Abstract:This paper gives marine propeller load characteristic simulation system of electric propulsion as an example, the shaft structures of real propulsion system and simulation system are compared. Based on the detailed mathematical deduction of simulation principle and original research, and with the control strategy of simulation system, dynamic regulation under several typical working conditions of the propulsion and load simulation system is analyzed. Matlab/Simulink simulation and experimental results validate the simulation principle analysis and realization method, which are common, and can be used as research reference for other electric drive simulation systems.
[1] Hodge C G. Modern applications of power electronics to marine propulsion systems[J]. Proceedings of the 14th International Symposium on Power Semiconductor Devices and ICs, 2002: 9-16. [2] Ren W, Steurer M, Woodruff S. Progress and challenges in real time hardware-in-the loop simulations of integrated ship power systems[C]. IEEE Power Engineering Society General Meeting, 2005: 534-537. [3] Diao Lijun, Liu Zhigang, Shen Maosheng, et al. A novel simulation system of marine propeller load character- istics[C]. The 7th International Power Engineering Conference, 2005:1147-1152. [4] Jianqing S, Yongqing W, Xiaofeng Z. Applications of doubly-fed machine in simulating load of marine electric propulsion[C]. Proceedings of the Eighth International Conference on Electrical Machines and Systems, 2005:1377-1380. [5] Li H, Steurer M, Shi K L, et al. Development of a unified design, test, and research platform for wind energy systems based on hardware-in-the-loop real-time simulation[J]. IEEE Trans. on Industrial Electronics, 2006, 53(4):1144-1151. [6] Jing L, Ma Z M, Zhang J, et al. A hardware-in-the- loop simulator based on dynamometers for traction control system[C]. IEEE International Conference on Vehicular Electronics and Safety, 2005:15-19. [7] Ma Zhiwen, Zheng Trillion L, Lin Fei. Research on reciprocal power-fed AC drive test rig for electric traction applications[C]. ICEMS 2005, 2005: 1873- 1876. [8] 刁利军, 刘志刚, 李哲峰, 等. 新型船用螺旋桨特性仿真系统的建模、仿真和研制[C]. 第四届全国优秀博士生学术年会, 西安, 2007:841-846. [9] 任修明, 杨德望. 船舶交流永磁推进电动机的研 究[J]. 舰船科学技术, 2003, 25(1): 37-41. [10] Shuai L, Corzine K. Multilevel multi-phase propulsion drives[C]. IEEE on Electric Ship Technologies Symposium, 2005: 363-370. [11] Collins E R, Huang Y. A programmable dynamometer for testing rotating machinery using a three-phase induction machine[J]. IEEE Trans. on Energy Conversion, 1994, 9(3): 521-527. [12] 陈实如. 船用螺旋桨负载特性动态实验仿真系统研究[D]. 哈尔滨: 哈尔滨工程大学, 2001. [13] Norton R L. Machine design[M]. America: Prentice Hall, 1998. [14] Sandholdt P, Ritchie E, Pedersen J K, et al. A dynamometer performing dynamical emulation of loads with nonlinear friction[C]. ISIE'96, 1996: 873-878. [15] Nomura M, Suzuki M, Hori M, et al. Decoupling torque control system for automotive engine tester[J]. IEEE Trans. on Industry Applications, 2000, 36(2): 467-474. [16] Bose B K. Modern power electronics and AC drives[M]. 1st ed. Harlow, En: Prentice-Hall, 2002. [17] 高景德, 王祥珩, 李发海. 交流电动机及其系统的分析[M]. 2版. 北京: 清华大学出版社, 2004.