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http://dx.doi.org/10.7779/JKSNT.2014.34.3.254

Nondestructive Examination of PHWR Pressure Tube Using Eddy Current Technique  

Lee, Hee-Jong (KHNP Central Research Institute)
Choi, Sung-Nam (KHNP Central Research Institute)
Cho, Chan-Hee (KHNP Central Research Institute)
Yoo, Hyun-Joo (KHNP Central Research Institute)
Moon, Gyoon-Young (KHNP Central Research Institute)
Publication Information
Journal of the Korean Society for Nondestructive Testing / v.34, no.3, 2014 , pp. 254-259 More about this Journal
Abstract
A pressurized heavy water reactor (PHWR) core has 380 fuel channels contained and supported by a horizontal cylindrical vessel known as the calandria, whereas a pressurized water reactor (PWR) has only a single reactor vessel. The pressure tube, which is a pressure-retaining component, has a 103.4 mm inside diameter ${\times}$ 4.19 mm wall thickness, and is 6.36 m long, made of a zirconium alloy (Zr-2.5 wt% Nb). This provides support for the fuel while transporting the $D_2O$ heat-transfer fluid. The simple tubular geometry invites highly automated inspection, and good approach for all inspection. Similar to all nuclear heat-transfer pressure boundaries, the PHWR pressure tube requires a rigorous, periodic inspection to assess the reactor integrity in accordance with the Korea Nuclear Safety Committee law. Volumetric-based nondestructive evaluation (NDE) techniques utilizing ultrasonic and eddy current testing have been adopted for use in the periodic inspection of the fuel channel. The eddy current testing, as a supplemental NDE method to ultrasonic testing, is used to confirm the flaws primarily detected through ultrasonic testing, however, eddy current testing offers a significant advantage in that its ability to detect surface flaws is superior to that of ultrasonic testing. In this paper, effectiveness of flaw detection and the depth sizing capability by eddy current testing for the inside surface of a pressure tube, will be introduced. As a result of this examination, the ET technique is found to be useful only as a detection technique for defects because it can detect fine defects on the surface with high resolution. However, the ET technique is not recommended for use as a depth sizing method because it has a large degree of error for depth sizing.
Keywords
Pressurized Heavy Water Reactor Pressure Tube; Eddy Current Testing; Flaw; Nondestructive Examination;
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  • Reference
1 ASME, "Nondestructive Examination," 2010 Edition Article 8, Mandatory App. II "Eddy Current Examination of Nonferromagnetic Heat Exchanger Tubing": American Society of Mechanical Engineers
2 H. J. Lee, M. W. Nam, C. H. Choi, S. N. Choi, H. J. Yoo, B. S. Yoon and S. H. Yang "Development of Inservice Inspection Technology for Major Components in Nuclear Power Plant," Final Research Report, KEPRI, pp. 151-162 (2010)
3 H. J. Lee, M. W. Nam, C. H. Choi, Y. S. Kim and B. S. Yoon, "Development of NDE Technology for Rod Control Cluster Assembly (RCCA) in Nuclear Power Plant," Final Research Report, KEPRI, pp. 181-210 (1997)
4 H. J Lee, C. H. Choi, M. W. Nam, Y. S. Kim, B. S. Yoon, H. J. Yoo, Y. B. Jo, J. S. Lee, G. Y. Moon, I. C. Kim, G. Y. Chun and T. H. Lee, "Development of Eddy Current Testing System for Steam Generator in Nuclear Power Plant," Final Research Report, KHNP CRI, pp. 250-321 (2013)