Fluid–structure interaction study of the start-up of a rocket engine nozzle

Garelli, Luciano; Paz, Rodrigo R.; Storti, Mario A.

doi:10.1016/j.compfluid.2010.03.005

Cited by 38 publications

(18 citation statements)

References 28 publications

(28 reference statements)

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“…Compressible fluid-structure interaction (FSI) occurs in a broad range of technical applications involving, e.g., nonlinear aeroelasticity [16,42] and shock-induced deformations of rocket nozzles [23,55]. The numerical modeling and simulation of compressible FSI can be challenging, in particular if an accurate representation of the structural interface within the fluid solver and a consistent coupling of both subdomains is required.…”

Section: Introductionmentioning

confidence: 99%

A cut-cell finite volume – finite element coupling approach for fluid–structure interaction in compressible flow

Pasquariello

Hammerl

Örley

et al. 2016

Journal of Computational Physics

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We present a loosely coupled approach for the solution of fluid-structure interaction problems between a compressible flow and a deformable structure. The method is based on staggered Dirichlet-Neumann partitioning. The interface motion in the Eulerian frame is accounted for by a conservative cut-cell Immersed Boundary method. The present approach enables subcell resolution by considering individual cut-elements within a single fluid cell, which guarantees an accurate representation of the time-varying solid interface. The cut-cell procedure inevitably leads to non-matching interfaces, demanding for a special treatment. A Mortar method is chosen in order to obtain a conservative and consistent load transfer. We validate our method by investigating two-dimensional test cases comprising a shock-loaded rigid cylinder and a deformable panel. Moreover, the aeroelastic instability of a thin plate structure is studied with a focus on the prediction of flutter onset. Finally, we propose a three-dimensional fluid-structure interaction test case of a flexible inflated thin shell interacting with a shock wave involving large * Corresponding author.

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Section: Introductionmentioning

confidence: 99%

A cut-cell finite volume – finite element coupling approach for fluid–structure interaction in compressible flow

Pasquariello

Hammerl

Örley

et al. 2016

Journal of Computational Physics

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“…For a wind turbine, FSI scheme was used by Kim and Kim (2006). In the field of aerospace, FSI theory was used by Garelli et al (2010) for rocket engine nozzle and for aerofoil by Ramji and Wei (2004). Recently, Jo et al (2012) conducted the loosely coupled method to compute the deformation in pile structure of a wind turbine.…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional numerical simulation of a vertical axis tidal turbine using the two-way fluid structure interaction approach

Khalid

Zhang

et al. 2013

J. Zhejiang Univ. Sci. A

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The objective of this study was to develop, as well as validate the strongly coupled method (two-way fluid structural interaction (FSI)) used to simulate the transient FSI response of the vertical axis tidal turbine (VATT) rotor, subjected to spatially varying inflow. Moreover, this study examined strategies on improving techniques used for mesh deformation that account for large displacement or deformation calculations. The blade's deformation for each new time step is considered in transient two-way FSI analysis, to make the design more reliable. Usually this is not considered in routine one-way FSI simulations. A rotor with four blades and 4-m diameter was modeled and numerically analyzed. We observed that two-way FSI, utilizing the strongly coupled method, was impossible for a complex model; and thereby using ANSYS-CFX and ANSYS-MECHANICAL in work bench, as given in ANSYS-WORKBENCH, helped case examples 22 and 23, by giving an error when the solution was run. To make the method possible and reduce the computational power, a novel technique was used to transfer the file in ANSYS-APDL to obtain the solution and results. Consequently, the results indicating a two-way transient FSI analysis is a time-and resource-consuming job, but with our proposed technique we can reduce the computational time. The ANSYS STRUCTURAL results also uncover that stresses and deformations have higher values for two-way FSI as compared to one-way FSI. Similarly, fluid flow CFX results for two-way FSI are closer to experimental results as compared to one-way simulation results. Additionally, this study shows that, using the proposed method we can perform coupled simulation with simple multi-node PCs (core i5).

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“…Moreover, its application to the stability of rocket engines has rarely been studied [8,9,12]. In an industrial context, the only model currently used to predict static instability and frequency shifting in an overexpanded flow through a nozzle is the Pekkari's stability model [9].…”

Section: Stability Prediction For Overexpanded Nozzle Undergoing Rigimentioning

confidence: 99%

Frequency dependency of side loads resulting from shock motion in a forced oscillating rocket nozzle

Lefrançois

2011

Computers & Fluids

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Fluid–structure interaction study of the start-up of a rocket engine nozzle

Cited by 38 publications

References 28 publications

A cut-cell finite volume – finite element coupling approach for fluid–structure interaction in compressible flow

A cut-cell finite volume – finite element coupling approach for fluid–structure interaction in compressible flow

Three-dimensional numerical simulation of a vertical axis tidal turbine using the two-way fluid structure interaction approach

Frequency dependency of side loads resulting from shock motion in a forced oscillating rocket nozzle

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