Stochastic Modeling of Integrated Power System coupled to Hydrodynamics in the All-Electric Ship

被引:5
|
作者
Prempraneerach, P. [1 ,3 ]
Kirtley, J. [2 ]
Chryssostomidis, C. [1 ]
Triantafyllou, M. S. [1 ]
Kamiadakis, G. E. [1 ,4 ]
机构
[1] MIT, Dept Mech Engn, Cambridge, MA 02138 USA
[2] MIT, Dept Mech Engn, Cambridge, MA 02138 USA
[3] Rajamangala Univ Technol Thunyabur, Dept Engn Mech, Pathum Thani, Thailand
[4] Brown Univ, Div Appl Math, Providence, RI 02912 USA
来源
2008 INTERNATIONAL SYMPOSIUM ON POWER ELECTRONICS, ELECTRICAL DRIVES, AUTOMATION AND MOTION, VOLS 1-3 | 2008年
关键词
Hydrodynamics; Marine vehicle power systems; Induction motor drives; Stochastic differential equations;
D O I
10.1109/SPEEDHAM.2008.4581214
中图分类号
TE [石油、天然气工业]; TK [能源与动力工程];
学科分类号
0807 ; 0820 ;
摘要
In the paper, we model the integrated power system (IPS) of a typical destroyer ship coupled to hydrodynamics. This IPS is composed of a 21MW, 3-phase synchronous generator supplying electric power to 4160 V AC bus and to a 19 MW, 15-phase induction motor driven by an indirect rotor field oriented control for the motor torque. Moreover, stochastic responses are examined when there exists a variation in the induction motor's rotor resistance and a disturbance from the slowly-varying added resistance, derived from a Pierson and Moskowitz sea spectrum.
引用
收藏
页码:563 / +
页数:2
相关论文
共 50 条
  • [21] An Evidence Theory Based Advisory Layer for All-Electric Ship Power Systems
    Hoang, Phuong H.
    Ozkan, Gokhan
    Deb, Naireeta
    Edrington, Chris S.
    Papari, Behnaz
    2019 IEEE ELECTRIC SHIP TECHNOLOGIES SYMPOSIUM (ESTS 2019): EMERGING TECHNOLOGIES FOR FUTURE ELECTRIC SHIPS, 2019, : 599 - 604
  • [22] Model and Control of Naval Ship Power System by The Concept of All-Electric Ships Based on Renewable Energy
    Gaber, Mohab
    El-banna, S. H.
    Eldabah, Mahmoud
    Hamad, M. S.
    2019 21ST INTERNATIONAL MIDDLE EAST POWER SYSTEMS CONFERENCE (MEPCON 2019), 2019, : 1235 - 1240
  • [23] All-electric braking system
    Bokulich, F
    AEROSPACE ENGINEERING, 1999, 19 (04) : 8 - 8
  • [24] System-level thermal management of pulsed loads on an all-electric ship
    Webb, Tyler W.
    Kiehne, Thomas M.
    Haag, Scott T.
    IEEE TRANSACTIONS ON MAGNETICS, 2007, 43 (01) : 469 - 473
  • [25] All-electric braking system
    Aerosp Eng (Warrendale PA), 4 (08):
  • [26] Experiences with the simulation of a notional all-electric ship integrated power system on a large-scale high-speed electromagnetic transients simulator
    Langston, J.
    Suryanarayanan, S.
    Steurer, M.
    Andrus, M.
    Woodruff, S.
    Ribeiro, P. F.
    2006 POWER ENGINEERING SOCIETY GENERAL MEETING, VOLS 1-9, 2006, : 1424 - +
  • [27] Considerations in simulation of a notional all-electric ship AC/DC conversion system
    Langston, J.
    Martin, A.
    Suryanarayanan, S.
    Steurer, M.
    Andrus, M.
    Woodruff, S. L.
    Simpson, J.
    2007 IEEE POWER ENGINEERING SOCIETY GENERAL MEETING, VOLS 1-10, 2007, : 3917 - +
  • [28] Notional All-Electric Ship Thermal Simulation and Visualization
    Dias, F. G.
    Souza, J. A.
    Ordonez, J. C.
    Vargas, J. V. C.
    Hovsapian, R.
    Amy, J. V., Jr.
    2009 IEEE ELECTRIC SHIP TECHNOLOGIES SYMPOSIUM, 2009, : 533 - +
  • [29] Optimal Demand-Side Management and Power Generation Scheduling in an All-Electric Ship
    Kanellos, Fotis D.
    Tsekouras, George J.
    Hatziargyriou, Nikos D.
    IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, 2014, 5 (04) : 1166 - 1175
  • [30] PHYSICAL MODELING OF ALL-ELECTRIC FURNACES
    BANSAL, B
    IEEE TRANSACTIONS ON INDUSTRY APPLICATIONS, 1978, 14 (01) : 55 - 61
12345