Transactions of the Korean Society of Mechanical Engineers A (대한기계학회논문집A)

The Korean Society of Mechanical Engineers (대한기계학회)
권호 표지
DOI QR코드

DOI QR Code

Failure Probability Estimation of Flaw in CANDU Pressure Tube Considering the Dimensional Change

가동중 중수로 압력관의 외경과 두꼐 변화를 고려한 결함의 파손확률 예측

  • 곽상록 (성균관대학교 대학원 기계공학과) ;
  • 이준성 (경기대학교 전자기계공학부) ;
  • 김영진 (성균관대학교 기계공학부) ;
  • 박윤원 (한국원자력안전기술원)
  • Published : 2002.11.01
Download PDF
⟨ Previous Next ⟩

Abstract

The pressure tube is a major component of the CANDU reactor, which supports nuclear fuel bundle and heavy water coolant. Pressure tubes are installed horizontally inside the reactor and only selected samples are periodically examined during in-service inspection. In this respect, a probabilistic safety assessment method is more appropriate fur the assessment of overall pressure tube safety. The failure behavior of CANDU pressure tubes, however, is governed by delayed hydride cracking which is the major difference from pipings and reactor pressure vessels. Since the delayed hydride cracking has more widely distributed governing parameters, it is impossible to apply a general PFM methodology directly. In this paper, a PFM methodology for the safety assessment of CANDU pressure tubes is introduced by applying Monte Carlo simulation in determining failure probability Initial hydrogen concentration, flaw shape and depth, axial and radial crack growth rate and fracture toughness were considered as probabilistic variables. Parametric study has been done under the base of pressure tube dimension and hydride precipitation temperature in calculating failure probability. Unstable fracture and plastic collapse are used for the failure assessment. The estimated failure probability showed about three-order difference with changing dimensions of pressure tube.

Keywords

References

  1. Sang-Log Kwak, Joon-Seong Lee, Young-Jin Kim and Youn-Won Park, 2000, 'Development of CANDU Pressure Tube Integrity Evaluation System : Its Application to Sharp Flaw and Blunt Notch,' Transactions of the KSME, A, Vol. 24, No. 1, pp. 206-214
  2. AECL, 1996,' Fitness-for-Service Guide lines for Zirconium Alloy Pressure Tubes in Operating CANDU Reactors,' COG-91-66
  3. CSA, 1994,' Periodic Inspection of CANDU Nuclear Power Plant Components,' CAN/CSAN285.4
  4. KINS, 1992,' In-Service Inspection report : Fuel Channel Pressure Tube,' KINS/AR-152
  5. Walker, J.R., 1990,' A Probabilistic Approach to Leak Before Break in CANDU Pressure Tubes,' The International Journal of Pressure Vessels and Piping, Vol. 43, pp. 229-239 https://doi.org/10.1016/0308-0161(90)90104-P
  6. Leemans, D.V, Leger, M., 1993,' Probabilistic Techniques for the Assessment of Pressure Tube Hydride Blistering in CANDU Reactor Cores,' The International Journal of Pressure Vessels and Piping, Vol. 56, pp. 37-51 https://doi.org/10.1016/0308-0161(93)90116-B
  7. ASME Code, 1995, 'Section XI : Rules for Testing and Inspection of Components of Light-Water Cooled Plants'
  8. Joon-Seong Lee, Sang-Log Kwak and Young-Jin Kim, 2001, 'Application of Probabilistic Fracture Mechanics Technique Using Monte Carlo Simulation,' Transactions of the KSPE, Vol. 18, No. 10, pp. 154-160
  9. Kiefner, J.F., Maxey, W.A., Eiber, R.I., and Duffy, A.R., 1973,' Failure Stress Levels of Flaws in Pressurized Cylinders,' ASTM STP 536, pp. 461-481
  10. Rubinstein, R.Y., 1981, Simulation and Monte Carlo Method, John Wiley & Sons
  11. Harris, D.O., Dedhia, D.D. and Lu, S.C., 1992, 'PRAISE:A Probabilistic Fracture Mechanics Computer Code for Piping Reliability Analysis,' NUREG/CR-5864