Three-Dimensional Time-Resolved Magneto-Optical Microscopy for Investigation of Magnetic Vortex Dynamics in the Presence of Defects

Mehrnia, Mahdi

23 May 2022

No description available.

Physics

Condensed Matter Physics

Optics

3D Kerr Microscopy

Magnetic Vortex

Magnetic Vortex Core Dynamics

Magnetic Vortex Core Reversal

Magnetic Vortex Core-Defects Interaction

ランキン渦流中での予混合火炎伝播に与える渦核半径の影響に関する数値解析

YAMAMOTO, Kazuhiro, SHINODA, Masahisa, YAMASHITA, Hiroshi, KONDOU, Shuuji, 山本, 和弘, 篠田, 昌久, 山下, 博史, 近藤, 周司

January 2008

No description available.

Numerical Analysis

Vortex Core Radius

Rankin Vortex

Vortex Bursting

Swirling Flow

Flame Propagation

Premixed Flame

Combustion Noise and Instabilities from Confined Non-premixed Swirl Flames

Mohamed Jainulabdeen, Mohammed Abdul Kadher

21 October 2019

No description available.

Aerospace Materials

Combustion Noise

Thermoacoustic Instability

Precessing Vortex Core

Swirl Flames

DMD

POD

Application of Subjective Logic to Vortex Core Line Extraction and Tracking from Unsteady Computational Fluid Dynamics Simulations

Shaw, Ryan Phillip

09 March 2012

Presented here is a novel tool to extract and track believable vortex core lines from unsteady Computational Fluid Dynamics data sets using multiple feature extraction algorithms. Existing work explored the possibility of extracting features concurrent with a running simulation using intelligent software agents, combining multiple algorithms' capabilities using subjective logic. This work modifies the steady-state approach to work with unsteady fluid dynamics and is designed to work within the Concurrent Agent-enabled Feature Extraction concept. Each agent's belief tuple is quantified using a predefined set of information. The information and functions necessary to set each component in each agent's belief tuple is given along with an explanation of the methods for setting the components. This method is applied to the analyses of flow in a lid-driven cavity and flow around a cylinder, which highlight strengths and weaknesses of the chosen algorithms and the potential for subjective logic to aid in understanding the resulting features. Feature tracking is successfully applied and is observed to have a significant impact on the opinion of the vortex core lines. In the lid-driven cavity data set, unsteady feature extraction modifications are shown to impact feature extraction results with moving vortex core lines. The Sujudi-Haimes algorithm is shown to be more believable when extracting the main vortex core lines of the cavity simulation while the Roth-Peikert algorithm succeeding in extracting the weaker vortex cores in the same simulation. Mesh type and time step is shown to have a significant effect on the method. In the curved wake of the cylinder data set, the Roth-Peikert algorithm more reliably detects vortex core lines which exist for a significant amount of time. the method was finally applied to a massive wind turbine simulation, where the importance of performing feature extraction in parallel is shown. The use of multiple extraction algorithms with subjective logic and feature tracking helps determine the expected probability that an extracted vortex core is believable. This approach may be applied to massive data sets which will greatly reduce analysis time and data size and will aid in a greater understanding of complex fluid flows.

Feature Extraction

Feature Tracking

Vortex Core Lines

Computational Fluid Dynamics

Subjective Logic

Mechanical Engineering

Estudo do escoamento de gás no interior de ciclones através da técnica de fluidodinâmica computacional. / Study of the gas flow inside cyclones using computational fluid dynamics.

Cruz, Fabiana Sanches

31 January 2013

Neste trabalho, buscou-se investigar a aplicação de uma modelagem RANS, com a utilização do modelo de turbulência das Tensões de Reynolds (RSTM), na modelagem do escoamento de gás no interior de ciclones, especialmente na simulação do movimento periódico do vórtice, conhecido como Precessing Vortex Core (PVC), com apoio da Fluidodinâmica Computacional. Utilizou-se o pacote de CFD de código aberto OpenFOAM, e as simulações foram realizadas em regime transiente. Dois modelos RSTM foram testados, o modelo LRR com os valores padrões para as constantes e uma modificação das constantes do termo de redistribuição. Compararam-se os resultados obtidos com dados da literatura e verificou-se que ambos os modelos representaram o campo médio de velocidade. No entanto, somente o modelo LRR conseguiu reproduzir o campo de flutuações de velocidade. Detectou-se o movimento de precessão do vórtice, que pode ser visualizado através de imagens sequenciais do escoamento, e uma frequência característica do movimento pode ser calculada através do Espectro de potência. / The flow field of a gas cyclone was simulated with a RANS model using Computational Fluid Dynamics (CFD) and the Precession of the Vortex Core (PVC) was investigated. The CFD simulations were carried out using the open source code OpenFOAM and the simulations were performed in a transient regime. Two Reynolds Stress Turbulence Models (RSTM) were investigated - the LRR model with standard constants and another with modified constants in the pressure-strain term. The results obtained by the models were compared with values of mean velocity taken from the literature and predictions were satisfactory. However, only the LRR model with standard constants predicted with precision the fluctuation velocity field. The precessing vortex was detected and illustrated by the flow field visualization and a characteristic frequency was calculated by Power Spectrum Density.

Ciclone

Computational fluid dynamics

Cyclone

Fluidodinâmica computacional

Modelos de turbulência

Precessing vortex core

Turbulence

Turbulence models

Turbulência

Vórtice de precessão

Estudo do escoamento de gás no interior de ciclones através da técnica de fluidodinâmica computacional. / Study of the gas flow inside cyclones using computational fluid dynamics.

Fabiana Sanches Cruz

31 January 2013

Neste trabalho, buscou-se investigar a aplicação de uma modelagem RANS, com a utilização do modelo de turbulência das Tensões de Reynolds (RSTM), na modelagem do escoamento de gás no interior de ciclones, especialmente na simulação do movimento periódico do vórtice, conhecido como Precessing Vortex Core (PVC), com apoio da Fluidodinâmica Computacional. Utilizou-se o pacote de CFD de código aberto OpenFOAM, e as simulações foram realizadas em regime transiente. Dois modelos RSTM foram testados, o modelo LRR com os valores padrões para as constantes e uma modificação das constantes do termo de redistribuição. Compararam-se os resultados obtidos com dados da literatura e verificou-se que ambos os modelos representaram o campo médio de velocidade. No entanto, somente o modelo LRR conseguiu reproduzir o campo de flutuações de velocidade. Detectou-se o movimento de precessão do vórtice, que pode ser visualizado através de imagens sequenciais do escoamento, e uma frequência característica do movimento pode ser calculada através do Espectro de potência. / The flow field of a gas cyclone was simulated with a RANS model using Computational Fluid Dynamics (CFD) and the Precession of the Vortex Core (PVC) was investigated. The CFD simulations were carried out using the open source code OpenFOAM and the simulations were performed in a transient regime. Two Reynolds Stress Turbulence Models (RSTM) were investigated - the LRR model with standard constants and another with modified constants in the pressure-strain term. The results obtained by the models were compared with values of mean velocity taken from the literature and predictions were satisfactory. However, only the LRR model with standard constants predicted with precision the fluctuation velocity field. The precessing vortex was detected and illustrated by the flow field visualization and a characteristic frequency was calculated by Power Spectrum Density.

Ciclone

Fluidodinâmica computacional

Modelos de turbulência

Turbulência

Vórtice de precessão

Computational fluid dynamics

Cyclone

Precessing vortex core

Turbulence

Turbulence models

An isothermal experimental study of the unsteady fluid mechanics of gas turbine fuel injector flowfields

Midgley, Kristofer

January 2005

Low-emissions combustor design is crucially important to gas turbine engine manufacturers. Unfortunately, many designs are susceptible to unsteady oscillations that can result in structural fatigue and increased noise. Computational approaches that resolve flow unsteadiness, for example Large Eddy Simulation (LES), are being explored as one avenue to help understand such phenomena. However, in order to quantifY the accuracy of LES predictions, benchmark validation data in suitably chosen test cases are required. Comprehensive experimental data covering both time-averaged and timeresolved features are currently scarce. It was the aim of this thesis, therefore, to provide such data .in a configuration representing the near-field of a typical gas turbine fuel injector. It was decided to focus on the fuel injector since many unsteady events are believed to originate because of the transient interactions between the fuel injector flow and the main combustor flow. A radial fed two-stream fuel injector, based on a preexisting industrial gas-turbine Turbomeca design was used, since this geometry was known to be susceptible to unsteadiness. The fuel injector was investigated under isothermal conditions to place emphasis on the fluid mechanical behaviour of the fuel injector, including detailed capture of any unsteady phenomena present. Light Sheet Imaging (LSI) systems were used as the primary experimental technique to provide high quality spatially and temporally resolved instantaneous velocity and scalar field information in 2D planes (using ParticieImage Velocimetry (PIV) and Planar LaserInduced Fluorescence (PUF) techniques). Several methods were employed to extract information quantifYing the flow unsteadiness and improve visualisation of timedependent large-scale turbulent structures. Proper Orthogonal Decomposition (POD) analysis enabled clear identification of the dominant modes of energy containing structures. The results indicated that periodic high-energy containing vortex structures occurred in the swirl stream shear layer, emerging from the fuel injector. These formed a two-strong two-weak rotating vortex pattern which propagated down the main duct flow path. The formation of these vortices was found to be a function of the swirl number and originated due to an interaction between the forward moving swirl flow and the furthest upstream penetration point ofthe recirculation zone present in the main duct flow. Dependent on the magnitude of the swirl number (influencing the swirl stream cone angle) and the geometry of the fuel injector, the vortex formation point was sometimes found inside the fuel injector itself. If the vortices originated inside the fuel injector they appeared much more coherent in space and time and of higher energy. A second unsteady high energy containing phenomenon was also identified, namely a Precessing Vortex Core (PVC), which was damped out if the fuel injector contained a central jet. The dynamics of the PVC interacted with the dynamics of the swirl stream shear layer vortices to reduce there strength. Transient scalar measurements indicated that there was a clear connection between the unsteady vortex pattern and the rate of mixing, resulting in bursts of high heat release and is therefore identified as one source of combustor oscillations. Future fuel injector designs need to pay close attention to these unsteady features in selecting swirl number and internal geometry parameters.

629.134353

A Study Of A Vortex Particle Method For Vortex Breakdown Phenomena

Shankar Kumar, B

01 1900

Vortex breakdown is an important phenomenon observed in swirling flows involving the development of a stagnation point on the axis of the vortex followed by a region of recirculation when the swirl increases beyond a particular level. It has been studied extensively over past 50 years and various theories have been proposed to explain its various aspects. However, a single model explaining all the aspects together is yet to emerge. Numerical simulations of breakdown have been performed using a variety of grid-based as well as vortex methods. Vortex methods are a Lagrangian alternative to grid-based methods wherein the motion of the vorticity is determined by the local fluid velocity convection, with models for viscous effects when considered. The fluid velocity is obtained from the vorticity field. Only the rotational regions of the flow need to be considered leading to significant economy of computational effort for simulations of vorticity dominated flows, such as vortex breakdown. The inviscid vortex filament method has been used to simulate several aspects of the vortex breakdown phenomenon. The vortex filament method however, cannot easily simulate viscous effects. To simulate the viscous effects the viscous vortex particle method needs to be used. This work was intended to be a first step towards this end by initially evaluating the effectiveness of the inviscid version of the vortex particle method in simulating the breakdown phenomenon. The inviscid vortex particle method was found to satisfactorily simulate most qualitative aspects involved in the formation of vortex breakdown such as the retardation of axial velocity along centerline, radial swelling of the vortex core, formation of stagnation points, creation of azimuthal vorticity gradient from axial vorticity gradient and the turning of vortex lines along with the formation of a bubble-like structure with recirculating flow within. The effect of a wall placed adjacent to the vortex core was simulated by using image vortices. The wall was not found to influence the location of breakdown. However, the initiation of the spiral mode was found to occur earlier when a wall was present. For a quantitative assessment, a simulation of the experimental results of Faler and Leibovich (1978) was attempted. The simulation managed to predict the location of the breakdown and the extent of the bubble. The shape and height of the bubble obtained however were not in accord with the experimental observations. A single vortical cell was obtained in the interior of the bubble.

Air Flow - Fluid Dynamics

Vortex Particle Method

Vortex Breakdown

Vortex Rings - Simulation

Vortex - Dynamics

Vortex Core

Single Filament Ring

Multi-filament Ring

Aeronautics

A Computational Fluid Dynamics Feature Extraction Method Using Subjective Logic

Mortensen, Clifton H.

08 July 2010

Computational fluid dynamics simulations are advancing to correctly simulate highly complex fluid flow problems that can require weeks of computation on expensive high performance clusters. These simulations can generate terabytes of data and pose a severe challenge to a researcher analyzing the data. Presented in this document is a general method to extract computational fluid dynamics flow features concurrent with a simulation and as a post-processing step to drastically reduce researcher post-processing time. This general method uses software agents governed by subjective logic to make decisions about extracted features in converging and converged data sets. The software agents are designed to work inside the Concurrent Agent-enabled Feature Extraction concept and operate efficiently on massively parallel high performance computing clusters. Also presented is a specific application of the general feature extraction method to vortex core lines. Each agent's belief tuple is quantified using a pre-defined set of information. The information and functions necessary to set each component in each agent's belief tuple is given along with an explanation of the methods for setting the components. A simulation of a blunt fin is run showing convergence of the horseshoe vortex core to its final spatial location at 60% of the converged solution. Agents correctly select between two vortex core extraction algorithms and correctly identify the expected probabilities of vortex cores as the solution converges. A simulation of a delta wing is run showing coherently extracted primary vortex cores as early as 16% of the converged solution. Agents select primary vortex cores extracted by the Sujudi-Haimes algorithm as the most probable primary cores. These simulations show concurrent feature extraction is possible and that intelligent agents following the general feature extraction method are able to make appropriate decisions about converging and converged features based on pre-defined information.

Clifton Mortensen

feature extraction

subjective logic

computational fluid dynamics

agent-based data mining

vortex core

massive data set post-processing

Mechanical Engineering

Combined PIV/PLIF measurements in a high-swirl fuel injector flowfield

Cheng, Liangta

January 2013

Current lean-premixed fuel injector designs have shown great potential in terms of reducing emissions of pollutants, but such designs are susceptible to combustion instabilities in which aerodynamic instability plays a major role and also has an effect on mixing of air and fuel. In comparison to prototype testing with combustors running in operating conditions, computational approaches such as Large Eddy Simulations (LES) offer a much more cost-effective alternative in the design stage. However, computational models employed by LES require validation by experimental data. This is one of the main motivations behind the present experimental study. Combined particle image velocimetry (PIV) and planar laser induced fluorescence (PLIF) instrumentation allowed simultaneous measurements of velocity vector and a conserved scalar introduced into the fuel stream. The results show that the inner swirl shear layer features two pairs of vortices, which draw high concentration fuel mixture from the central jet into the swirl stream and causes it to rotate in their wakes. Such periodic entrainment also occurs with the characteristic frequencies of the vortices. This has clear implications for temporal variations in fuel/air ratio in a combusting flow; these bursts of mixing, and hence heat release, could be a possible cause of mixing-induced pressure oscillation in combusting tests. For the first time in such a flow, all 3 components of the turbulent scalar flux were available for validation of LES-based predictions. A careful assessment of experimental errors, particularly the error associated with spatial filtering, was carried out. Comparison of LES predictions with experimental data showed very good agreement for both 1st and 2nd moment statistics, as well as spectra and scalar pdfs. It is particularly noteworthy that comparison between LES computed and measured scalar fluxes was very good; this represents successful validation of the simple (constant Schmidt number) SGS model used for this complex and practically important fuel injector flow. In addition to providing benchmark data for the validation of LES predictions, a new experimental technique has been developed that is capable of providing spatially resolved residence time data. Residence times of combustors have commonly been used to help understand NOx emissions and can also contribute to combustion instabilities. Both the time mean velocity and turbulence fields are important to the residence time, but determining the residence time via analysis of a measured velocity field is difficult due to the inherent unsteadiness and the three dimensional nature of a high-Re swirling flow. A more direct approach to measure residence time is reported here that examines the dynamic response of fuel concentration to a sudden cutoff in the fuel injection. Residence time measurement was mainly taken using a time-resolved PLIF technique, but a second camera for PIV was added to check that the step change does not alter the velocity field and the spectral content of the coherent structures. Characteristic timescales evaluated from the measurements are referred to as convection and half-life times: The former describes the time delay from a fuel injector exit reference point to a downstream point of interest, and the latter describes the rate of decay once the effect of the reduced scalar concentration at the injection source has been transported to the point of interest. Residence time is often defined as the time taken for a conserved scalar to reduce to half its initial value after injection is stopped: this is equivalent to the sum of the convection time and the half-life values. The technique was applied to a high-swirl fuel injector typical of that found in combustor applications. Two test cases have been studied: with central jet (with-jet) and without central jet (no-jet). It was found that the relatively unstable central recirculation zone of the no-jet case resulted in increased transport of fuel into the central region that is dominated by a precessing vortex core, where long half-life times are also found. Based on this, it was inferred that the no-jet case may be more prone to NOx production. The technique is described here for a single-phase isothermal flow field, but with consideration, it could be extended to studying reacting flows to provide more insight into important mixing phenomena and relevant timescales.

629.25