Paper Titles

Risk-Informed Inservice Inspection Program for Ulchin Unit 4
p.2199

Criterions of UT Thickness Measurement on Thinned Pipe Management Program
p.2204

Equipment Development and Nondestructive Examination Techniques for Inspection of Reactor Pressure Vessel Head Penetration
p.2210

Application of Nondestructive Testing Technique for Safeguards Inspection
p.2214

The Development of Fusion Sensor Techniques for Condition Monitoring of a Check Valve
p.2220

Development of a Web-Based Integrity Evaluation System for Primary Components in a Nuclear Power Plant
p.2226

Development of an On-Line Ultrasonic System to Monitor Flow-Accelerated Corrosion of Piping in Nuclear Power Plants
p.2232

Inspection of the Defect in an Irradiated Fuel Rod Using the Probe of a Differential Encircling Coil Type
p.2239

Development of an Integrity Evaluation System on the Basis of Cooperative Virtual Reality Environment for Reactor Pressure Vessel
p.2244

HomeKey Engineering MaterialsKey Engineering Materials Vols. 270-273The Development of Fusion Sensor Techniques for...

The Development of Fusion Sensor Techniques for Condition Monitoring of a Check Valve

Article Preview

Abstract:

You might also be interested in these eBooks

Advances in Nondestructive Evaluation

Info:

Periodical:

Key Engineering Materials (Volumes 270-273)

Pages:

2220-2225

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.270-273.2220

Citation:

Cite this paper

Online since:

August 2004

Authors:

Seung Hwan Seong, Jung Soo Kim, Seop Hur, Jung Taek Kim, Won Man Park, Dai Bum Cha

Keywords:

Accelerometer, Acoustic, Check Valve, Condition Monitoring, Fusion Sensor

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2004 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] H.D. Hayes, Aging and Service Wear of Check Valves Used in Engineering Safety-Feature Systems of Nuclear Power Plants, " NUREG/CR-4302 (ORNL-6193/V2), Vol. 1, "Operating Experience and Failure Identification, Oak Ridge, TN, April (1991).

[2] J.I. Braverman, et. al., Assessment of Age-Related Degradation of Structure and Passive Components for US Nuclear Power Plant, NUREG/CR-6679, BNL-NUREG-52587, NRC, August (2000).

[3] R.E. Uhrig and L.H. Tsoukalas, Application of Neural Networks, EPRI/TR-103443-P1-2, Knoxville, TN, January (1994).

[4] A. Agostinelli, Check Valve Diagnostics Utilizing Acoustic and Magnetic Technologies, Nuclear Plant Journal, pp.80-90, November, (1990).

[5] H.D. Hayes, Evaluation of Check Valve Monitoring Methods, Proceedings of the 17th Water Reactor Safety Meeting, October 23-25, Rockville, MD, (1989).

[6] M.K. Yang, Acoustic and Ultrasonic Signals as Diagnostic Tools for Check Valves, J. of Reactor Vessel Technology, Vol. 115, pp.135-141, May, (1993).

DOI: 10.1115/1.2929507

[7] C. Sim, H. Choi and H. K Baik, The Development of a Non-Intrusive Test of Check Valve Using Acoustic and Magnets, J. of Acoustic Society of Korea, Vol. 16 No. 1E, (1997).

[8] A.V. Oppenheim and R.W. Schafer, Digital Signal Procssing, Prentice Hall Inc., NJ.