’s east java. Int J Nav Archit Ocean Eng. 11:380–395.
  • Mantari JL, E Silva SR, Soares CG. 2011. Intact stability of fishing vessels under combined action of fishing gear, beam waves and wind. Ocean Eng. 38:1989–1999.
  • Mata-Álvarez-Santullano F, Souto-Iglesias A. 2014. Stability, safety and operability of small fishing vessels. Ocean Eng. 79:81–91. doi:10.1016/j.oceaneng.2014.01.011.
  • Mathews ST. 1972. A critical review of the 12th ITTC Wave Spectrum Recommendations, Report of Seakeeping Committee, Appendix 9. Proc. 13th I TTC, Berlin 973–986.
  • Nakos D, Sclavounos P. 1991. Ship motions by a three-dimensional Rankine panel method.
  • Nielsen IR. 1987. Assessment of ship performance in a seaway. Publ. Nord. Sortedam Dossering 19, DK-200 Copenhage, Denmark, ISBN 87-982637-1-4.
  • Niklas K, Pruszko H. 2019. Full scale CFD seakeeping simulations for case study ship redesigned from V-shaped bulbous bow to X-bow hull form. Appl Ocean Res. 89:188–201.
  • Obeng F, Domeh V, Khan F, Bose N, Sanli E. 2022a. Analyzing operational risk for small fishing vessels considering crew effectiveness. Ocean Eng. 249:110512.
  • Obeng F, Domeh V, Khan F, Bose N, Sanli E. 2022b. Capsizing accident scenario model for small fishing trawler. Saf Sci. 145:105500.
  • Ochi MK, Hubble EN. 1976. Six-parameter wave spectra, in: Proceedings of the 15th Coastal Engineering Conference. Honolulu, USA, pp. 301–328.
  • O’Hanlon JF, McCauley ME. 1973. Motion sickness incidence as a function of the frequency and acceleration of vertical sinusoidal motion.
  • Ozturk D, Delen C, Mancini S, Serifoglu MO, Hizarci T. 2021. Full-Scale CFD analysis of double-M craft seakeeping performance in regular head waves. J Mar Sci Eng. 9:504.
  • Pierson WJ, Moskowitz L. 1964. A proposed spectral form for fully developed wind seas based on the similarity theory of S. A. kitaigorodskii. J Geophys Res. 69:5181–5190.
  • Romanowski A, Tezdogan T, Turan O. 2019. Development of a CFD methodology for the numerical simulation of irregular sea-states. Ocean Eng. 192:106530.
  • Salvesen N, Tuck EO, Faltinsen O. 1970. Ship motions and Sea loads. Trans Soc Nav Archit Mar Eng. 78:250–287.
  • Sandvik E, Gutsch M, Asbjørnslett BE. 2018. A simulation-based ship design methodology for evaluating susceptibility to weather-induced delays during marine operations. Ship Technol Res. 65:137–152.
  • Sariöz K, Sariöz E. 2006. Practical seakeeping performance measures for high speed displacement vessels. Nav Eng J. 118:23–36.
  • Scott JR. 1965. A sea spectrum for model tests and long-term ship prediction. J Ship Res. 9:145–152.
  • Statistics Indonesia. 2019. Number of Boats/Ships by Province and Type of Boats/Ships for Marine Fisheries, 2000-2016 (In Indonesian).
  • St Denis M, Pierson WJ. 1953. On the motions of ships in confused seas. Trans Soc Nav Archit Mar Eng. 61:280–357.
  • Tello M, Ribeiro E Silva S, Guedes Soares C. 2009. Fishing Vessels Responses in Waves under Operational Conditions, in: Proceedings of the XXI Naval Architecture Pan-American Conference (COPINAVAL’09). pp. 18–22.
  • Tello M, Ribeiro E Silva S, Guedes Soares C. 2011. Seakeeping performance of fishing vessels in irregular waves. Ocean Eng. 38:763–773. doi:10.1016/j.oceaneng.2010.12.020.
  • Tezdogan T, Demirel YK, Kellett P, Khorasanchi M, Incecik A, Turan O. 2015. Full-scale unsteady RANS CFD simulations of ship behaviour and performance in head seas due to slow steaming. Ocean Eng. 97:186–206.
  • Tezdogan T, Incecik A, Turan O. 2014. Operability assessment of high speed passenger ships based on human comfort criteria. Ocean Eng. 89:32–52.
  • Tezdogan T, Incecik A, Turan O. 2016. Full-scale unsteady RANS simulations of vertical ship motions in shallow water. Ocean Eng. 123:131–145.
  • Tezdogan T, Shenglong Z, Demirel YK, Liu W, Leping X, Yuyang L, Kurt RE, Djatmiko EB, Incecik A. 2018. An investigation into fishing boat optimisation using a hybrid algorithm. Ocean Eng. 167:204–220.
  • Ugurlu F, Yildiz S, Boran M, Ugurlu Ö, Wang J. 2020. Analysis of fishing vessel accidents with Bayesian network and Chi-square methods. Ocean Eng. 198:106956.
  • Wang J, Pillay A, Kwon YS, Wall AD, Loughran CG. 2005. An analysis of fishing vessel accidents. Accid Anal Prev. 37:1019–1024.
  • Zhang L, Zhang J, Shang Y. 2021. A practical direct URANS CFD approach for the speed loss and propulsion performance evaluation in short-crested irregular head waves. Ocean Eng. 219:108287.

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