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Year 2019, , 69 - 73, 28.03.2019
https://doi.org/10.17350/HJSE19030000123

Abstract

References

  • 1. A.S. McDonald, M.A Mueller, H. Polinder. Structural mass in direct drive permanent magnet electrical generator. IET Renewable Power Generation 2 (2008) 3-15.
  • 2. T. M. Jahns. The expanding role of PM machines in directdrive applications, 2011 International Conference on Electrical Machines and Systems. (2011) 1-8.
  • 3. Wang J, Luo S.M., Su Deyu. Multi-objective optimal design of cycloid speed reducer based on genetic algorithm. Mechanism and Machine Theory 102 (2016) 139-148.
  • 4. Wu Z.Y, Qu R.H, Li J., et al., Lightweight Design of Rotor Supporting Structure of Large PM Wind Generator Based on Response Surface Model. 2015 18th International Conference on Electrical Machines and Systems (ICEMS), pp. 705-709, 2015.
  • 5. Gui S.G., Optimal design of product structure based on ANSYS APDL. Modular Machine Tool & Automatic Manufacturing Technique 07 (2010) 92-96.
  • 6. Wu Z.Y, Qu R.H, Li J., et al. Structure optimization of rotor supporting of permanent magnet direct drive synchronous generators for large wind turbine based on genetic algorithm and finite element method. 2015 IEEE International Electric Machines & Drives Conference (IEMDC), vol. 2, no. 1, pp. 1755-1760, 2015.
  • 7. N. Taran and M. Ardebili. Efficiency optimization of an axial flux permanent magnet synchronous generator for low speed wind power applications. 2014 22nd Iranian Conference on Electrical Engineering (ICEE), pp. 539-544, 2014.
  • 8. A. Mahmoudi, S. Kahourzade, N.A. Rahim, et al., Design, analysis and prototyping of an axial flux permanent magnet motor based on Genetic Algorithm and Finite-Element Analysis. IEEE Transactions on Magnetics, vol. 49, no. 4, pp. 1479-1492, 2013.
  • 9. M.J. Navardi, B. Babaghorbani, A. Ketabi. Efficiency improvement and torque ripple minimization of switched reluctance motor using FEM and seeker optimization algorithm. Energy Conversion and Managem- ent, 78 (2013) 237-244.

Lightweight Design of Rotor Supporting for Large Permanent Magnet Direct Drive Wind Generator

Year 2019, , 69 - 73, 28.03.2019
https://doi.org/10.17350/HJSE19030000123

Abstract

Under the action of electromagnetic force, mechanical force and gravity, the radial deformation of rotor supporting must meet the design standard while ensuring the lightest mass. At first, the mathematical model of single objective optimization is established. Then, the objective function is optimized by the combination of genetic algorithm and finite element method GA-FEM . With the help of this method, the optimal design parameters of the rotor supporting are obtained. This paper takes the actual rotor supporting of 7MW prototype as the optimization object. The optimal solution of this structure without the lightweight holes can be obtained by first optimization. And then, the optimal solution of the final structure with the lightweight holes is obtained by the second optimization. The final simulation shows that the stiffness can be met while reducing the mass by 40%.

References

  • 1. A.S. McDonald, M.A Mueller, H. Polinder. Structural mass in direct drive permanent magnet electrical generator. IET Renewable Power Generation 2 (2008) 3-15.
  • 2. T. M. Jahns. The expanding role of PM machines in directdrive applications, 2011 International Conference on Electrical Machines and Systems. (2011) 1-8.
  • 3. Wang J, Luo S.M., Su Deyu. Multi-objective optimal design of cycloid speed reducer based on genetic algorithm. Mechanism and Machine Theory 102 (2016) 139-148.
  • 4. Wu Z.Y, Qu R.H, Li J., et al., Lightweight Design of Rotor Supporting Structure of Large PM Wind Generator Based on Response Surface Model. 2015 18th International Conference on Electrical Machines and Systems (ICEMS), pp. 705-709, 2015.
  • 5. Gui S.G., Optimal design of product structure based on ANSYS APDL. Modular Machine Tool & Automatic Manufacturing Technique 07 (2010) 92-96.
  • 6. Wu Z.Y, Qu R.H, Li J., et al. Structure optimization of rotor supporting of permanent magnet direct drive synchronous generators for large wind turbine based on genetic algorithm and finite element method. 2015 IEEE International Electric Machines & Drives Conference (IEMDC), vol. 2, no. 1, pp. 1755-1760, 2015.
  • 7. N. Taran and M. Ardebili. Efficiency optimization of an axial flux permanent magnet synchronous generator for low speed wind power applications. 2014 22nd Iranian Conference on Electrical Engineering (ICEE), pp. 539-544, 2014.
  • 8. A. Mahmoudi, S. Kahourzade, N.A. Rahim, et al., Design, analysis and prototyping of an axial flux permanent magnet motor based on Genetic Algorithm and Finite-Element Analysis. IEEE Transactions on Magnetics, vol. 49, no. 4, pp. 1479-1492, 2013.
  • 9. M.J. Navardi, B. Babaghorbani, A. Ketabi. Efficiency improvement and torque ripple minimization of switched reluctance motor using FEM and seeker optimization algorithm. Energy Conversion and Managem- ent, 78 (2013) 237-244.
There are 9 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Zhenyu Wu This is me

Siming Wang This is me

Ng Li This is me

Publication Date March 28, 2019
Published in Issue Year 2019

Cite

Vancouver Wu Z, Wang S, Li N. Lightweight Design of Rotor Supporting for Large Permanent Magnet Direct Drive Wind Generator. Hittite J Sci Eng. 2019;6(1):69-73.

Hittite Journal of Science and Engineering is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY NC).