A Novel Control-rod Drive Mechanism via Electromagnetic Levitation in MNSR

• Authors: Mohammad Divandari , Mehdi Hashemi-Tilehnoee , Masoud Khaleghi , Mohammadreza Hosseinkhah
• Languages of publication: EN

Abstracts

EN

In this paper, an electromagnetic levitation system was used with a synchronous motor to navigate the control rod of a small-type research reactor. The result from this prototype magnetic levitation system was in agreement with simulation results. The control system was programmed in MATLAB through open-loop system, closed-loop with state feedback and closed-loop with state feedback integral tracking. The final control system showed the highest performance with a low positioning error. Our results showed that the developed control system has the potential to be used as a reliable actuator in nuclear reactors to satisfy higher performance and safety.

Keywords

EN

magnetic levitation system; nuclear reactor; state feedback; tracking

• Publisher: De Gruyter Open
• Journal: Nukleonika
• Year: 2014
• Volume: 59
• Issue: 2
• Pages: 73-79

Dates

received

17 - 12 - 2013

accepted

25 - 4 - 2014

online

8 - 7 - 2014

Contributors

author

Mohammad Divandari

• Department of Electrical Engineering, Aliabad Katoul branch, Islamic Azad University, Aliabad Katoul, Iran, Tel: +98 911 353 2381

author

Mehdi Hashemi-Tilehnoee

• Department of Electrical Engineering, Aliabad Katoul branch, Islamic Azad University, Aliabad Katoul, Iran, Tel: +98 911 353 2381

author

Masoud Khaleghi

• Department of Mechanical Engineering, Sirjan University of Technology, Kerman, Iran

author

Mohammadreza Hosseinkhah

• Department of Electrical Engineering, Aliabad Katoul branch, Islamic Azad University, Aliabad Katoul, Iran, Tel: +98 911 353 2381

References

• 1. Hanliang, B., Wenxiang, Z., & Duo, D. (2000). Studies on the performance of the hydraulic control rod drive for the NHR-200. Nucl. Eng. Des., 195, 117-121.
• 2. Yuanqiang, W., Xingzhong, D., Huizhong, Z., & Zhiyong, H. (2002). Design and tests for the HTR-10 control rod system. Nucl. Eng. Des., 218, 147-154.
• 3. Takeda, T., & Tachibana, Y. (2003). Indirect air cooling techniques for control rod drives in the high temperature engineering test reactor. Nucl. Eng. Des., 223, 25-40.
• 4. Chyou, Y. P., Yu, D. D., & Chen, Y. N. (2004). Performance validation on the prototype of control rod driving mechanism for the TRR-II project. Nucl. Eng. Des., 227, 195-207.
• 5. Mousavi Shirazi, S. A., Aghanajafi, C., Sadoughi, S., & Sharifloo, N. (2010). Design, construction and simulation of a multipurpose system for precision movement of control rods in nuclear reactors. Ann. Nucl. Energy, 37, 1659-1665.[WoS]
• 6. Tanaka, A., Futahashi, K., Takanabe, K., Kurimura, C., Kato, J., & Hara, H. (2008). Development of a 3-D simulation analysis system for PWR control rod drive mechanism. Int. J. Pressure Vessels Pip., 85, 655-661.
• 7. International Atomic Energy Agency. (1986). Technology and use of low power research reactors. Vienna: IAEA. (IAEA-TECDOC-384).
• 8. Tabadar, Z., Hadad, K., Nematollahi, M. R., Jabbari, M., Khaleghi, M., & Hashemi-Tilehnoee, M. (2012). Simulation of a control rod ejection accident in a VVER-1000/V446 using RELAP5/Mod3.2. Ann. Nucl. Energy, 45, 106-114.[WoS]
• 9. Ku, C. L., Li, T. H. S., & Guo, N. R. (2005). Design of a novel fuzzy sliding-mode control for magnetic ball levitation system. J. Intell. Robot. Syst., 42(3), 295-316.[Crossref]
• 10. Maghsoudlou, A., Barzamini, R., & Farhani, K. D. (2011). Non-linear control based on feedback linearization for double-electromagnet suspension system. Electron. Electr. Eng., 108(2), 85-90.
• 11. Ogata, K. (2010). Modern control engineering (5th ed.). Boston: Prentice-Hall.

Identifiers

DOI

10.2478/nuka-2014-0008