论文信息 - Seismic Capacity Test of Nuclear Piping System using Multi-platform Shake Table

Seismic Capacity Test of Nuclear Piping System using Multi-platform Shake Table

In this study, dynamic characteristics and seismic capacity of the nuclear power plant piping system are evaluated by model test results using multi-platform shake table. The model is 21.2 m long and consists of straight pipes, elbows, and reducers. The stainless steel pipe diameters are 60.3 mm (2 in.) and 88.9 mm (3 in.) and the system was assembled in accordance with ASME code criteria. The dynamic characteristics such as natural frequency, damping and acceleration responses of the piping system were estimated using the measured acceleration, displacement and strain data. The natural frequencies of the specimen were not changed significantly before and after the testing and the failure and leakage of the piping system was not observed until the final excitation. The damping ratio was estimated in the range of 3.13 ~ 4.98 % and it is found that the allowable stress(345 MPa) according to ASME criteria is 2.5 times larger than the measured maximum stress (138 MPa) of the piping system even under the maximum excitation level of this test.

[1] Jin-Hee Ahn,et al. Structural dynamic displacement vision system using digital image processing , 2011 .

[2] Sung Gook Cho,et al. Analysis of Experimental Modal Properties of an Electric Cabinet via a Forced Vibration Test Using a Shaker , 2011 .

[3] Jinsuo Nie,et al. Analysis of JNES Seismic Tests on Degraded Piping , 2010 .

[4] Sung Gook Cho,et al. Effects of the Excitation Level on the Dynamic Characteristics of Electrical Cabinets of Nuclear Power Plants , 2010 .

[5] K. L. Merz,et al. Differences in dynamic response of typical class II piping due to restraint method and input amplitude , 1988 .

[6] N. Null. Seismic Analysis of Safety-Related Nuclear Structures and Commentary , 2000 .

[7] C. Hofmayer,et al. Analysis of nuclear piping system seismic tests with conventional and energy absorbing supports , 1997 .

[8] 김태완. 국내 저층 철골 모멘트골조의 내진설계 , 2011 .

[9] Shinobu Yoshimura,et al. Probabilistic fracture mechanics analysis of nuclear piping considering variation of seismic loading , 2002 .

[10] P. Sollogoub,et al. Seismic behaviour of piping systems with and without defects: experimental and numerical evaluations , 1999 .