Analyses for random flow-induced vibration of cylindrical structures subjected to turbulent axial flow

TL;DR: In this paper, a two-dimensional arbitrary Lagrangian Eulerian finite-element analysis is used to compute the hydrodynamic coupling effects in a 5×5 rod cluster subject to single-phase parallel flow.

TL;DR: In this paper, the dynamics of clustered cylinders in axial flow, such as found in heat exchangers and nuclear reactors, is treated in this chapter, considering inviscid and viscous fluid coupling.

TL;DR: This review analyzes grid-to-rod fretting in pressurized water reactors, a leading cause of fuel failure, from a fluid-structure interaction perspective, discussing theoretical concepts, practical methods, and wear prediction techniques to ensure fuel robustness and prevent unplanned reactor stops.

TL;DR: The basic dynamics of pipes conveying fluid is reviewed in this paper, establishing why this system has become a model dynamical problem and the radiation of the experience gained in studying this problem into other areas of Applied Mechanics, particularly other problems in fluid-structure interactions involving slender structures and axial flows.

TL;DR: In this article, the authors examined the attenuation of the frequency spectral density and of the cross-spectral density associated with the second-order moments of the pressure field and showed that attenuation caused by the finite size of transducers is generally more sever.

TL;DR: In this article, a mathematical model is proposed to describe the phenomena of parallel-flow-induced vibrations of a flexible rod, and a solution is obtained for a rod with arbitrary end conditions; the solution can be used for fixed, hinged, cantilevered and other elastically supported end conditions.

TL;DR: In this paper, the statistical properties of the wall pressure field determined from these recordings included the power spectral density, space-time correlations, and convection speeds embracing both broad and narrow (third-octave) frequency bands.