The effect of fuel rod supporting conditions on fuel rod vibration characteristics and grid-to-rod fretting wear

Abstract The grid-to-rod fretting wear-induced fuel rod failure observed in PWRs may be caused by excessive fluid-induced vibration and inadequate fuel rod support by the spacer grid spring. In order to simulate in-reactor grid-to-rod fretting wear behaviors, the grid-to-rod fuel rod supporting conditions as a function of time were predicted by taking into account cladding creep rate, initial spacer grid spring deflection, spacer grid spring force relaxation, etc. Based on these grid-to-rod supporting conditions, the fuel rod vibration modes and natural frequencies were calculated with the help of the ANSYS code, while the fuel rod vibration amplitudes were estimated by the Paidoussis’ empirical formula. With these vibration characteristics that depend upon the grid-to-rod supporting conditions, the in-reactor fretting wear axial profile observed on the fuel rod surface are found to be simulated quite well. In addition, key design guidelines for the fuel assembly and the spacer grid are proposed to minimize the grid-to-rod fretting wear that may be utilized to develop an advanced fuel design against fretting wear.