Torque Characteristic Analysis of Outer Rotor Permanent Magnet Generator for Low Head Hydro Power Application
Abstract
This paper analyzes the torque characteristics of outer rotor PMG for low head hydro power application. The aim is to prevent the generator torque from exceeding the turbine torque as the prime mover so that the system can work properly in both start and steady state conditions. The PMG is of outer rotor type and the torques are calculated analytically and numerically. The analysis is focused only on the PMG without connecting it to the turbine. Two analyzed torques include electromagnetic torque and starting torque, which comprises cogging torque, hysteresis torque and friction torque. The electromagnetic torque was obtained by loading the PMG with resistance and impedance (RL-LL in series) respectively. The results indicate that electromagnetic torque is the highest among all the investigated torques although its value is only 5.6% of the turbine torque, and cogging torque is the highest among the starting torque. From those results, it can be concluded that the hydro turbine torque can overcome the generator torque both at start and steady state conditions.
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P. Irasari, P. Sutikno, P. Widiyanto, and Q. Maulana, "Performance Measurement of a Compact Generator - Hydro Turbine System," International Journal of Electrical and Computer Engineering (IJECE), vol. 5, pp. 1252-1261 2015.
C. h. Corp., "Very Low Head (VLH) Turbine," in 11th Annual Power of Water Conference, ed. Ontario, 2011.
R. A. Subekti, A. Susatyo, and P. Irasari, "Design and Analysis of the Prototype of Pico Hydro Scale Submersible Type Turbine-Generator for Flat Flow River Application," Teknologi Indonesia, vol. 35, pp. 1-8, 2012.
E. Fornasiero, M. Morandin, E. Carraro, N. Bianchi, and S. Bolognani, "Outer Rotor IPM Generator with Wide Constant Power Region for Automotive Applications," in ITEC, Dearborn, MI, USA 15-18 June 2014
I. Tar?mer and C. Ocak, "Performance Comparision of Internal and External Rotor Structured Wind Generators Mounted from Same Permanent Magnets on Same Geometry," Electronics and Electrical Engineering, vol. 4, pp. 65-70, 2009.
H. A. Lari, A. Kiyoumarsi, B. M. Dehkordi, A. Darijani, and S. M. Madani, "Analysis and Design of a Permanent-Magnet Outer-Rotor Synchronous Generator for a Direct-Drive Vertical-Axis Wind Turbine," Iranian Journal of Electrical & Electronic Engineering, vol. 10, 2014.
L. Jian, K. T. Chau, and J. Z. Jiang, "A Magnetic-Geared Outer-Rotor Permanent-Magnet Brushless Machine for Wind Power Generation," IEEE Transactions on Industry Applications vol. 45, pp. 954-962, 2009.
J. Chen, C. V. Nayar, and L. Xu, "Design and Finite-Element Analysis of an Outer-Rotor Permanent-Magnet Generator for Directly Coupled Wind Turbines," IEEE Transactions on Magnetics vol. 36, pp. 3802-3809, 2000.
Y. Kraimeen, I. Al-Adwan, and M. S. N. Al-Din, "Finite Element Analysis of an Outer Rotor Permanent Magnet Brushless DC Generator," International Journal of Electrical Engineering, vol. 6, pp. 99-116, 2013.
W. Fei, P. C. K. Luk, J. Shen, and Y. Wang, "A Novel Outer-Rotor Permanent-Magnet Flux-Switching Machine for Urban Electric Vehicle Propulsion," in 3rd International Conference on Power Electronics Systems and Applications, Hong Kong, China, 20-22 May 2009.
W. Fei, P. C. K. Luk, J. Shen, Y. Wang, and M. Jin, "A Novel Permanent Magnet Flux Switching Machine with an Outer-Rotor Configuration for In-Wheel Light Traction Applications," IEEE Transaction on Industry Applications, vol. 48, pp. 1496-1506, 2012.
J. Machowski, J. W. Bialek, and J. R. Bumby, Power System Dynamics and Stability. England: John Wiley & Sons, 1998.
W. Wu, V. S. Ramsden, T. Crawford, and G. Hill, "A Low-Speed, High-Torque, Direct-Drive Permanent Magnet Generator For Wind Turbines," in IEEE Industrial Application Conference, 2000, pp. 147-154.
N. Ozturk, A. Dalcal?, E. Celik, and S. Sakar, "Cogging Torque Reduction by Optimal Design of PM Synchronous Generator for Wind Turbines," International Journal of Hydrogen Energy vol. 42, pp. 1759 3 - 7600, 2017.
L. Dosiek and P. Pillay, "Cogging Torque Reduction in Permanent Magnet Machines," IEEE Transactions on Industry Applications vol. 43, pp. 1565-1571, 2007.
J.-Y. Choi, S.-M. Jang, and B.-M. Song, "Design of a Direct-Coupled Radial-Flux Permanent Magnet Generator for Wind Turbines " in Power and Energy Society General Meeting, 2010 IEEE Minneapolis, MN 2010, pp. 1-6.
C. Huynh, L. Zheng, and D. Acharya, "Losses in High Speed Permanent Magnet Machines Used in Microturbine Applications," Journal of Engineering for Gas Turbines and Power, vol. 131, pp. 022301-1 - 022301-6, 2009.
I. Mosincat, "Hysteresis Losses Infuence on the Cogging Torque of High-Eciency Surface Mounted PM Machines," Master Thesis, Department of energy technology, Aalborg University, Denmark, 2011.
P. M. P. Amaro, "Friction Torque in Thrust Ball and Roller Bearings Lubricated with "Wind Turbine Gear Oils" at Constant Temperature," Master Thesis, Mechanical Engineering, University of Porto, Porto, Portugal, 2012.
J. F. Gieras, R.-J. Wang, and M. J. Kamper, Axial Flux Permanent Magnet Brushless Machines, 2nd ed.: Springer, 2008.
DOI: https://doi.org/10.31284/j.iptek.2019.v23i2.524
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