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Entwicklung paralleler Algorithmen zur numerischen Simulation von Gas-Partikel-Stroemungen unter Beruecksichtigung von Partikel-Partikel-KollisionenWassen, Erik 17 December 1998 (has links) (PDF)
Gas-Partikel-Stroemungen finden sich in weiten Bereichen
der Energie- und Verfahrenstechnik. Beispiele fuer haeu-
fig anzutreffende Problemstellungen sind der Transport,
die Separation oder die Injektion eines Gemisches aus
festen Partikeln und einem Traegergas.
Fuer die numerische Simulation solcher disperser Mehr-
phasenstroemungen hat sich das Lagrange-Verfahren als
besonders geeignet erwiesen. Andererseits stellt die An-
wendung dieses Berechnungsverfahrens hoechste Anforderun-
gen an die Ressourcen der verwendeten Rechner. Dies gilt
im besonderen Masse fuer die Simulation von Stroemungen
mit einer moderaten bis hohen Partikelbeladung, in denen
die Partikel-Partikel-Kollisionen einen grossen Einfluss
auf das Stroemungsverhalten haben.
Um das grosse Leistungspotential, das heutige massiv par-
allele Hochleistungsrechner bieten, effizient zu nutzen,
wurden im Rahmen dieser Arbeit parallele Simulationsalgo-
rithmen fuer die numerische Berechnung kollisionsbehafte-
ter Gas-Partikel-Stroemungen entwickelt. Die Effizienz
dieser Algorithmen wurde anhand verschiedener Testfaelle
untersucht. Auf der Grundlage der dabei erzielten Ergeb-
nisse wurden Vorschlaege fuer weitere Entwicklungsmoeg-
lichkeiten erarbeitet. / Gas-particle-flows can be found widely in the field of
energy production and process engineering. Examples for
applications of such kind of flows are transport, se-
paration or injection of a mixture of solid particles
and a gaseous phase.
The Lagrangian approach has proved to be a suitable means
for the numerical simulation of disperse multiphase flows.
On the other hand its application requires a large amount
of computational power, especially when flows with a mo-
derate or high particle loading are computed and particle-
particle collisions have a significant influence on the
flow.
In order to use efficiently the large computational power
that parallel computers provide nowadays, parallel algo-
rithms for the numerical simulation of gas-particle flows
including particle-particle collisions were developed in
the cource of this work. The algorithms' efficiency was
investigated considering different test cases. On the
basis of the results suggestions for further developments
were made.
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Identification of material parameters in mechanical modelsMeyer, Marcus 04 June 2010 (has links) (PDF)
Die Dissertation beschäftigt sich mit
Parameteridentifikationsproblemen, wie sie häufig in
Fragestellungen der Festkörpermechanik zu finden sind. Hierbei
betrachten wir die Identifikation von Materialparametern -- die
typischerweise die Eigenschaften der zugrundeliegenden
Materialien repräsentieren -- aus gemessenen Verformungen oder
Belastungen eines Testkörpers. In mathematischem Sinne
entspricht dies der Lösung von Identifikationsproblemen, die
eine spezielle Klasse von inversen Problemen bilden.
Der Inhalt der Dissertation ist folgendermaßen gegliedert. Nach
dem einführenden Abschnitt 1 wird in Abschnitt 2 ein Überblick
von Optimierungs- und Regularisierungsverfahren zur stabilen
Lösung nichtlinearer inverser Probleme diskutiert. In Abschnitt
3 betrachten wir die Identifikation von skalaren und stückweise
konstanten Parametern in linearen elliptischen
Differentialgleichungen. Hierbei werden zwei Testprobleme
erörtert, die Identifikation von Diffusions- und
Reaktionsparameter in einer allgemeinen elliptischen
Differentialgleichung und die Identifikation der
Lame-Konstanten in einem Modell der linearisierten Elastizität.
Die zugrunde liegenden PDE-Modelle und Lösungszugänge werden
erläutert. Insbesondere betrachten wir hier Newton-artige
Algorithmen, Gradientenmethoden, Multi-Parameter
Regularisierung and den evolutionären Algorithmus CMAES.
Abschließend werden Ergebnisse einer numerischen Studie
präsentiert. Im Abschnitt 4 konzentrieren wir uns auf die
Identifikation von verteilten Parametern in hyperelastischen
Materialmodellen. Das nichtlineare Elastizitätsproblem wird
detailiert erläutert und verschiedene Materialmodelle werden
diskutiert (linear elastisches St.-Venant-Kirchhoff Material
und nichtlineare Neo-Hooke, Mooney-Rivlin und Modified-Fung
Materialien. Zur Lösung des resultierenden
Parameteridentifikationsproblems werden Lösungsansätze aus der
optimalen Steuerung in Form eines Newton-Lagrange SQP
Algorithmus verwendet. Die Resultate einer numerischen Studie
werden präsentiert, basierend auf einem zweidimensionales
Testproblem mit einer sogenannten Cook-Mebran. Abschließend
wird im Abschnitt 5 die Verwendung adaptiver FEM für die Lösung
von Parameteridentifikationsproblems kurz erörtert. / The dissertation is focussed on parameter identification
problems arising in the context of structural mechanics. At
this, we consider the identification of material parameters -
which typically represent the properties of an underlying
material - from given measured displacements and forces of a
loaded test body. In mathematical terms such problems denote
identification problems as a special case of general inverse
problems.
The dissertation is organized as follows. After the
introductive section 1, section 2 is devoted to a survey of
optimization and regularization methods for the stable solution
of nonlinear inverse problems. In section 3 we consider the
identification of scalar and piecewise constant parameters in
linear elliptic differential equations and examine two test
problems, namely the identification of diffusion and reaction
parameters in a generalized linear elliptic differential
equation of second order and the identification of the Lame
constants in the linearized elasticity model. The underlying
PDE models are introduced and solution approaches are discussed
in detail. At this, we consider Newton-type algorithms,
gradient methods, multi-parameter regularization, and the
evolutionary algorithm CMAES. Consequently, numerical studies
for a two-dimensional test problem are presented. In section 4
we point out the identification of distributed material
parameters in hyperelastic deformation models. The nonlinear
elasticity boundary value problem for large deformations is
introduced. We discuss several material laws for linear elastic
(St.-Venant-Kirchhoff) materials and nonlinear Neo-Hooke,
Mooney-Rivlin, and Modified-Fung materials. For the solution of
the corresponding parameter identification problem, we focus on
an optimal control solution approach and introduce a
regularized Newton-Lagrange SQP method. The Newton-Lagrange
algorithm is demonstrated within a numerical study. Therefore,
a simplified two-dimensional Cook membrane test problem is
solved. Additionally, in section 5 the application of adaptive
methods for the solution of parameter identification problems
is discussed briefly.
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Parallele Algorithmen für die numerische Simulation dreidimensionaler, disperser Mehrphasenströmungen und deren Anwendung in der Verfahrenstechnik / Parallel algorithms for the numerical simulation of 3-dimensional disperse multiphase flows and theire application in process technologyFrank, Thomas 30 August 2002 (has links)
Many fluid flow processes in nature and technology are characterized by the presence
and coexistence of two ore more phases. These two- or multiphase flows are furthermore
characterized by a greater complexity of possible flow phenomena and phase interactions
then in single phase flows and therefore the numerical simulation of these multiphase
flows is usually demanding a much higher numerical effort. The presented work
summarizes the research and development work of the author and his research group on
"Numerical Methods for Multiphase Flows" at the University of Technology, Chemnitz over the
last years. This work was focussed on the development and application of numerical
approaches for the prediction of disperse fluid-particle flows in the field of
fluid mechanics and process technology.
A main part of the work presented here is concerned with the modelling of different
physical phenomena in fluid-particle flows under the paradigm of the Lagrangian treatment
of the particle motion in the fluid. The Eulerian-Lagrangian approach has proved to be an
especially well suited numerical approach for the simulation of disperse multiphase flows.
On the other hand its application requires a large amount of (parallel) computational power
and other computational ressources. The models described in this work give a mathematical
description of the relevant forces and momentum acting on a single spherical particle in
the fluid flow field, the particle-wall interaction and the particle erosion to the wall.
Further models has been derived in order to take into account the influence of
particle-particle collisions on the particle motion as well as the interaction of the
fluid flow turbulence with the particle motion. For all these models the state-of-the-art
from literature is comprehensively discussed.
The main field of interest of the work presented here is in the area of development,
implementation, investigation and comparative evaluation of parallelization
methods for the Eulerian-Lagrangian approach for the simulation of disperse multiphase
flows. Most of the priorly existing work of other authors is based on shared-memory
approaches, quasi-serial or static domain decomposition approaches. These parallelization
methods are mostly limited in theire applicability and scalability to parallel computer
architectures with a limited degree of parallelism (a few number of very powerfull compute
nodes) and to more or less homogeneous multiphase flows with uniform particle concentration
distribution and minor complexity of phase interactions. This work now presents a novel
parallelization method developed by the author, realizing a dynamic load balancing
for the Lagrangian approach (DDD - Dynamic Domain Decomposition) and therefore leading
to a substantial decrease in total computation time necessary for multiphase flow
computations with the Eulerian-Lagrangian approach.
Finally, the developed and entirely parallelized Eulerian-Lagrangian approach MISTRAL/PartFlow-3D
offers the opportunity of efficient investigation of disperse multiphase flows with
higher concentrations of the disperse phase and the resulting strong phase interaction
phenomena (four-way coupling). / Viele der in Natur und Technik ablaufenden Strömungsvorgänge sind durch die
Koexistenz zweier oder mehrerer Phasen gekennzeichnet. Diese sogenannten Zwei- oder
Mehrphasensysteme zeichnen sich durch ein hohes Maß an Komplexität aus und
erfordern oft einen sehr hohen rechentechnischen Aufwand zu deren numerischer Simulation.
Die vorliegende Arbeit faßt langjährige Forschungs- und Entwicklungsarbeiten
des Autors und seiner Forschungsgruppe "Numerische Methoden für Mehrphasenströmungen"
an der TU Chemnitz zusammen, die sich mit der Entwicklung und Anwendung numerischer
Berechnungsverfahren für disperse Fluid-Partikel-Strömungen auf dem Gebiet
der Strömungs- und Verfahrenstechnik befassen.
Ein wesentlicher Teil der Arbeit befaßt sich mit der Modellierung unterschiedlicher
physikalischer Phänomene in Fluid-Partikel-Strömungen unter dem Paradigma der Lagrange'schen
Betrachtungsweise der Partikelbewegung. Das Euler-Lagrange-Verfahren hat sich als
besonders geeignetes Berechnungsverfahren für die numerische Simulation disperser
Mehrphasenströmungen erwiesen, stellt jedoch in seiner Anwendung auch höchste
Anforderungen an die Ressourcen der verwendeten (parallelen) Rechnerarchitekturen.
Die näher ausgeführten mathematisch-physikalischen Modelle liefern eine Beschreibung
der auf eine kugelförmige Einzelpartikel im Strömungsfeld wirkenden Kräfte
und Momente, der Partikel-Wand-Wechselwirkung und der Partikelerosion. Weitere Teilmodelle
dienen der Berücksichtigung von Partikel-Partikel-Stoßvorgängen und der
Wechselwirkung zwischen Fluidturbulenz und Partikelbewegung.
Der Schwerpunkt dieser Arbeit liegt im Weiteren in der Entwicklung, Untersuchung und vergleichenden
Bewertung von Parallelisierungsverfahren für das Euler-Lagrange-Verfahren zur Berechnung von
dispersen Mehrphasenströmungen. Zuvor von anderen Autoren entwickelte Parallelisierungsmethoden
für das Lagrange'sche Berechnungsverfahren basieren im Wesentlichen auf Shared-Memory-Ansätzen,
Quasi-Seriellen Verfahren oder statischer Gebietszerlegung (SDD) und sind somit in ihrer
Einsetzbarkeit und Skalierbarkeit auf Rechnerarchitekturen mit relativ geringer Parallelität
und auf weitgehend homogene Mehrphasenströmungen mit geringer Komplexität der Phasenwechselwirkungen
beschränkt. In dieser Arbeit wird eine vom Autor entwickelte, neuartige Parallelisierungsmethode
vorgestellt, die eine dynamische Lastverteilung für das Lagrange-Verfahren ermöglicht (DDD - Dynamic
Domain Decomposition) und mit deren Hilfe eine deutliche Reduzierung der Gesamtausführungszeiten
einer Mehrphasenströmungsberechnung mit dem Euler-Lagrange-Verfahren möglich ist.
Im Ergebnis steht mit dem vom Autor und seiner Forschungsgruppe entwickelten vollständig parallelisierten
Euler-Lagrange-Verfahren MISTRAL/PartFlow-3D ein numerisches Berechnungsverfahren zur Verfügung,
mit dem disperse Mehrphasenströmungen mit höheren Konzentrationen der dispersen Phase und
daraus resultierenden starken Phasenwechselwirkungen (Vier-Wege-Kopplung) effektiv untersucht
werden können.
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Entwicklung paralleler Algorithmen zur numerischen Simulation von Gas-Partikel-Stroemungen unter Beruecksichtigung von Partikel-Partikel-KollisionenWassen, Erik 14 December 1998 (has links)
Gas-Partikel-Stroemungen finden sich in weiten Bereichen
der Energie- und Verfahrenstechnik. Beispiele fuer haeu-
fig anzutreffende Problemstellungen sind der Transport,
die Separation oder die Injektion eines Gemisches aus
festen Partikeln und einem Traegergas.
Fuer die numerische Simulation solcher disperser Mehr-
phasenstroemungen hat sich das Lagrange-Verfahren als
besonders geeignet erwiesen. Andererseits stellt die An-
wendung dieses Berechnungsverfahrens hoechste Anforderun-
gen an die Ressourcen der verwendeten Rechner. Dies gilt
im besonderen Masse fuer die Simulation von Stroemungen
mit einer moderaten bis hohen Partikelbeladung, in denen
die Partikel-Partikel-Kollisionen einen grossen Einfluss
auf das Stroemungsverhalten haben.
Um das grosse Leistungspotential, das heutige massiv par-
allele Hochleistungsrechner bieten, effizient zu nutzen,
wurden im Rahmen dieser Arbeit parallele Simulationsalgo-
rithmen fuer die numerische Berechnung kollisionsbehafte-
ter Gas-Partikel-Stroemungen entwickelt. Die Effizienz
dieser Algorithmen wurde anhand verschiedener Testfaelle
untersucht. Auf der Grundlage der dabei erzielten Ergeb-
nisse wurden Vorschlaege fuer weitere Entwicklungsmoeg-
lichkeiten erarbeitet. / Gas-particle-flows can be found widely in the field of
energy production and process engineering. Examples for
applications of such kind of flows are transport, se-
paration or injection of a mixture of solid particles
and a gaseous phase.
The Lagrangian approach has proved to be a suitable means
for the numerical simulation of disperse multiphase flows.
On the other hand its application requires a large amount
of computational power, especially when flows with a mo-
derate or high particle loading are computed and particle-
particle collisions have a significant influence on the
flow.
In order to use efficiently the large computational power
that parallel computers provide nowadays, parallel algo-
rithms for the numerical simulation of gas-particle flows
including particle-particle collisions were developed in
the cource of this work. The algorithms' efficiency was
investigated considering different test cases. On the
basis of the results suggestions for further developments
were made.
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Identification of material parameters in mechanical modelsMeyer, Marcus 04 June 2010 (has links)
Die Dissertation beschäftigt sich mit
Parameteridentifikationsproblemen, wie sie häufig in
Fragestellungen der Festkörpermechanik zu finden sind. Hierbei
betrachten wir die Identifikation von Materialparametern -- die
typischerweise die Eigenschaften der zugrundeliegenden
Materialien repräsentieren -- aus gemessenen Verformungen oder
Belastungen eines Testkörpers. In mathematischem Sinne
entspricht dies der Lösung von Identifikationsproblemen, die
eine spezielle Klasse von inversen Problemen bilden.
Der Inhalt der Dissertation ist folgendermaßen gegliedert. Nach
dem einführenden Abschnitt 1 wird in Abschnitt 2 ein Überblick
von Optimierungs- und Regularisierungsverfahren zur stabilen
Lösung nichtlinearer inverser Probleme diskutiert. In Abschnitt
3 betrachten wir die Identifikation von skalaren und stückweise
konstanten Parametern in linearen elliptischen
Differentialgleichungen. Hierbei werden zwei Testprobleme
erörtert, die Identifikation von Diffusions- und
Reaktionsparameter in einer allgemeinen elliptischen
Differentialgleichung und die Identifikation der
Lame-Konstanten in einem Modell der linearisierten Elastizität.
Die zugrunde liegenden PDE-Modelle und Lösungszugänge werden
erläutert. Insbesondere betrachten wir hier Newton-artige
Algorithmen, Gradientenmethoden, Multi-Parameter
Regularisierung and den evolutionären Algorithmus CMAES.
Abschließend werden Ergebnisse einer numerischen Studie
präsentiert. Im Abschnitt 4 konzentrieren wir uns auf die
Identifikation von verteilten Parametern in hyperelastischen
Materialmodellen. Das nichtlineare Elastizitätsproblem wird
detailiert erläutert und verschiedene Materialmodelle werden
diskutiert (linear elastisches St.-Venant-Kirchhoff Material
und nichtlineare Neo-Hooke, Mooney-Rivlin und Modified-Fung
Materialien. Zur Lösung des resultierenden
Parameteridentifikationsproblems werden Lösungsansätze aus der
optimalen Steuerung in Form eines Newton-Lagrange SQP
Algorithmus verwendet. Die Resultate einer numerischen Studie
werden präsentiert, basierend auf einem zweidimensionales
Testproblem mit einer sogenannten Cook-Mebran. Abschließend
wird im Abschnitt 5 die Verwendung adaptiver FEM für die Lösung
von Parameteridentifikationsproblems kurz erörtert. / The dissertation is focussed on parameter identification
problems arising in the context of structural mechanics. At
this, we consider the identification of material parameters -
which typically represent the properties of an underlying
material - from given measured displacements and forces of a
loaded test body. In mathematical terms such problems denote
identification problems as a special case of general inverse
problems.
The dissertation is organized as follows. After the
introductive section 1, section 2 is devoted to a survey of
optimization and regularization methods for the stable solution
of nonlinear inverse problems. In section 3 we consider the
identification of scalar and piecewise constant parameters in
linear elliptic differential equations and examine two test
problems, namely the identification of diffusion and reaction
parameters in a generalized linear elliptic differential
equation of second order and the identification of the Lame
constants in the linearized elasticity model. The underlying
PDE models are introduced and solution approaches are discussed
in detail. At this, we consider Newton-type algorithms,
gradient methods, multi-parameter regularization, and the
evolutionary algorithm CMAES. Consequently, numerical studies
for a two-dimensional test problem are presented. In section 4
we point out the identification of distributed material
parameters in hyperelastic deformation models. The nonlinear
elasticity boundary value problem for large deformations is
introduced. We discuss several material laws for linear elastic
(St.-Venant-Kirchhoff) materials and nonlinear Neo-Hooke,
Mooney-Rivlin, and Modified-Fung materials. For the solution of
the corresponding parameter identification problem, we focus on
an optimal control solution approach and introduce a
regularized Newton-Lagrange SQP method. The Newton-Lagrange
algorithm is demonstrated within a numerical study. Therefore,
a simplified two-dimensional Cook membrane test problem is
solved. Additionally, in section 5 the application of adaptive
methods for the solution of parameter identification problems
is discussed briefly.
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A Numerical Study of the Gas-Particle Flow in Pipework and Flow Splitting Devices of Coal-Fired Power PlantSchneider, Helfried, Frank, Thomas, Pachler, Klaus, Bernert, Klaus 17 April 2002 (has links) (PDF)
In power plants using large utility coal-fired boilers for generation of electricity the coal is pulverised in coal mills and then it has to be pneumatically transported and distributed to a larger number of burners (e.g. 30-40) circumferentially arranged in several rows around the burning chamber of the boiler. Besides the large pipework flow splitting devices are necessary for distribution of an equal amount of pulverised fuel (PF) to each of the burners. So called trifurcators (without inner fittings or guiding vanes) and ''riffle'' type bifurcators are commonly used to split the gas-coal particle flow into two or three pipes/channels with an equal amount of PF mass flow rate in each outflow cross section of the flow splitting device. These PF flow splitting devices are subject of a number of problems. First of all an uneven distribution of PF over the burners of a large utility boiler leads to operational and maintenance problems, increased level of unburned carbon and higher rates of NOX emissions. Maldistribution of fuel between burners caused by non uniform concentration of the PF (particle roping) in pipe and channel bends prior to flow splitting devices leads to uncontrolled differences in the fuel to air ratio between burners. This results in localised regions in the furnace which are fuel rich, where insufficient air causes incomplete combustion of the fuel. Other regions in the furnace become fuel lean, forming high local concentrations of NOX due to the high local concentrations of O2. Otherwise PF maldistribution can impact on power plant maintenance in terms of uneven wear on PF pipework, flow splitters as well as the effects on boiler panels (PF deposition, corrosion, slagging).
In order to address these problems in establishing uniform PF distribution over the outlet cross sections of flow splitting devices in the pipework of coal-fired power plants the present paper deals with numerical prediction and analysis of the complex gas and coal particle (PF) flow through trifurcators and ''riffle'' type bifurcators. The numerical investigation is based on a 3-dimensional Eulerian- Lagrangian approach (MISTRAL/PartFlow-3D) developed by Frank et al. The numerical method is capable to predict isothermal, incompressible, steady gas- particle flows in 3-dimensional, geometrically complex flow geometries using boundary fitted, block-structured, numerical grids. Due to the very high numerical effort of the investigated gas-particle flows the numerical approach has been developed with special emphasis on efficient parallel computing on clusters of workstations or other high performance computing architectures. Besides the aerodynamically interaction between the carrier fluid phase and the PF particles the gas-particle flow is mainly influenced by particle-wall interactions with the outer wall boundaries and the inner fittings and guiding vanes of the investigated flow splitting devices. In order to allow accurate quantitative prediction of the motion of the disperse phase the numerical model requires detailed information about the particle-wall collision process. In commonly used physical models of the particle-wall interaction this is the knowledge or experimental prediction of the restitution coefficients (dynamic friction coefficient, coefficient of restitution) for the used combination of particle and wall material, e.g. PF particles on steel.
In the present investigation these parameters of the particle-wall interaction model have been obtained from special experiments in two test facilities. Basic experiments to clarify the details of the particle-wall interaction process were made in a test facility with a spherical disk accelerator. This test facility furthermore provides the opportunity to investigate the bouncing process under normal pressure as well as under vacuum conditions, thus excluding aerodynamically influences on the motion of small particles in the near vicinity of solid wall surfaces (especially under small angles of attack). In this experiments spherical glass beads were used as particle material. In a second test facility we have investigated the real impact of non-spherical pulverised fuel particles on a steel/ceramic target. In this experiments PF particles were accelerated by an injector using inert gas like e.g. CO2 or N2 as the carrier phase in order to avoid dust explosion hazards. The obtained data for the particle-wall collision models were compared to those obtained for glass spheres, where bouncing models are proofed to be valid. Furthermore the second test facility was used to obtain particle erosion rates for PF particles on steel targets as a function of impact angles and velocities.
The results of experimental investigations has been incorporated into the numerical model. Hereafter the numerical approach MISTRAL/PartFlow-3D has been applied to the PF flow through a ''riffle'' type bifurcator. Using ICEM/CFD-Hexa as grid generator a numerical mesh with approximately 4 million grid cells has been designed for approximation of the complex geometry of the flow splitting device with all its interior fittings and guiding vanes. Based on a predicted gas flow field a large number of PF particles are tracked throughout the flow geometry of the flow-splitter. Besides mean quantities of the particle flow field like e.g. local particle concentrations, mean particle velocities, distribution of mean particle diameter, etc. it is now possible to obtain information about particle erosion on riffle plates and guiding vanes of the flow splitting device. Furthermore the influence of different roping patterns in front of the flow splitter on the uniformness of PF mass flow rate splitting after the bifurcator has been investigated numerically.
Results show the efficient operation of the investigated bifurcator in absence of particle roping, this means under conditions of an uniform PF particle concentration distribution in the inflow cross section of the bifurcator. If particle roping occurs and particle concentration differs over the pipe cross section in front of the bifurcator the equal PF particle mass flow rate splitting can be strongly deteriorated in dependence on the location and intensity of the particle rope or particle concentration irregularities. The presented results show the importance of further development of efficient rope splitting devices for applications in coal-fired power plants. Numerical analysis can be used as an efficient tool for their investigation and further optimisation under various operating and flow conditions.
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Simulation of Unsteady Gas-Particle Flows including Two-way and Four-way Coupling on a MIMD Computer ArchitecturPachler, Klaus, Frank, Thomas, Bernert, Klaus 17 April 2002 (has links) (PDF)
The transport or the separation of solid particles or droplets suspended in a fluid flow is a common task in mechanical and process engineering. To improve machinery and physical processes (e.g. for coal combustion, reduction of NO_x and soot) an optimization of complex phenomena by simulation applying the fundamental conservation equations is required. Fluid-particle flows are characterized by the ratio of density of the two phases gamma=rho_P/rho_F, by the Stokes number St=tau_P/tau_F and by the loading in terms of void and mass fraction.
Those numbers (Stokes number, gamma) define the flow regime and which relevant forces are acting on the particle. Dependent on the geometrical configuration the particle-wall interaction might have a heavy impact on the mean flow structure. The occurrence of particle-particle collisions becomes also more and more important with the increase of the local void fraction of the particulate phase. With increase of the particle loading the interaction with the fluid phase can not been neglected and 2-way or even 4-way coupling between the continous and disperse phases has to be taken into account.
For dilute to moderate dense particle flows the Euler-Lagrange method is capable to resolve the main flow mechanism. An accurate computation needs unfortunately a high number of numerical particles (1,...,10^7) to get the reliable statistics for the underlying modelling correlations. Due to the fact that a Lagrangian algorithm cannot be vectorized for complex meshes the only way to finish those simulations in a reasonable time is the parallization applying the message passing paradigma.
Frank et al. describes the basic ideas for a parallel Eulererian-Lagrangian solver, which uses multigrid for acceleration of the flow equations. The performance figures are quite good, though only steady problems are tackled. The presented paper is aimed to the numerical prediction of time-dependend fluid-particle flows using the simultanous particle tracking approach based on the Eulerian-Lagrangian and the particle-source-in-cell (PSI-Cell) approach. It is shown in the paper that for the unsteady flow prediction efficiency and load balancing of the parallel numerical simulation is an even more pronounced problem in comparison with the steady flow calculations, because the time steps for the time integration along one particle trajectory are very small per one time step of fluid flow integration and so the floating point workload on a single processor node is usualy rather low.
Much time is spent for communication and waiting time of the processors, because for cold flow particle convection not very extensive calculations are necessary. One remedy might be a highspeed switch like Myrinet or Dolphin PCI/SCI (500 MByte/s), which could balance the relative high floating point performance of INTEL PIII processors and the weak capacity of the Fast-Ethernet communication network (100 Mbit/s) of the Chemnitz Linux Cluster (CLIC) used for the presented calculations. Corresponding to the discussed examples calculation times and parallel performance will be presented. Another point is the communication of many small packages, which should be summed up to bigger messages, because each message requires a startup time independently of its size. Summarising the potential of such a parallel algorithm, it will be shown that a Beowulf-type cluster computer is a highly competitve alternative to the classical main frame computer for the investigated Eulerian-Lagrangian simultanous particle tracking approach.
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A Numerical Study of the Gas-Particle Flow in Pipework and Flow Splitting Devices of Coal-Fired Power PlantSchneider, Helfried, Frank, Thomas, Pachler, Klaus, Bernert, Klaus 17 April 2002 (has links)
In power plants using large utility coal-fired boilers for generation of electricity the coal is pulverised in coal mills and then it has to be pneumatically transported and distributed to a larger number of burners (e.g. 30-40) circumferentially arranged in several rows around the burning chamber of the boiler. Besides the large pipework flow splitting devices are necessary for distribution of an equal amount of pulverised fuel (PF) to each of the burners. So called trifurcators (without inner fittings or guiding vanes) and ''riffle'' type bifurcators are commonly used to split the gas-coal particle flow into two or three pipes/channels with an equal amount of PF mass flow rate in each outflow cross section of the flow splitting device. These PF flow splitting devices are subject of a number of problems. First of all an uneven distribution of PF over the burners of a large utility boiler leads to operational and maintenance problems, increased level of unburned carbon and higher rates of NOX emissions. Maldistribution of fuel between burners caused by non uniform concentration of the PF (particle roping) in pipe and channel bends prior to flow splitting devices leads to uncontrolled differences in the fuel to air ratio between burners. This results in localised regions in the furnace which are fuel rich, where insufficient air causes incomplete combustion of the fuel. Other regions in the furnace become fuel lean, forming high local concentrations of NOX due to the high local concentrations of O2. Otherwise PF maldistribution can impact on power plant maintenance in terms of uneven wear on PF pipework, flow splitters as well as the effects on boiler panels (PF deposition, corrosion, slagging).
In order to address these problems in establishing uniform PF distribution over the outlet cross sections of flow splitting devices in the pipework of coal-fired power plants the present paper deals with numerical prediction and analysis of the complex gas and coal particle (PF) flow through trifurcators and ''riffle'' type bifurcators. The numerical investigation is based on a 3-dimensional Eulerian- Lagrangian approach (MISTRAL/PartFlow-3D) developed by Frank et al. The numerical method is capable to predict isothermal, incompressible, steady gas- particle flows in 3-dimensional, geometrically complex flow geometries using boundary fitted, block-structured, numerical grids. Due to the very high numerical effort of the investigated gas-particle flows the numerical approach has been developed with special emphasis on efficient parallel computing on clusters of workstations or other high performance computing architectures. Besides the aerodynamically interaction between the carrier fluid phase and the PF particles the gas-particle flow is mainly influenced by particle-wall interactions with the outer wall boundaries and the inner fittings and guiding vanes of the investigated flow splitting devices. In order to allow accurate quantitative prediction of the motion of the disperse phase the numerical model requires detailed information about the particle-wall collision process. In commonly used physical models of the particle-wall interaction this is the knowledge or experimental prediction of the restitution coefficients (dynamic friction coefficient, coefficient of restitution) for the used combination of particle and wall material, e.g. PF particles on steel.
In the present investigation these parameters of the particle-wall interaction model have been obtained from special experiments in two test facilities. Basic experiments to clarify the details of the particle-wall interaction process were made in a test facility with a spherical disk accelerator. This test facility furthermore provides the opportunity to investigate the bouncing process under normal pressure as well as under vacuum conditions, thus excluding aerodynamically influences on the motion of small particles in the near vicinity of solid wall surfaces (especially under small angles of attack). In this experiments spherical glass beads were used as particle material. In a second test facility we have investigated the real impact of non-spherical pulverised fuel particles on a steel/ceramic target. In this experiments PF particles were accelerated by an injector using inert gas like e.g. CO2 or N2 as the carrier phase in order to avoid dust explosion hazards. The obtained data for the particle-wall collision models were compared to those obtained for glass spheres, where bouncing models are proofed to be valid. Furthermore the second test facility was used to obtain particle erosion rates for PF particles on steel targets as a function of impact angles and velocities.
The results of experimental investigations has been incorporated into the numerical model. Hereafter the numerical approach MISTRAL/PartFlow-3D has been applied to the PF flow through a ''riffle'' type bifurcator. Using ICEM/CFD-Hexa as grid generator a numerical mesh with approximately 4 million grid cells has been designed for approximation of the complex geometry of the flow splitting device with all its interior fittings and guiding vanes. Based on a predicted gas flow field a large number of PF particles are tracked throughout the flow geometry of the flow-splitter. Besides mean quantities of the particle flow field like e.g. local particle concentrations, mean particle velocities, distribution of mean particle diameter, etc. it is now possible to obtain information about particle erosion on riffle plates and guiding vanes of the flow splitting device. Furthermore the influence of different roping patterns in front of the flow splitter on the uniformness of PF mass flow rate splitting after the bifurcator has been investigated numerically.
Results show the efficient operation of the investigated bifurcator in absence of particle roping, this means under conditions of an uniform PF particle concentration distribution in the inflow cross section of the bifurcator. If particle roping occurs and particle concentration differs over the pipe cross section in front of the bifurcator the equal PF particle mass flow rate splitting can be strongly deteriorated in dependence on the location and intensity of the particle rope or particle concentration irregularities. The presented results show the importance of further development of efficient rope splitting devices for applications in coal-fired power plants. Numerical analysis can be used as an efficient tool for their investigation and further optimisation under various operating and flow conditions.
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Simulation of Unsteady Gas-Particle Flows including Two-way and Four-way Coupling on a MIMD Computer ArchitecturPachler, Klaus, Frank, Thomas, Bernert, Klaus 17 April 2002 (has links)
The transport or the separation of solid particles or droplets suspended in a fluid flow is a common task in mechanical and process engineering. To improve machinery and physical processes (e.g. for coal combustion, reduction of NO_x and soot) an optimization of complex phenomena by simulation applying the fundamental conservation equations is required. Fluid-particle flows are characterized by the ratio of density of the two phases gamma=rho_P/rho_F, by the Stokes number St=tau_P/tau_F and by the loading in terms of void and mass fraction.
Those numbers (Stokes number, gamma) define the flow regime and which relevant forces are acting on the particle. Dependent on the geometrical configuration the particle-wall interaction might have a heavy impact on the mean flow structure. The occurrence of particle-particle collisions becomes also more and more important with the increase of the local void fraction of the particulate phase. With increase of the particle loading the interaction with the fluid phase can not been neglected and 2-way or even 4-way coupling between the continous and disperse phases has to be taken into account.
For dilute to moderate dense particle flows the Euler-Lagrange method is capable to resolve the main flow mechanism. An accurate computation needs unfortunately a high number of numerical particles (1,...,10^7) to get the reliable statistics for the underlying modelling correlations. Due to the fact that a Lagrangian algorithm cannot be vectorized for complex meshes the only way to finish those simulations in a reasonable time is the parallization applying the message passing paradigma.
Frank et al. describes the basic ideas for a parallel Eulererian-Lagrangian solver, which uses multigrid for acceleration of the flow equations. The performance figures are quite good, though only steady problems are tackled. The presented paper is aimed to the numerical prediction of time-dependend fluid-particle flows using the simultanous particle tracking approach based on the Eulerian-Lagrangian and the particle-source-in-cell (PSI-Cell) approach. It is shown in the paper that for the unsteady flow prediction efficiency and load balancing of the parallel numerical simulation is an even more pronounced problem in comparison with the steady flow calculations, because the time steps for the time integration along one particle trajectory are very small per one time step of fluid flow integration and so the floating point workload on a single processor node is usualy rather low.
Much time is spent for communication and waiting time of the processors, because for cold flow particle convection not very extensive calculations are necessary. One remedy might be a highspeed switch like Myrinet or Dolphin PCI/SCI (500 MByte/s), which could balance the relative high floating point performance of INTEL PIII processors and the weak capacity of the Fast-Ethernet communication network (100 Mbit/s) of the Chemnitz Linux Cluster (CLIC) used for the presented calculations. Corresponding to the discussed examples calculation times and parallel performance will be presented. Another point is the communication of many small packages, which should be summed up to bigger messages, because each message requires a startup time independently of its size. Summarising the potential of such a parallel algorithm, it will be shown that a Beowulf-type cluster computer is a highly competitve alternative to the classical main frame computer for the investigated Eulerian-Lagrangian simultanous particle tracking approach.
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Parallele Algorithmen für die numerische Simulation dreidimensionaler, disperser Mehrphasenströmungen und deren Anwendung in der VerfahrenstechnikFrank, Thomas 21 June 2002 (has links)
Many fluid flow processes in nature and technology are characterized by the presence
and coexistence of two ore more phases. These two- or multiphase flows are furthermore
characterized by a greater complexity of possible flow phenomena and phase interactions
then in single phase flows and therefore the numerical simulation of these multiphase
flows is usually demanding a much higher numerical effort. The presented work
summarizes the research and development work of the author and his research group on
"Numerical Methods for Multiphase Flows" at the University of Technology, Chemnitz over the
last years. This work was focussed on the development and application of numerical
approaches for the prediction of disperse fluid-particle flows in the field of
fluid mechanics and process technology.
A main part of the work presented here is concerned with the modelling of different
physical phenomena in fluid-particle flows under the paradigm of the Lagrangian treatment
of the particle motion in the fluid. The Eulerian-Lagrangian approach has proved to be an
especially well suited numerical approach for the simulation of disperse multiphase flows.
On the other hand its application requires a large amount of (parallel) computational power
and other computational ressources. The models described in this work give a mathematical
description of the relevant forces and momentum acting on a single spherical particle in
the fluid flow field, the particle-wall interaction and the particle erosion to the wall.
Further models has been derived in order to take into account the influence of
particle-particle collisions on the particle motion as well as the interaction of the
fluid flow turbulence with the particle motion. For all these models the state-of-the-art
from literature is comprehensively discussed.
The main field of interest of the work presented here is in the area of development,
implementation, investigation and comparative evaluation of parallelization
methods for the Eulerian-Lagrangian approach for the simulation of disperse multiphase
flows. Most of the priorly existing work of other authors is based on shared-memory
approaches, quasi-serial or static domain decomposition approaches. These parallelization
methods are mostly limited in theire applicability and scalability to parallel computer
architectures with a limited degree of parallelism (a few number of very powerfull compute
nodes) and to more or less homogeneous multiphase flows with uniform particle concentration
distribution and minor complexity of phase interactions. This work now presents a novel
parallelization method developed by the author, realizing a dynamic load balancing
for the Lagrangian approach (DDD - Dynamic Domain Decomposition) and therefore leading
to a substantial decrease in total computation time necessary for multiphase flow
computations with the Eulerian-Lagrangian approach.
Finally, the developed and entirely parallelized Eulerian-Lagrangian approach MISTRAL/PartFlow-3D
offers the opportunity of efficient investigation of disperse multiphase flows with
higher concentrations of the disperse phase and the resulting strong phase interaction
phenomena (four-way coupling). / Viele der in Natur und Technik ablaufenden Strömungsvorgänge sind durch die
Koexistenz zweier oder mehrerer Phasen gekennzeichnet. Diese sogenannten Zwei- oder
Mehrphasensysteme zeichnen sich durch ein hohes Maß an Komplexität aus und
erfordern oft einen sehr hohen rechentechnischen Aufwand zu deren numerischer Simulation.
Die vorliegende Arbeit faßt langjährige Forschungs- und Entwicklungsarbeiten
des Autors und seiner Forschungsgruppe "Numerische Methoden für Mehrphasenströmungen"
an der TU Chemnitz zusammen, die sich mit der Entwicklung und Anwendung numerischer
Berechnungsverfahren für disperse Fluid-Partikel-Strömungen auf dem Gebiet
der Strömungs- und Verfahrenstechnik befassen.
Ein wesentlicher Teil der Arbeit befaßt sich mit der Modellierung unterschiedlicher
physikalischer Phänomene in Fluid-Partikel-Strömungen unter dem Paradigma der Lagrange'schen
Betrachtungsweise der Partikelbewegung. Das Euler-Lagrange-Verfahren hat sich als
besonders geeignetes Berechnungsverfahren für die numerische Simulation disperser
Mehrphasenströmungen erwiesen, stellt jedoch in seiner Anwendung auch höchste
Anforderungen an die Ressourcen der verwendeten (parallelen) Rechnerarchitekturen.
Die näher ausgeführten mathematisch-physikalischen Modelle liefern eine Beschreibung
der auf eine kugelförmige Einzelpartikel im Strömungsfeld wirkenden Kräfte
und Momente, der Partikel-Wand-Wechselwirkung und der Partikelerosion. Weitere Teilmodelle
dienen der Berücksichtigung von Partikel-Partikel-Stoßvorgängen und der
Wechselwirkung zwischen Fluidturbulenz und Partikelbewegung.
Der Schwerpunkt dieser Arbeit liegt im Weiteren in der Entwicklung, Untersuchung und vergleichenden
Bewertung von Parallelisierungsverfahren für das Euler-Lagrange-Verfahren zur Berechnung von
dispersen Mehrphasenströmungen. Zuvor von anderen Autoren entwickelte Parallelisierungsmethoden
für das Lagrange'sche Berechnungsverfahren basieren im Wesentlichen auf Shared-Memory-Ansätzen,
Quasi-Seriellen Verfahren oder statischer Gebietszerlegung (SDD) und sind somit in ihrer
Einsetzbarkeit und Skalierbarkeit auf Rechnerarchitekturen mit relativ geringer Parallelität
und auf weitgehend homogene Mehrphasenströmungen mit geringer Komplexität der Phasenwechselwirkungen
beschränkt. In dieser Arbeit wird eine vom Autor entwickelte, neuartige Parallelisierungsmethode
vorgestellt, die eine dynamische Lastverteilung für das Lagrange-Verfahren ermöglicht (DDD - Dynamic
Domain Decomposition) und mit deren Hilfe eine deutliche Reduzierung der Gesamtausführungszeiten
einer Mehrphasenströmungsberechnung mit dem Euler-Lagrange-Verfahren möglich ist.
Im Ergebnis steht mit dem vom Autor und seiner Forschungsgruppe entwickelten vollständig parallelisierten
Euler-Lagrange-Verfahren MISTRAL/PartFlow-3D ein numerisches Berechnungsverfahren zur Verfügung,
mit dem disperse Mehrphasenströmungen mit höheren Konzentrationen der dispersen Phase und
daraus resultierenden starken Phasenwechselwirkungen (Vier-Wege-Kopplung) effektiv untersucht
werden können.
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