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A simpler approach to analysis ship maneuvering performances of hybrid propulsion ship using a HILS

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Abstract

A simulation verification of the hybrid propulsion ship considering accurate electro-dynamic model is required to evaluate ship maneuverability before the maritime demonstration. This paper presents the simplified model constructions for the hybrid propulsion ship using a real time simulator in terms of the dynamic models accuracy and the improvement of a computation speed. In addition, the hardware in the loop simulator based on a laboratory virtual instrument engineering workbench using the ship dynamic model and the developed equipment is proposed to evaluate the electro dynamic characteristics of hybrid propulsion ship. The validity of a proposed model on a hardware in the loop simulator is verified by simulation compared with a detailed model on an electronic circuit simulation software.

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References

  1. Jung TH, Kang SG, Lee JG, Ahn JG (2018) International maritime organization (IMO) ship emission regulation trends and domestic and foreign measures. Bull Soc Naval Archit Korea 55(3):48–54

    Google Scholar 

  2. Kang GH, Kim SD (2017) Electric propulsion ship technology trend and power consumption analysis according to ship. Korean Inst Electr Eng 66(7):13–20

    Google Scholar 

  3. Zahedi B, Norum LE (2012) Modeling and simulation of all-electric ships with low-voltage dc hybrid power systems. IEEE Trans Power Electron 28(10):4525–4537

    Article  Google Scholar 

  4. Hansen JF, Frank W (2015) History and state of the art in commercial electric ship propulsion, integrated power systems, and future trends. Proc IEEE 103(12):2229–2242

    Article  Google Scholar 

  5. Lea M, Thompson D, Van Blarcom B, Eaton J, Friesch J, Richards J (2003) Scale model testing of a commercial rim-driven propulsor pod. J Ship Prod 19(2):121–130

    Article  Google Scholar 

  6. Fang MC, Luo JH (2005) The nonlinear hydro ynamic model for simulating a ship steering in waves with autopilot system. Ocean Eng 32:1486–1502

    Article  Google Scholar 

  7. Ku HK, Kwak KK, Kim JM (2015) A study integrated-power-system simulation model of all-electric-ship. Trans Korean Inst Power Electron 20(1):45–50

    Article  Google Scholar 

  8. Kirtley JL, Beaty HW (1998) Electric motor handbook, chapter 6. McGraw-Hill, New York

    Google Scholar 

  9. Juri J, Pekarek Steven D, Ali D (2006) Parametric average-value model of synchronous machine-rectifier systems. IEEE Trans Energy Convers 21(1):9–18

    Article  Google Scholar 

  10. Erickson RW, Maksimovic D (2007) Fundamentals of power electronics. Springer, Berlin

    Google Scholar 

  11. Rim CT, Choi NS, Cho GC, Cho GH (1994) A complete dc and ac analysis of three-phase controlled-current PWM rectifier using circuit d–q transformation. IEEE Trans Power Electron 9(4):390–396

    Article  Google Scholar 

  12. Kim SA (2018) A study on the design and control of integrated power supply system with static transfer switch for special vehicle. Ph.D. Dissertation, Department of electrical engineering of Dong-A university.

  13. Lee GW, Surendran S, Kim S (2009) Algorithms to control the moving ship during harbour entry. Appl Math Model 33(5):2474–2490

    Article  Google Scholar 

  14. Kim SA, Hong KP, Lee SK, Kang GH (2020) Dynamic characteristics analysis of ship model considering RDP system. J Adv Mar Eng Technol 44(2):90–101

    Google Scholar 

  15. Lee HY, Shin SS (1998) Approximate technique for ship’s maneuverability prediction. J Soc Naval Archit Korea 35(4):2474–2490

    Google Scholar 

  16. Molland AF, Stephen RT, Dominic AH (2017) Ship resistance and propulsion. Cambridge University Press, Cambridge

    Book  Google Scholar 

  17. Kim DY, Kim YT (2019) Fundamental design of a 75-kw-rim-driven propeller. J Korean Soc Mar Eng 43(1):31–39

    Google Scholar 

  18. Kobayashi H, Blok JJ, Barr R, Kim YS, Nowicki J (2003) specialist committee on ESSO OSAKA: final report and recommendations to the 23rd ITTC. In: Proceedings of the 23rd International Towing Tank Conference, pp 8–14.

  19. Lee CK (2005) A study on the evaluation and validation of IMO maneuverability standards of vessels. J Navig Port Res 29(5):365–370

    Article  Google Scholar 

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Kim, SA. A simpler approach to analysis ship maneuvering performances of hybrid propulsion ship using a HILS. J Mar Sci Technol 26, 233–242 (2021). https://doi.org/10.1007/s00773-020-00735-4

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