Abstract
Ground vibration induced by the collapse of large-scale cooling towers in nuclear power plants (NPPs) has recently been realized as a potential secondary disaster to adjacent nuclear-related facilities with demands for vibration mitigation. The previous concept to design cooling towers and nuclear-related facilities operating in a containment as isolated components in NPPs is inappropriate in a limited site which is the cases for inland NPPs in China. This paper presents a numerical study on the mitigation of ground vibration in a “cooling tower-soil-containment” system via a novel application of two materials acting as cushions underneath cooling towers, that is, foamed concrete and a “tube assembly.” Comprehensive “cooling tower-cushion-soil” models were built with reasonable cushion material models. Computational cases were performed to demonstrate the effect of vibration mitigation using seven earthquake waves. Results found that collapse-induced ground vibrations at a point with a distance of 300 m were reduced in average by 91%, 79%, and 92% in radial, tangential, and vertical directions when foamed concrete was used, and the vibrations at the same point were reduced by 53%, 32%, and 59% when the “tube assembly” was applied, respectively. Therefore, remarkable vibration mitigation was achieved in both cases to enhance the resilience of the “cooling tower-soil-containment” system against the secondary disaster.
Highlights
A quantity of nuclear power plants (NPPs) will be built in inland China in the several years to meet the rapidly increasing energy demand [1]
The collapse of the towers can induce secondary disasters, for example, intensive ground vibrations featured with a mass of uncertain positions of vibratory sources distributing throughout a large area of ground surface
A numerical study was performed to investigate the mitigation of collapse-induced ground vibration using two materials acting as cushions, that is, foamed concrete and the “tube assembly” to enhance the resilience of the “cooling towersoil-containment” system against the postearthquake disaster in NPPs
Summary
A quantity of nuclear power plants (NPPs) will be built in inland China in the several years to meet the rapidly increasing energy demand [1]. For typical case using strongly weathered sandy slate as foundation soil, the maximum acceleration amplitude of ground vibration in radial direction at a distance of 350 m can reach as high as 0.29 g [4] This paper presents a numerical study of novel application of two materials (i.e., foamed concrete and the “tube assembly”) acting as cushions to reduce collapse-induced ground. Numerical approach to build “cooling tower-cushion-soil” models was presented in detail Using these models, the collapse of a cooling tower was simulated and comparative computation was performed to demonstrate ground vibration reduction by using each cushion. The commercial finite element program ANSYS/LS-DYNA was used [24]
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