The Experiment of Flow Induced Vibration in PWR RCCAs

  • Kim, Sang-Nyung (Department of Nuclear Engineering, Kyunghee University) ;
  • Cheol Shin (Department of Nuclear Engineering, Kyunghee University)
  • Published : 2001.03.01

Abstract

Recently, severe wear on the shutdown rod cladding of Ulchin Nuclear Power Plant #1, #2 were observed by the Eddy Current Test(E.C.T.). In particular, the wear at the sixth card location was up to 75%. The test results indicated that the Flow Induced Vibration(F.I.V.) might be the cause of the fretting wear resulting from the contact between Rod Cluster Control Assemblies(RCCAs) and their spacing cards(guide plates) arranged in the guide tube. From reviewing RCCAs fretting wear repots and analyzing the general characteristics of F.I.V. mechanism in the reactor, geometric layout and flow conditions around the control rod, it is concluded that the turbulence excitation is the most probable vibration mechanism of RCCA. To identify the governing mechanism of RCCA vibration, an experiment was performed for a representative rod position in which the most serious fretting wear experienced among the six rod positions. The experimental rig was designed and set up to satisfy the governing nondimensional numbers which are Reynolds number and mass damping parameter. The vibration amplitude measurement by the non-contact laser displacement sensor showed good agreements in the frequency and the maximum wearing(vibration) location with Ulchin E.C.T. results and Framatome report, respectively. The sudden increase in the vibration amplitude was sensed around the 6th guide plate with mass flow rate variation. Comparing the similitude rod behaviour with the idealized response of a cylinder in flow induced vibration, it was found that he dominant mechanism of vibration was transferred from turbulence excitation to periodic shedding at the mass flow ate 90ι/min. Also the critical velocity of the vibration in RCCAs was determined and the vibration can be prevented by reducing the bypass flow rate below the critical velocity.

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References

  1. Blevins, Robert D., 1997, 'Flow-induced vibration,' 0-442-20828-6
  2. Kim Kyung-Suk, Jung Hyun-Chul, Kang Ki-Soo, Kang Young-June, Cha Yong-Hoon and Jung Woon-Gwan, 1999, 'Experimental Analysis of Vibration Modes of Plates Using ESPI,' KSME International Journal, Vol. 13, pp. 677-686
  3. Kim Sang-nyung and Shin Cheol, 1998, 'Thermal Hydraulic Analysis for RCCA Fretting Wear caused by Flow-induced Vibration,' Korean Nuclear Society Spring Meeting, Vol. 1, pp. 489-495
  4. Korea Energy Research Institute Material Corrosion Lab., 1997, 'Technical Development of RCCA Diagnosis', Intermediate Report
  5. Leclercq J., 1995, 'Mechanical Behaviour of Control Rod of 900 MWe PWR,' Report No. RC/1-Revision 0
  6. Paidousis M. P., 1981, 'Fluidelastic Vibration of Cylinder Arrays in Axial and Cross Flow: State of the Art,' Journal of Sound and Vibration(A81), 76(3), pp. 329-360 https://doi.org/10.1016/0022-460X(81)90516-2
  7. Rho, Byung-Joon and Oh, Je-Ha, 1995, 'LDV Measurement of Turbulent Flow Behavior of Droplets in a Two-Phase Coaxial Jet,' KSME Journal, Vol. 9, pp. 360-368
  8. Ulchin Nuclear Center Plant Technical Team, 1995, 'RCCA Inspection Follow-up Measures of Ulchin #1, 2 Plant,' Wonbaldan(Noh) 743.06-Attachment
  9. Ulchin Nuclear Center Plant Technical Team, 1971, 'RCCA Inspection Results,' Ulchin #2 E. C. T. Experience
  10. Wambsganss M. W. and Chen S. S., 1971, 'Tentative Design Guide for Calculation the Vibration Response of Flexible Cylindrical Elements in Axial Flow,' Argonne National Laboratory Report, ANL-ETD-71-07
  11. Yasuo, A. and Paidoussis, M. P., 1989, 'Flow-Induced Instability of Heat-Exchanger Tubes due to Axial Flow in a Diffuser-Shaped,' Journal of Pressure Vessel Technology, Vol. 111, pp. 428-434