Research on the impact effect of AP1000 shield building subjected to large commercial aircraft |
Wang, Xiuqing
(School of Civil Engineering, Guangzhou University)
Wang, Dayang (School of Civil Engineering, Guangzhou University) Zhang, Yongshan (School of Civil Engineering, Guangzhou University) Wu, Chenqing (School of Civil Engineering, Guangzhou University) |
1 | Q. Fang, H. Wu, T. Zhang, State of the art for damage and failure of nuclear power plant under large commercial aircraft impact, J. Build. Struct. 5 (2019) 1-27. |
2 | W.K. Zheng, Research on the Impacting Load of the Nuclear Power Plant Impacted by a Large Commercial Aircraft, Tsinghua University, 2013. |
3 | J.B. Liu, W.K. Zheng, Impact load analysis on a nuclear power plant impacted by a large commercial aircraft, J. Vib. Shock 33 (2014) 97-101. |
4 | T. Zhang, H. Wu, Q. Fang, et al., Numerical simulations of nuclear power plant containment subjected to aircraft impact, Nucl. Eng. Des. 320 (2017) 207-221. DOI |
5 | F. Lin, H. Tang, Nuclear containment structure subjected to commercial aircraft crash and subsequent vibrations and fire, Nucl. Eng. Des. 322 (2017) 68-80. DOI |
6 | D.Y. Wang, C.Q. Wu, W.C. Huang, et al., Vibration investigation on fluid-structure interaction of AP1000 shield building subjected to multi earth-quake excitations, Ann. Nucl. Energy 126 (APR) (2019) 312-329. DOI |
7 | T. Huang, T. Zhang, Z.F. Dong, et al., An analysis of the dynamic response of nuclear containment under the impact of a large commercial aircraft, J. Vib. Shock 37 (2018) 8-14. |
8 | J.B. Liu, P. Han, Numerical analyses of a shield building subjected to a large commercial aircraft impact, Shock Vib. (2018) 1-17. |
9 | D.Y. Wang, Y.S. Zhang, C.Q. Wu, et al., Seismic performance of base-isolated AP1000 shield building with consideration of fluid-structure interaction, Nucl. Eng. Des. 353 (2019) 110241. DOI |
10 | Westinghouse Electric Corporation, AP1000 design control document, Rev. 19 (2011). |
11 | The Boeing Company, 737-783, view [EB/OL], http://www.boeing.com/commercial/airports/3view.page, 2015. |
12 | European Aviation Safety Agency, EASA. E. 115 Type-Certificate Data Sheet for LEAP-1B Series Engines, 2018. Germany. |
13 | S.R. Bodner, P.S. Symonds, Test and theoretical investigation of the plastic deformation of cantilever beams subjected to impulsive loading, J. Appl. Mech. 29 (1962) 719-728. DOI |
14 | European Aviation Safety Agency, EASA. IM. A. 120 Type-Certificate Data Sheet for BOEING 737, 2018. Germany. |
15 | T. Zhang, H. Wu, Q. Fang, et al., Influences of nuclear containment radius on the aircraft impact force based on the Riera function, Nucl. Eng. Des. 293 (2015) 196-204. DOI |
16 | T. Zhang, Q. Fang, H. Wu, et al., Numerical simulation on response and damage of nuclear containment under aircraft impact, Journal of PLA University of Science and Technology(Natural Science Edition) 4 (2014) 335-340. |
17 | L. Lin, X.Z. Lu, P.F. Han, et al., Analysis of impact force of large commercial aircraft on rigid wall and nuclear power plant containment, J. Vib. Shock 9 (2015) 158-163. |
18 | N. Jones, Structural Impact, Cambridge University Press, 1997. |
19 | G.R. Cowper, P.S. Symonds, Strain-hardening and Strain-Rate Effects in the Impact Loading of Cantilever Beams, Brown Univ Providence Ri, 1957. |
20 | H.C. Yao, P. Tan, F.L. Zhou, Load time history analysis method for commercial aircraft impact on rigid wall, J. Nat. Disasters 28 (2) (2019) 49-59. |
21 | L.S.T.C. Ls-Dyna, Keyword User's Manual, Livermore Software Technology Corporation, 2017. R10.0. |
22 | T. Sugano, H. Tsubota, Y. Kasai, et al., Local damage to reinforced concrete structures caused by impact of aircraft engine missiles Part 1. Test program, method and results, Nucl. Eng. Des. 140 (1993) 387-405. DOI |
23 | H. Jiang, M.G. Chorzepa, Aircraft impact analysis of nuclear safety-related concrete structures: a review, Eng. Fail. Anal. 46 (2014) 118-133. DOI |
24 | International Atomic Energy Agency (IAEA), Safety Reports Series: Safety Aspects of Nuclear Power Plants in Human Induced External Events: General Considerations, 2017. No. 86. |
25 | International Atomic Energy Agency (IAEA), Safety Reports Series: Safety Aspects of Nuclear Power Plants in Human Induced External Events: Assessment of Structures, 2018, p. 87. |
26 | NRC, Consideration of Aircraft Impacts for New Nuclear Power Reactors. Nuclear Regulatory Commission, RIN 3150-AI19, Washington DC, 2009. |
27 | J.D. Riera, On the stress analysis of structures subjected to aircraft impact forces, Nucl. Eng. Des. 8 (1968) 415-426. DOI |
28 | T. Sugano, H. Tsubota, Y. Kasai, et al., Local damage to reinforced concrete structures caused by impact of aircraft engine missiles Part 2. Evaluation of test results, Nucl. Eng. Des. 140 (1993) 407-423. DOI |
29 | Riedel, Noldgen Werner, et al., Local damage to Ultra High Performance Concrete structures caused by an impact of aircraft engine missiles, Nucl. Eng. Des. 210 (2010) 2633-2642. DOI |
30 | T. Sugano, H. Tsubota, Y. Kasai, et al., Full-scale aircraft impact test for evaluation of impact force, Nucl. Eng. Des. 140 (1993) 373-385. DOI |
31 | R.L. Frano, L. Stefanini, Investigation of the behaviour of a LILW superficial repository under aircraft impact, Nucl. Eng. Des. 300 (2016) 552-562. DOI |
32 | Boeing Commercial Airplanes, D6-38A004 737 MAX Airplane Characteristics for Airport Planning, America, 2017. |
33 | R.L. Frano, G. Forasassi, Preliminary evaluation of aircraft impact on a near term nuclear power plant, Nucl. Eng. Des. 241 (12) (2011) 5245-5250. DOI |