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
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
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
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
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
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
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
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
Kirtley JL, Beaty HW (1998) Electric motor handbook, chapter 6. McGraw-Hill, New York
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
Erickson RW, Maksimovic D (2007) Fundamentals of power electronics. Springer, Berlin
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
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.
Lee GW, Surendran S, Kim S (2009) Algorithms to control the moving ship during harbour entry. Appl Math Model 33(5):2474–2490
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
Lee HY, Shin SS (1998) Approximate technique for ship’s maneuverability prediction. J Soc Naval Archit Korea 35(4):2474–2490
Molland AF, Stephen RT, Dominic AH (2017) Ship resistance and propulsion. Cambridge University Press, Cambridge
Kim DY, Kim YT (2019) Fundamental design of a 75-kw-rim-driven propeller. J Korean Soc Mar Eng 43(1):31–39
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.
Lee CK (2005) A study on the evaluation and validation of IMO maneuverability standards of vessels. J Navig Port Res 29(5):365–370
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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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DOI: https://doi.org/10.1007/s00773-020-00735-4