TY  - THES
A1  - Schmitz, Tonia Annick
T1  - Entwicklung und Bilanzierung eines Photobioreaktorsystems zur Makroalgenkultivierung am Standort einer landwirtschaftlichen Biogasanlage
N2  - Marine Makroalgen besitzen vielversprechende Eigenschaften und Inhaltsstoffe für die Verwendung als Energieträger, Nahrungsmittel oder als Ausgangsstoff für Pharmazeutika. Dass die Quantität und Qualität der in natürlicher Umgebung wachsenden Makroalgen schwankt, reduziert jedoch deren Verwertbarkeit und erschwert die Erschließung hochpreisiger Marktsegmente. Zudem ist eine Ausweitung der Zucht in marinen und küstennahen Aquakulturen in Europa gegenwärtig wenig aussichtsreich, da vielversprechende Areale bereits zum Fischfang oder als Erholungs- bzw. Naturschutzgebiete ausgewiesen sind. Im Rahmen dieser Arbeit wird demzufolge ein geschlossenes Photobioreaktorsystem zur Makroalgenkultivierung entwickelt, welches eine umfassende Kontrolle der abiotischen Kultivierungsparameter und eine effektive Aufbereitung des Kulturmediums vorsieht, um eine standortunabhängige Algenproduktion zu ermöglichen. Zur Bilanzierung des Gesamtkonzeptes einer Kultivierung und Verwertung (stofflich oder energetisch) werden die spezifischen Wachstumsraten und Methanbildungspotentiale der Algenarten Ulva intestinalis, Fucus vesiculosus und Palmaria palmata in praktischen Versuchen ermittelt.

Im Ergebnis wird für den gegenwärtigen Entwicklungsstand der Kultivierungsanlage eine positive Bilanz für die stoffliche Verwertung der Algenart Ulva intestinalis und eine negative Bilanz für die energetische Verwertung aller untersuchten Algenarten erzielt. Wird ein Optimalszenario betrachtet, indem die Besatzdichten und Wachstumsraten der Algen in der Zucht erhöht werden, bleibt die Energiebilanz negativ. Allerdings summieren sich die finanzielle Einnahmen durch einen Verkauf der Algen als Produkt auf jährlich 460.869€ für Ulva intestinalis, 4.010€ für Fucus vesiculosus und 16.913€ für Palmaria palmata. Im Ergebnis ist insbesondere eine stoffliche Verwertung der gezüchteten Grünalge Ulva intestinalis anzustreben und die Produktivität der Zuchtanlage im Sinne des Optimalszenarios zu steigern.
N2  - Marine macroalgae have renown properties as feedstock for fuel, food or pharmaceuticals. However, since the quantity and quality of naturally grown algae vary widely, their exploitability is reduced – especially for producers in high priced markets. Moreover, the expansion of marine or shore-based cultivation systems is unlikely in Europe, since promising sites either lie in fishing zones, recreational areas or natural reserves. The aim of this thesis was therefore to develop a closed photobioreactor system enabling full control of abiotic environmental parameters and an effective reconditioning of the cultivation medium in order to produce marine macroalgae at sites distant from shore. Using environmental management accounting methods, the potential output of macroalgae cultivation and valorization (product- or energy-based) is being assessed based on the specific growth rates and methane yields achievable with the species Ulva intestinalis, Fucus vesiculosus and Palmaria palmata.

The balancing results for the status quo of the developed cultivation system show a positive outcome for a product-based valorization of the species Ulva intestinalis and a negative outcome for an energy-based valorization of all species investigated. Considering an optimum scenario providing an increase of growth rates and culture density, the balance of an energy-based valorization remains negative for all three species. However, the financial income by selling the cultivated macroalgae as a product sums up to a yearly amount of 460.869€ for Ulva intestinalis, 4.010€ for Fucus vesiculosus and 16.913€ for Palmaria palmata. Concluding, a product-based valorization seems promising – especially for the green algae Ulva intestinalis – when the productivity of the developed cultivation system is increased in accordance to the framework of the optimum scenario.
KW  - Makroalgen
KW  - Photobioreaktor
KW  - Biogas
KW  - Makroalgen
KW  - Photobioreaktorsystem
KW  - Biogasproduktion
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200604-41774
ER  - 
TY  - THES
A1  - Salavati, Mohammad
T1  - Multi-Scale Modeling of Mechanical and Electrochemical Properties of 1D and 2D Nanomaterials, Application in Battery Energy Storage Systems
N2  - Material properties play a critical role in durable products manufacturing. Estimation of the precise characteristics in different scales requires complex and expensive experimental measurements. Potentially, computational methods can provide a platform to determine the fundamental properties before the final experiment. Multi-scale computational modeling leads to the modeling of the various time, and length scales include nano, micro, meso, and macro scales. These scales can be modeled separately or in correlation with coarser scales. Depend on the interested scales modeling, the right selection of multi-scale methods leads to reliable results and affordable computational cost. The present dissertation deals with the problems in various length and time scales using computational methods include density functional theory (DFT), molecular mechanics (MM), molecular dynamics (MD), and finite element (FE) methods. 
Physical and chemical interactions in lower scales determine the coarser scale properties. Particles interaction modeling and exploring fundamental properties are significant challenges of computational science. Downscale modelings need more computational effort due to a large number of interacted atoms/particles. To deal with this problem and bring up a fine-scale (nano) as a coarse-scale (macro) problem, we extended an atomic-continuum framework. The discrete atomic models solve as a continuum problem using the computationally efficient FE method.  MM or force field method based on a set of assumptions approximates a solution on the atomic scale. In this method, atoms and bonds model as a harmonic oscillator with a system of mass and springs. The negative gradient of the potential energy equal to the forces on each atom. In this way, each bond's total potential energy includes bonded, and non-bonded energies are simulated as equivalent structural strain energies. Finally, the chemical nature of the atomic bond is modeled as a piezoelectric beam element that solves by the FE method.  
Exploring novel materials with unique properties is a demand for various industrial applications. During the last decade, many two-dimensional (2D) materials have been synthesized and shown outstanding properties. Investigation of the probable defects during the formation/fabrication process and studying their strength under severe service life are the critical tasks to explore performance prospects. We studied various defects include nano crack, notch, and point vacancy (Stone-Wales defect) defects employing MD analysis. Classical MD has been used to simulate a considerable amount of molecules at micro-, and meso- scales.  Pristine and defective nanosheet structures considered under the uniaxial tensile loading at various temperatures using open-source LAMMPS codes. The results were visualized with the open-source software of OVITO and VMD. 
Quantum based first principle calculations have been conducting at electronic scales and known as the most accurate Ab initio methods. However, they are computationally expensive to apply for large systems. We used density functional theory (DFT) to estimate the mechanical and electrochemical response of the 2D materials. Many-body Schrödinger's equation describes the motion and interactions of the solid-state particles. Solid describes as a system of positive nuclei and negative electrons, all electromagnetically interacting with each other, where the wave function theory describes the quantum state of the set of particles. However, dealing with the 3N coordinates of the electrons, nuclei, and N coordinates of the electrons spin components makes the governing equation unsolvable for just a few interacted atoms. Some assumptions and theories like Born Oppenheimer and Hartree-Fock mean-field and Hohenberg-Kohn theories are needed to treat with this equation. First, Born Oppenheimer approximation reduces it to the only electronic coordinates. Then Kohn and Sham, based on Hartree-Fock and Hohenberg-Kohn theories, assumed an equivalent fictitious non-interacting electrons system as an electron density functional such that their ground state energies are equal to a set of interacting electrons. Exchange-correlation energy functionals are responsible for satisfying the equivalency between both systems. The exact form of the exchange-correlation functional is not known. However, there are widely used methods to derive functionals like local density approximation (LDA), Generalized gradient approximation (GGA), and hybrid functionals (e.g., B3LYP). In our study, DFT performed using VASP codes within the GGA/PBE approximation, and visualization/post-processing of the results realized via open-source software of VESTA.
The extensive DFT calculations are conducted 2D nanomaterials prospects as anode/cathode electrode materials for batteries. Metal-ion batteries' performance strongly depends on the design of novel electrode material. Two-dimensional (2D) materials have developed a remarkable interest in using as an electrode in battery cells due to their excellent properties. Desirable battery energy storage systems (BESS) must satisfy the high energy density, safe operation, and efficient production costs. Batteries have been using in electronic devices and provide a solution to the environmental issues and store the discontinuous energies generated from renewable wind or solar power plants. Therefore, exploring optimal electrode materials can improve storage capacity and charging/discharging rates, leading to the design of advanced batteries.
Our results in multiple scales highlight not only the proposed and employed methods' efficiencies but also promising prospect of recently synthesized nanomaterials and their applications as an anode material. In this way, first, a novel approach developed for the modeling of the 1D nanotube as a continuum piezoelectric beam element.  The results converged and matched closely with those from experiments and other more complex models. Then mechanical properties of nanosheets estimated and the failure mechanisms results provide a useful guide for further use in prospect applications. Our results indicated a comprehensive and useful vision concerning the mechanical properties of nanosheets with/without defects. Finally, mechanical and electrochemical properties of the several 2D nanomaterials are explored for the first time—their application performance as an anode material illustrates high potentials in manufacturing super-stretchable and ultrahigh-capacity battery energy storage systems (BESS). Our results exhibited better performance in comparison to the available commercial anode materials.
KW  - Batterie
KW  - Modellierung
KW  - Nanostrukturiertes Material
KW  - Mechanical properties
KW  - Multi-scale modeling
KW  - Energiespeichersystem
KW  - Elektrodenmaterial
KW  - Elektrode
KW  - Mechanische Eigenschaft
KW  - Elektrochemische Eigenschaft
KW  - Electrochemical properties
KW  - Battery development
KW  - Nanomaterial
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200623-41830
ER  - 
TY  - THES
A1  - Radmard Rahmani, Hamid
T1  - Artificial Intelligence Approach for Seismic Control of Structures
N2  - Abstract In the first part of this research, the utilization of tuned mass dampers in the vibration control of tall buildings during earthquake excitations is studied. The main issues such as optimizing the parameters of the dampers and studying the effects of frequency content of the target earthquakes are addressed.

Abstract The non-dominated sorting genetic algorithm method is improved by upgrading generic operators, and is utilized to develop a framework for determining the optimum placement and parameters of dampers in tall buildings. A case study is presented in which the optimal placement and properties of dampers are determined for a model of a tall building under different earthquake excitations through computer simulations.

Abstract In the second part, a novel framework for the brain learning-based intelligent seismic control of smart structures is developed. In this approach, a deep neural network learns how to improve structural responses during earthquake excitations using feedback control.

Abstract Reinforcement learning method is improved and utilized to develop a framework for training the deep neural network as an intelligent controller. The efficiency of the developed framework is examined through two case studies including a single-degree-of-freedom system and a high-rise building under different earthquake excitation records.

Abstract The results show that the controller gradually develops an optimum control policy to reduce the vibrations of a structure under an earthquake excitation through a cyclical process of actions and observations.

Abstract It is shown that the controller efficiently improves the structural responses under new earthquake excitations for which it was not trained. Moreover, it is shown that the controller has a stable performance under uncertainties.
KW  - Erdbeben
KW  - seismic control
KW  - tuned mass damper
KW  - reinforcement learning
KW  - earthquake
KW  - machine learning
KW  - Operante Konditionierung
KW  - structural control
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200417-41359
ER  - 
TY  - THES
A1  - Rabizadeh, Ehsan
T1  - Goal-oriented A Posteriori Error Estimation and Adaptive Mesh Refinement in 2D/3D Thermoelasticity Problems
T1  - Zielorientierte a posteriori Fehlerabschätzung und adaptive Netzverfeinerung bei 2D- und 3Dthermoelastischen Problemen
N2  - In recent years, substantial attention has been devoted to thermoelastic multifield problems and their numerical analysis. Thermoelasticity is one of the important categories of multifield problems which deals with the effect of mechanical and thermal disturbances on an elastic body. In other words, thermoelasticity encompasses the phenomena that describe the elastic and thermal behavior of solids and their interactions under thermo-mechanical loadings. Since providing an analytical solution for general coupled thermoelasticity problems is mathematically complicated, the development of alternative numerical solution techniques seems essential.

Due to the nature of numerical analysis methods, presence of error in results is inevitable, therefore in any numerical simulation, the main concern is the accuracy of the approximation. There are different error estimation (EE) methods to assess the overall quality of numerical approximation. In many real-life numerical simulations, not only the overall error, but also the local error or error in a particular quantity of interest is of main interest. The error estimation techniques which are developed to evaluate the error in the quantity of interest are known as “goal-oriented” error estimation (GOEE) methods.

This project, for the first time, investigates the classical a posteriori error estimation and goal-oriented a posteriori error estimation in 2D/3D thermoelasticity problems. Generally, the a posteriori error estimation techniques can be categorized into two major branches of recovery-based and residual-based error estimators. In this research, application of both recovery- and residual-based error estimators in thermoelasticity are studied. Moreover, in order to reduce the error in the quantity of interest efficiently and optimally in 2D and 3D thermoelastic problems, goal-oriented adaptive mesh refinement is performed. 

As the first application category, the error estimation in classical Thermoelasticity (CTE) is investigated. In the first step, a rh-adaptive thermo-mechanical formulation based on goal-oriented error estimation is proposed.The developed goal-oriented error estimation relies on different stress recovery techniques, i.e., the superconvergent patch recovery (SPR), L2-projection patch recovery (L2-PR), and weighted superconvergent patch recovery (WSPR). Moreover, a new adaptive refinement strategy (ARS) is presented that minimizes the error in a quantity of interest and refines the discretization such that the error is equally distributed in the refined mesh. The method is validated by numerous numerical examples where an analytical solution or reference solution is available.

After investigating error estimation in classical thermoelasticity and evaluating the quality of presented error estimators, we extended the application of the developed goal-oriented error estimation and the associated adaptive refinement technique to the classical fully coupled dynamic thermoelasticity. In this part, we present an adaptive method for coupled dynamic thermoelasticity problems based on goal-oriented error estimation. We use dimensionless variables in the finite element formulation and for the time integration we employ the acceleration-based Newmark-_ method. In this part, the SPR, L2-PR, and WSPR recovery methods are exploited to estimate the error in the quantity of interest (QoI). By using
adaptive refinement in space, the error in the quantity of interest is minimized. Therefore,  the discretization is refined such that the error is equally distributed in the refined mesh. We demonstrate the efficiency of this method by numerous numerical examples.
After studying the recovery-based error estimators, we investigated the residual-based error estimation in thermoelasticity. In the last part of this research, we present a 3D adaptive method for thermoelastic problems based on goal-oriented error estimation where the error is measured with respect to a pointwise quantity of interest. We developed a method for a posteriori error estimation and mesh adaptation based on dual weighted residual (DWR) method relying on the duality principles and consisting of an adjoint problem solution. Here, we consider the application of the derived estimator and mesh refinement to two-/three-dimensional (2D/3D) thermo-mechanical multifield problems. In this study, the goal is considered to be given by singular pointwise functions, such as the point value or point value derivative at a specific point of interest (PoI). An adaptive algorithm has been adopted to refine the mesh to minimize the goal in the quantity of interest.

The mesh adaptivity procedure based on the DWR method is performed by adaptive local h-refinement/coarsening with allowed hanging nodes. According to the proposed DWR method, the error contribution of each element is evaluated. In the refinement process, the contribution of each element to the goal error is considered as the mesh refinement criterion.

In this study, we substantiate the accuracy and performance of this method by several numerical examples with available analytical solutions. Here, 2D and 3D problems under thermo-mechanical loadings are considered as benchmark problems. To show how accurately the derived estimator captures the exact error in the evaluation of the pointwise quantity of interest, in all examples, considering the analytical solutions, the goal error effectivity index as a standard measure of the quality of an estimator is calculated. Moreover, in order to demonstrate the efficiency of the proposed method and show the optimal behavior of the employed refinement method, the results of different conventional error estimators and refinement techniques (e.g., global uniform refinement, Kelly, and weighted Kelly techniques) are used for comparison.
N2  - Einleitung und Motivation:	
1-	Im Laufe der letzten Jahrzehnte wurde den Mehrfeldproblemen und ihrer numerischen Analyse große Aufmerksamkeit gewidmet. Bei Mehrfeldproblemen wird die Wechselwirkung zwischen verschiedenen Feldern wie elastischen, elektrischen, magnetischen, chemischen oder thermischen Feldern untersucht. Eine wichtige Kategorie von Mehrfeldproblemen ist die Thermoelastizität. In der Thermoelastizität werden neben dem mechanischen Feld (Verschiebungen) auch das thermische Feld (Temperatur) und deren Auswirkungen aufeinander untersucht.
2-	In fortgeschrittenen und sensible Anwendungen mit Temperaturänderung (z. B. LNG-, CNG- oder LPG-Speichertanks bei Sonnentemperatur im Sommer) ist die Elastizitätstheorie, die nur Verschiebungen berücksichtigt, nicht ausreichend. In diesen Fällen ist die Verwendung einer thermoelastischen Formulierung unumgänglich, um zuverlässige Ergebnisse zu erzielen. 
3-	Da eine analytische Lösung für thermoelastische Probleme sehr selten bestimmbar ist, wird sie durch numerische Methoden ersetzt. Allerdings sind die numerischen Ergebnisse nicht exakt und approximieren nur die exakte Lösung. Daher sind Fehler in den numerischen Ergebnissen unvermeidlich.
4-	In jeder numerischen Simulation ist die Genauigkeit der Approximation das Hauptanliegen. Daher wurden verschiedene Fehlerschätzungstechniken entwickelt, um den Fehler der numerischen Lösung zu schätzen. Die herkömmlichen Fehlerschätzungsmethoden geben nur einen allgemeinen Überblick über die Gesamtgenauigkeit einer Näherungslösung. Bei vielen realen Problemen ist jedoch anstelle der Gesamtgenauigkeit die örtliche Genauigkeit (z. B. die Genauigkeit an einem bestimmten Punkt) von großem Interesse
5-	Herkömmliche Fehlerschätzer berechnen Fehler in gewissen Normen. In der Ingenieurpraxis interessieren allerdings Fehler in anderen Zielgrößen, beispielsweise in der Last-Verformungs-Kurve oder in gewissen Spannungs-komponenten und speziellen Positionen. Dafür wurden sog. zielorientierte Fehlerschätzer entwickelt.
6-	Die meisten numerischen Methoden unterteilen das Gebiet in kleine Teile (Element/Zelle), um das Problem zu lösen. Die Verwendung sehr feiner Elemente erhöht die Simulationsgenauigkeit, erhöht aber auch die Rechenzeit drastisch. Dieses Problem wird durch adaptive Methoden (AM) gelöst. AM können die Rechenzeit deutlich verringern. Bei adaptiven Methoden spielt die Fehlerschätzung eine Schlüsselrolle. Die Verfeinerung der Diskretisierung wird von einer Fehlerschätzung der Lösung kontrolliert und gesteuert (Elemente mit einem höheren geschätzten Fehler werden zur Verfeinerung/Aufteilung ausgewählt). 
Problemstellung und Zielsetzung der Arbeit
7-	Die thermoelastischen Probleme können in zwei Hauptgruppen eingeteilt werden: Klassische Thermoelastizität (KTE) und klassische gekoppelte Thermoelastizität (KKTE). In jeder Gruppe werden verschiedene thermoelastische Probleme mit verschiedenen Geometrien, und Rand-/Anfangsbedingungen untersucht. In dieser Untersuchung werden die KTE- und KKTE-Probleme numerisch gelöst und alle numerischen Lösungen durch Fehlerschätzung bewertet. 
8-	In dieser Arbeit werden die Gesamtgenauigkeit der numerischen Lösung durch herkömmliche globale Fehlerschätzverfahren (auch als recovery-basierte Methoden bekannt) und die Genauigkeit der Lösung in bestimmten Punkten durch neue lokale Methoden (z. B. Dual-gewichtete Residuumsmethode oder DWR-Methode) bewertet.
9-	Bei den dynamischen thermoelastischen Problemen ändern sich die Problembedin-gungen und anschließend die Lösung mit der Zeit. Daher werden die Fehler in jedem Zeitschritt geschätzt, um die Genauigkeit über die Zeit zu erhalten.
10-	In dieser Dissertation wurde eine neue adaptive Gitter-Verfeinerung (AGV)-Technik entwickelt und für thermoelastische Probleme implementiert.
Stand der Wissenschaft
11-	Da die Thermoelastizität im Vergleich zu anderen mechanischen Bereichen wie der Elastizität nicht so umfangreich untersucht ist, wurden nur sehr begrenzte Untersuchungen durchgeführt, um die numerischen Fehler abzuschätzen und zu kontrollieren. Alle diese Untersuchungen konzentrierten sich auf die konventionellen Techniken, die nur den Gesamtfehler abschätzen können. Um die lokalen Fehler (wie punktweise Fehler oder Fehler an einem bestimmten Punkt) abzuschätzen, ist die Verwendung der zielorientierten Fehlerschätzungstechniken unvermeidlich. Die Implementierung der recovery-basierten zielorientierten Fehlerschätzung in der Thermoelastizität wird vor diesem Projekt nicht untersucht.
12-	Viele numerische Analysen der dynamischen thermoelastischen Probleme basieren auf der Laplace-Transformationsmethode. Bei dieser Methode ist es praktisch nicht möglich, den Fehler in jedem Zeitschritt abzuschätzen. Daher wurden bisher die herkömmlichen globalen oder lokalen zielorientierten Fehlerschätzungsverfahren nicht in der dynamischen Thermoelastizität implementiert.
13-	Eine der neuesten fortgeschrittenen zielorientierten Fehlerschätzungsmethoden ist die Dual-gewichtete Residuumsmethode (DWR-Methode). Die DWR-Methode, die punktweise Fehler (wie Verschiebungs-, mechanische Spannungs- oder Dehnungsfehler an einem bestimmten Punkt) abschätzen kann, wird bei elastischen Problemen angewendet. Es wurde jedoch kein Versuch unternommen, die DWR-Methode für die thermoelastischen Probleme zu formulieren.
14-	In numerischen Simulationen sollte das Gitter verfeinert werden, um den Fehler zu verringern. Viele Verfeinerungstechniken basieren auf den globalen Fehlerschätzern, die versuchen, den Fehler der gesamten Lösung zu reduzieren. Daher sind diese Verfeinerungsmethoden zum reduzieren der lokalen Fehler nicht effizient. Wenn nur die Lösung an bestimmten Punkten interessiert ist und der Fehler dort reduziert werden will, sollten die zielorientierten Verfeinerungsmethoden angewendet werden, die vor dieser Untersuchung nicht in thermoelastischen Problemen entwickelt und implementiert wurden.
15-	Die realen Probleme sind in der Regel 3D-Probleme, und die Simulation mit vereinfachten 2D-Fällen zeigt nicht alle Aspekte des Problems. Wie bereits erwähnt, sollten in der numerischen Simulation zur Erhöhung der Genauigkeit Gitterverfeinerungstechniken eingesetzt werden. Die konventionell verfeinerten Gitter, die durch gleichmäßige Aufteilung aller Elemente erreicht werden, erhöhen die Rechenzeit. Diese Simulationszeiterhöhung bei 3D-Problemen ist enorm. Dieses Problem wird durch die Verwendung der intelligenten Verfeinerung anstelle der globalen gleichmäßigen Verfeinerung gelöst. In diesem Projekt wurde erstmals die zielorientierte adaptive Gitterverfeinerung (AGV) bei thermoelastischen 3D-Problemen entwickelt und implementiert.
Forschungsmethodik
16-	In dieser Arbeit werden die beiden Haupttypen der thermoelastischen Probleme (KTE und KKTE) untersucht. Das System der partiellen Differentialgleichung der Thermoelastizität besteht aus zwei Hauptgleichungen: der herkömmlichen Gleichgewichtsgleichung und der Energiebilanzgleichung.
17-	In diesem Projekt wird die Finite-Elemente-Methode (FEM) verwendet, um die Probleme numerisch zu simulieren.
18-	Der Computercode zur Lösung von 2D- und 3D-Problemen wurde in den Program-miersprachen MATLAB bzw. C++ entwickelt. Um die Rechenzeit zu verkürzen und die Computerressourcen effizient zu nutzen, wurden Parallelprogrammierungs- und Optimierungsalgorithmen eingesetzt.
19-	Nachdem die Probleme numerisch gelöst wurden, wurden zwei verschiedene Arten von globalen und lokalen Fehlerschätzungstechniken implementiert, um den Fehler zu schätzen und die Genauigkeit der Lösung zu messen. Der globale Typ ist die recovery-basierte zielorientierte Fehlerabschätzung, die wiederum in drei Unterkategorien von SPR-, L2-PR- und WSPR-Methoden unterteilt ist. Der lokale Typ ist die dual-gewichtete residuumsbasierte zielorientierte Fehlerabschätzung. Die Formulierung dieser Methoden wurde für thermoelastische Probleme entwickelt.
20-	Schließlich wurde nach der Fehlerschätzung die entwickelte AGV-Methode implementiert.
Wesentliche Ergebnisse und Schlussfolgerungen
21-	In diesem Projekt wurde die Fehlerschätzung der Thermoelastizität in den folgenden drei Schritten untersucht:
1-	Recovery-basierte Fehlerschätzung in statischen thermo Problemen (KTE), 
2- Recovery-basierte Fehlerabschätzung in dynamischen thermo Problemen (KKTE), 3- Residuumsbasierte Fehlerschätzung in statischen thermo Problemen (KTE),
22-	Im ersten Schritt, wurde das recovery-basierte  Fehlerschätzverfahren auf mehrere stationäre thermoelastische Probleme angewendet. Einige der untersuchten Probleme verfügen über analytische Lösungen. Der Vergleich der numerischen Ergebnisse mit der analytischen (exakten) Lösung zeigt, dass die WSPR-Methode die genaueste unter den SPR, L2-PR und WSPR Techniken ist.
23-	Darüber hinaus schließen wir aus den Ergebnissen des ersten Schritts, dass die zielorientierte Verfeinerung, im Vergleich zur herkömmlichen gleichmäßigen Total-Verfeinerungsmethode, nur ein Drittel der Unbekannten erfordert, um das Problem mit der gleichen Genauigkeit zu lösen. Daher benötigt die zielorientierte Adaptivität im Vergleich zu herkömmlichen Methoden viel weniger Rechenzeit, um die gleiche Genauigkeit zu erreichen.
24-	Im zweiten Schritt, sind die Fehlerschätzungstechniken dieselben wie im ersten Schritt, aber die untersuchten Probleme sind dynamisch und nicht statisch. Der Vergleich der numerischen Ergebnisse mit den analytischen Ergebnissen in einem Benchmark-Problem bestätigt die Genauigkeit der verwendeten Methode.
25-	Die Ergebnisse des zweiten Schritts zeigen, dass die geschätzten Fehler in allen gekoppelten Problemen niedriger sind als die ähnlichen ungekoppelten. Bei diesen Problemen reduziert die Implementierung der entwickelten adaptiven Methode den Fehler erheblich.
26-	Im dritten Schritt wurde das residuumsbasierte Fehlerabschätzungsverfahren auf mehrere thermoelastische Probleme im stationären Zustand angewendet. In allen Beispielen wird die Genauigkeit der Methode durch analytische Lösungen überprüft. Die numerischen Ergebnisse zeigen eine sehr gute Übereinstimmung mit der analytischen Lösung sowohl bei 2D- als auch bei 3D-Problemen.
27-	Im dritten Schritt werden die Ergebnisse der DWR-Verfeinerung mit Kelly-, W-Kelly- und gleichmäßigen Total-Verfeinerungstechniken verglichen. Die entwickelte DWR-Methode zeigt im Vergleich zu den anderen Methoden die beste Effizienz. Um beispielsweise die Fehlertoleranz von 10-6 zu erreichen, enthält das DWR-Gitter nur 2% unbekannte Parameter im Vergleich zu einem gleichmäßig verfeinerten Gitter. Die Verwendung des DWR-Verfahrens spart daher erhebliche Rechenzeit und Kosten.
KW  - Mesh Refinement
KW  - Thermoelastizität
KW  - Goal-oriented A Posteriori Error Estimation
KW  - 2D/3D Adaptive Mesh Refinement
KW  - Thermoelasticity
KW  - Deal ii C++ code
KW  - recovery-based and residual-based error estimators
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20201113-42864
ER  - 
TY  - THES
A1  - Kavrakov, Igor
T1  - Synergistic Framework for Analysis and Model Assessment in Bridge Aerodynamics and Aeroelasticity
N2  - Wind-induced vibrations often represent a major design criterion for long-span bridges. This work deals with the assessment and development of models for aerodynamic and aeroelastic analyses of long-span bridges.
Computational Fluid Dynamics (CFD) and semi-analytical aerodynamic models are employed to compute the bridge response due to both turbulent and laminar free-stream. For the assessment of these models, a comparative methodology is developed that consists of two steps, a qualitative and a quantitative one. The first, qualitative, step involves an extension
of an existing approach based on Category Theory and its application to the field of bridge aerodynamics. Initially, the approach is extended to consider model comparability and completeness. Then, the complexity of the CFD and twelve semi-analytical models are evaluated based on their mathematical constructions, yielding a diagrammatic representation of model quality. 
In the second, quantitative, step of the comparative methodology, the discrepancy of a system response quantity for time-dependent aerodynamic models is quantified using comparison metrics for time-histories. Nine metrics are established on a uniform basis to quantify the discrepancies in local and global signal features that are of interest in bridge aerodynamics. These signal features involve quantities such as phase, time-varying frequency and magnitude content, probability density, non-stationarity, and nonlinearity.
The two-dimensional (2D) Vortex Particle Method is used for the discretization of the Navier-Stokes equations including a Pseudo-three dimensional (Pseudo-3D) extension within an existing CFD solver. The Pseudo-3D Vortex Method considers the 3D structural behavior for aeroelastic analyses by positioning 2D fluid strips along a line-like structure. A novel turbulent Pseudo-3D Vortex Method is developed by combining the laminar Pseudo-3D VPM and a previously developed 2D method for the generation of free-stream turbulence. Using analytical derivations, it is shown that the fluid velocity correlation is maintained between the CFD strips.
Furthermore, a new method is presented for the determination of the complex aerodynamic admittance under deterministic sinusoidal gusts using the Vortex Particle Method. The sinusoidal gusts are simulated by modeling the wakes of flapping airfoils in the CFD domain with inflow vortex particles. Positioning a section downstream yields sinusoidal forces that are used for determining all six components of the complex aerodynamic admittance. A closed-form analytical relation is derived, based on an existing analytical model. With this relation, the inflow particles’ strength can be related with the target gust amplitudes a priori.
The developed methodologies are combined in a synergistic framework, which is applied to both fundamental examples and practical case studies. Where possible, the results are verified and validated. The outcome of this work is intended to shed some light on the complex wind–bridge interaction and suggest appropriate modeling strategies for an enhanced design.
T3  - Schriftenreihe des DFG Graduiertenkollegs 1462 Modellqualitäten // Graduiertenkolleg Modellqualitäten <Weimar> - 21 
KW  - Brücke
KW  - Bridge
KW  - Computational Fluid Dynamics
KW  - Aerodynamics
KW  - Aeroelasticity
KW  - Category Theory
KW  - Aerodynamik
KW  - Aeroelastizität
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200316-41099
UR  - https://asw-verlage.de/katalog/?id=2255
SN  - 978-3-95773-284-2
PB  - Bauhaus-Universitätsverlag
CY  - Weimar
ER  - 
TY  - THES
A1  - Hossein Nezhad Shirazi, Ali
T1  - Multi-Scale Modeling of Lithium ion Batteries: a thermal management approach and molecular dynamic studies
N2  - Rechargeable lithium ion batteries (LIBs) play a very significant role in power supply and storage. In recent decades, LIBs have caught tremendous attention in mobile communication, portable electronics, and electric vehicles. Furthermore, global warming has become a worldwide issue due to the ongoing production of greenhouse gases. It motivates solutions such as renewable sources of energy. Solar and wind energies are the most important ones in renewable energy sources. By technology progress, they will definitely require batteries to store the produced power to make a balance between power generation and consumption. Nowadays,rechargeable batteries such as LIBs are considered as one of the best solutions. They provide high specific energy and high rate performance while their rate of self-discharge is low.
Performance of LIBs can be improved through the modification of battery characteristics. The size of solid particles in electrodes can impact the specific energy and the cyclability of batteries. It can improve the amount of lithium content in the electrode which is a vital parameter in capacity and capability of a battery. There exist diferent sources of heat generation in LIBs such as heat produced during electrochemical reactions, internal resistance in battery. The size of electrode's electroactive particles can directly affect the produced heat in battery. It will be shown that the smaller size of solid particle enhance the thermal characteristics of LIBs.
Thermal issues such as overheating, temperature maldistribution in the battery, and thermal runaway have confined applications of LIBs. Such thermal challenges reduce the Life cycle of LIBs. As well, they may lead to dangerous conditions such as fire or even explosion in batteries. However, recent advances in fabrication of advanced materials such as graphene and carbon nanotubes with extraordinary thermal conductivity and electrical properties propose new opportunities to enhance their performance. Since experimental works are expensive, our objective is to use computational methods to investigate the thermal issues in LIBS. Dissipation of the heat produced in the battery can improve the cyclability and specific capacity of LIBs. In real applications, packs of LIB consist several battery cells that are used as the power source. Therefore, it is worth to investigate thermal characteristic of battery packs under their cycles of charging/discharging operations at different applied current rates. To remove the produced heat in batteries, they can be surrounded by materials with high thermal conductivity. Parafin wax absorbs high energy since it has a high latent heat. Absorption high amounts of energy occurs at constant temperature without phase change. As well, thermal conductivity of parafin can be magnified with nano-materials such as graphene, CNT, and fullerene to form a nano-composite medium. Improving the thermal conductivity of LIBs increase the heat dissipation from batteries which is a vital issue in systems of battery thermal management. The application of two-dimensional (2D) materials has been on the rise  since exfoliation the graphene from bulk graphite. 2D materials are single-layered in an order of nanosizes which show superior thermal, mechanical, and optoelectronic properties. They are potential candidates for energy storage and supply, particularly in lithium ion batteries as electrode material. The high thermal conductivity of graphene and graphene-like materials can play a significant role in thermal management of batteries. However, defects always exist in nano-materials since there is no ideal fabrication process. One of the most important defects in materials are nano-crack which can dramatically weaken the mechanical properties of the materials. Newly synthesized crystalline carbon nitride with the stoichiometry of C3N have attracted many attentions due to its extraordinary mechanical and thermal properties. The other nano-material is phagraphene which shows anisotropic mechanical characteristics which is ideal in production of nanocomposite.
It shows ductile fracture behavior when subjected under uniaxial loadings. It is worth to investigate their thermo-mechanical properties in its pristine and defective states. We hope that the findings of our work not only be useful for both experimental and theoretical researches but also help to design advanced electrodes for LIBs.
KW  - Akkumulator
KW  - Battery
KW  - Batterie
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200214-40986
ER  - 
TY  - JOUR
A1  - Harirchian, Ehsan
A1  - Lahmer, Tom
A1  - Rasulzade, Shahla
T1  - Earthquake Hazard Safety Assessment of Existing Buildings Using Optimized Multi-Layer Perceptron Neural Network
JF  - Energies
N2  - The latest earthquakes have proven that several existing buildings, particularly in developing countries, are not secured from damages of earthquake. A variety of statistical and machine-learning approaches have been proposed to identify vulnerable buildings for the prioritization of retrofitting. The present work aims to investigate earthquake susceptibility through the combination of six building performance variables that can be used to obtain an optimal prediction of the damage state of reinforced concrete buildings using artificial neural network (ANN). In this regard, a multi-layer perceptron network is trained and optimized using a database of 484 damaged buildings from the Düzce earthquake in Turkey. The results demonstrate the feasibility and effectiveness of the selected ANN approach to classify concrete structural damage that can be used as a preliminary assessment technique to identify vulnerable buildings in disaster risk-management programs.
KW  - Erdbeben
KW  - Maschinelles Lernen
KW  - earthquake damage
KW  - seismic vulnerability
KW  - artificial neural network
KW  - OA-Publikationsfonds2020
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200504-41575
UR  - https://www.mdpi.com/1996-1073/13/8/2060/htm
VL  - 2020
IS  - Volume 13, Issue 8, 2060
PB  - MDPI
CY  - Basel
ER  - 
TY  - JOUR
A1  - Harirchian, Ehsan
A1  - Lahmer, Tom
A1  - Buddhiraju, Sreekanth
A1  - Mohammad, Kifaytullah
A1  - Mosavi, Amir
T1  - Earthquake Safety Assessment of Buildings through Rapid Visual Screening
JF  - Buildings
N2  - Earthquake is among the most devastating natural disasters causing severe economical, environmental, and social destruction. Earthquake safety assessment and building hazard monitoring can highly contribute to urban sustainability through identification and insight into optimum materials and structures. While the vulnerability of structures mainly depends on the structural resistance, the safety assessment of buildings can be highly challenging. In this paper, we consider the Rapid Visual Screening (RVS) method, which is a qualitative procedure for estimating structural scores for buildings suitable for medium- to high-seismic cases. This paper presents an overview of the common RVS methods, i.e., FEMA P-154, IITK-GGSDMA, and EMPI. To examine the accuracy and validation, a practical comparison is performed between their assessment and observed damage of reinforced concrete buildings from a street survey in the Bingöl region, Turkey, after the 1 May 2003 earthquake. The results demonstrate that the application of RVS methods for preliminary damage estimation is a vital tool. Furthermore, the comparative analysis showed that FEMA P-154 creates an assessment that overestimates damage states and is not economically viable, while EMPI and IITK-GGSDMA provide more accurate and practical estimation, respectively.
KW  - Maschinelles Lernen
KW  - Machine learning
KW  - Erdbeben
KW  - buildings
KW  - earthquake safety assessment
KW  - earthquake
KW  - extreme events
KW  - seismic assessment
KW  - natural hazard
KW  - mitigation
KW  - rapid visual screening
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200331-41153
UR  - https://www.mdpi.com/2075-5309/10/3/51
VL  - 2020
IS  - Volume 10, Issue 3
PB  - MDPI
ER  - 
TY  - JOUR
A1  - Harirchian, Ehsan
A1  - Lahmer, Tom
T1  - Improved Rapid Visual Earthquake Hazard Safety Evaluation of Existing Buildings Using a Type-2 Fuzzy Logic Model
JF  - Applied Sciences
N2  - Rapid Visual Screening (RVS) is a procedure that estimates structural scores for buildings and prioritizes their retrofit and upgrade requirements. Despite the speed and simplicity of RVS, many of the collected parameters are non-commensurable and include subjectivity due to visual observations. This might cause uncertainties in the evaluation, which emphasizes the use of a fuzzy-based method. This study aims to propose a novel RVS methodology based on the interval type-2 fuzzy logic system (IT2FLS) to set the priority of vulnerable building to undergo detailed assessment while covering uncertainties and minimizing their effects during evaluation. The proposed method estimates the vulnerability of a building, in terms of Damage Index, considering the number of stories, age of building, plan irregularity, vertical irregularity, building quality, and peak ground velocity, as inputs with a single output variable. Applicability of the proposed method has been investigated using a post-earthquake damage database of reinforced concrete buildings from the Bingöl and Düzce earthquakes in Turkey.
KW  - Fuzzy-Logik
KW  - Erdbeben
KW  - Fuzzy Logic
KW  - Rapid Visual Screening
KW  - Vulnerability assessment
KW  - OA-Publikationsfonds2020
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:gbv:wim2-20200331-41161
UR  - https://www.mdpi.com/2076-3417/10/7/2375
VL  - 2020
IS  - Volume 10, Issue 3, 2375
PB  - MDPI
CY  - Basel
ER  -