Global ETD Search

81	Understanding the Responses of a Metal and a CMCTurbine Blade during a Controlled Rub Event using a Segmented Shroud Langenbrunner, Nisrene A. 08 August 2013 (has links) No description available. Aerospace Engineering Materials Science "tip rub" CMC OSU "Gas Turbine Lab: GTL "turbine blades" "turbine blade tip rub"
82	Optimization and Fabrication of Heat Exchangers for High-Density Power Control Unit Applications Parida, Pritish Ranjan 09 September 2010 (has links) The demand for more power and performance from electronic equipment has constantly been growing resulting in an increased amount of heat dissipation from these devices. Thermal management of high-density power control units for hybrid electric vehicles is one such application. Over the last few years, the performance of this power control unit has been improved and size has been reduced to attain higher efficiency and performance causing the heat dissipation as well as heat density to increase significantly. However, the overall cooling system has remained unchanged and only the heat exchanger corresponding to the power control unit (PCU) has been improved. This has allowed the manufacturing costs to go down. Efforts are constantly being made to reduce the PCU size even further and also to reduce manufacturing costs. As a consequence, heat density will go up (~ 200 – 250 W/cm2) and thus, a better high performance cooler/heat exchanger is required that can operate under the existing cooling system design and at the same time, maintain active devices temperature within optimum range (<120 – 125 °C) for higher reliability. The aim of this dissertation was to study the various cooling options based on jet impingement, mini-channel, ribbed mini-channel, phase change material and double sided cooling configurations for application in hybrid electric vehicle and other similar consumer products and perform parametric and optimization study on selected designs. Detailed experimental and computational analysis was performed on different cooling designs to evaluate overall performance. Severe constraints such as choice of coolant, coolant flow-rate, pressure drop, minimum geometrical size and operating temperature were required for the overall design. High performance jet impingement based cooler design with incorporated fin-like structures induced swirl and provided enhanced local heat transfer compared to traditional cooling designs. However, the cooling scheme could manage only 97.4% of the target effectiveness. Tapered/nozzle-shaped jets based designs showed promising results (~40% reduction in overall pressure drop) but were not sufficient to meet the overall operating temperature requirement. Various schemes of mini-channel arrangement, which were based on utilizing conduction and convection heat transfer in a conjugate mode, demonstrated improved performance over that of impingement cooling schemes. Impingement and mini-channel based designs were combined to show high heat transfer rates but at the expense of higher pressure drops (~5 times). As an alternate, mini-channel based coolers with ~1.5 mm size channels having trip strips or ribs were studied to accommodate the design constraints and to enhance local as well as overall heat transfer rates and achieve the target operating temperature. A step by step approach to the development of the heat exchanger is provided with an emphasis on system level design. The computational based optimization methodology is confirmed by a fabricated test bed to evaluate overall performance and compare the predicted results with actual performance. Additionally, one of the impingement based configuration (Swirl-Impingement-Fin) developed during the course of this work was applied to the internal cooling of a turbine blade trailing edge and was shown to enhance the thermal performance by at least a factor of 2 in comparison to the existing pin-fin technology for the conditions studied in this work. / Ph. D. Electronic cooling Swirl-impingement-Fin Jet Impingement Ribbed Mini-channel Automotive Application Power Converters for HEV Thermal Management Turbine Blade Internal Cooling
83	Unshrouded turbine blade tip heat transfer and film cooling Tang, Brian M. T. January 2011 (has links) This thesis presents a joint computational and experimental investigation into the heat transfer to unshrouded turbine blade tips suitable for use in high bypass ratio, large civil aviation turbofan engines. Both the heat transfer to the blade tip and the over-tip leakage flow over the blade tip are characterised, as each has a profound influence on overall engine efficiency. The study is divided into two sections; in the first, computational simulations of a very large scale, low speed linear cascade with a flat blade tip were conducted. These simulations were validated against experimental data collected by Palafox (2006). A thorough assessment of turbulence models and minimum meshing requirements was performed. The standard k-ω and standard k-ϵ turbulence models significantly overpredicted the turbulence levels within the tip gap. The other models were very similar in performance; the SST k-ω and realisable k-ϵ models were found to be the most suitable for the flow environment. The second section documents the development and testing of a novel hybrid blade tip design, the squealet tip, which seeks to combine the known benefits of winglet and double squealer tips. The development of the external geometry was performed primarily through engine-representative CFD simulations at a range of tip gaps from 0.45% to 1.34% blade chord. The squealet tip was found to have a similar aerodynamic sensitivity to tip clearance as a baseline double squealer tip, with a tip gap efficiency exchange rate of 2.03, although this was 18% greater than the alternative winglet tip. The squealet tip displayed higher predicted stage efficiency than the winglet tip over the majority of the range of tip clearances investigated, however. The overall heat load was reduced by 14% compared with the winglet tip but increased by 28% over the double squealer tip, primarily due to the change in wetted surface area. The predicted local heat transfer coefficients were similar across all geometries. A realistic internal cooling plenum and an array of blade tip cooling holes were subsequently added to the squealet tip geometry and the cooling configuration refined by the selective sealing of cooling holes. Film cooling performance was largely assessed by the predicted adiabatic wall temperature distributions. A viable cooling scheme which reduced the cooling air requirement by 38% was achieved, compared to the initial case which had all cooling holes open. This was associated with just a 7% increase in blade tip heat flux and no penalty in peak temperature on the blade tip. Film cooling air ejected from holes on the blade suction side was swept away from the blade tip region, making the squealet rim at the crown of the blade particularly challenging to cool. It was demonstrated that this region could be cooled effectively by ballistic cooling from holes located on the blade tip cavity floor, although this was expensive in terms of the mass flow rate of cooling air required. The computational results were reinforced with experimental data collected in a transonic linear cascade. Downstream aerodynamic loss measurements were taken for a linearised version of the squealet tip design without cooling at nominal tip gaps of 0.45%, 0.89% and 1.34% blade chord, which was compared to similar data taken by O’Dowd (2010) for flat and winglet tips. The squealet was seen to have a similar aerodynamic loss to the flat tip and a reduced loss compared with the winglet tip. Full surface heat transfer measurements were taken for the uncooled squealet tip, at tip gaps of 0.89% and 1.34% blade chord, and for two configurations of the cooled squealet tip, at a tip clearance of 0.89% blade chord. The qualitative similarity between the measured heat transfer distributions and the those predicted by the engine-representative CFD simulations was good. A CFD simulation of the uncooled linear cascade environment at the 1.34% blade chord tip clearance was performed using a single blade with translationally periodic boundary conditions. The predicted size of the over-tip leakage vortex was smaller than had been measured, resulting in a large underprediction in the magnitude of the downstream area-averaged aerodynamic loss. The magnitudes of the predicted blade tip Nusselt number distribution were similar to those produced by the engine-representative CFD simulations and lower than that measured experimentally. Differences in the shape of the Nusselt number distribution were observed in the vicinity of regions of separated and reattaching flow, but other salient features were replicated in the computational data. The squealet tip has been shown to be a promising, viable unshrouded blade tip design with an aerodynamic performance similar to the double squealer tip but is more amenable to film cooling. It is significantly lighter than a winglet tip and incurs a reduced thermal load. The squealet tip design can now be developed into a blade tip geometry for use in real engines to provide an alternative to shrouded turbine blades and current unshrouded blade tip designs. A commercial CFD solver, Fluent 6.3, was shown to capture blade tip heat transfer and over-tip leakage flow sufficiently well to be a useful design guide. However, the sensitivity of the flow structure (and hence, heat transfer) in the forward part of the blade tip cavity suggests that physical testing cannot be eliminated from the design process entirely. 629.132
84	Construction d'une chaîne d'outils numériques pour la conception aérodynamique de pales d'éoliennes / Construction of a numerical tool chain for aerodynamical conception of wind turbine blades Jin, Xin 19 September 2014 (has links) Ce mémoire présente les travaux réalisés en aérodynamique afin de pouvoir disposer d’une chaîne de conception complète nécessaire au traitement des différentes problématiques sur les pales éoliennes, qui ne peuvent être pris en compte à l’aide d’une méthode unique. Afin de pouvoir faire de l’optimisation de pales en fonction de différents critères, un outil numérique simplifié (VALDAG) a été développé. Le module de simulation utilise la méthode du Disque Actif Généralisé, qui s’appuie sur la résolution des équations Navier-Stokes, complété par des corrections empiriques. Il respecte un compromis entre la précision et le coût de calcul. Cet outil pour lequel une interface web a été développée pour le rendre adapté à des travaux d’ingénierie est susceptible de se calibrer automatiquement sur une nouvelle géométrie de pale grâce à la méthode Nelder-Mead Simplex. On peut ensuite réaliser une optimisation de la performance de la pale en modifiant cette géométrie, et générer les fichiers 3D qui serviront d’entrée à la simulation 3D et de visualisation des optimisations de forme. Ces designs optimisés sont ensuite validés par des simulations DNS à l’aide de l’outil NaSCar 3D développé à l’INRIA. Cet outil résout des équations Navier-Stokes sur un maillage cartésien 3D et prend en compte des obstacles immergés via la fonction Level-Set et la pénalisation. Après des adaptations sur le traitement de la géométrie de pales, un compromis de configuration CFD est trouvé pour simuler un rotor éolien. En conclusion, ce paquet d’outils VALDAG est peu coûteux, facile à utiliser et efficace. En associant VALDAG aux simulations 3D, une chaîne de conception est complétée. / This Ph.D. thesis presents some research work on aerodynamics of wind turbine blades, in order to dispose a conception chain necessary for different problems, which cannot be treated by one unique method. A simplified numerical toolkit (VALDAG) has been developed to optimize the performance of blades in different creteria. The simulation module use the Generalized Actuator Disc model, which relies on the solution of Navier-Stokes equations and completed with empiric corrections. This tool respects a reasonable compromise between model complexity and computational reliability. An automatic calibration mechanism was implemented using the Nelder-Mead Simplex algorithm. A web users interface (WUI) is also available to adapt VALDAG for industrial engineers. Optimization is then carried on by modifying the blades’ geometry parameters and the designs optimized is stocked in files which can be used for 3D simulation and/or visualization. The blade designed with VALDAG are then simulated by a 3D numerical tool to validate previous predictions. This 3D tool called NaSCar 3D is developed in INRIA and resolve Navier-Stokes equations on to a cartesian mesh, in which the immersed obstacles are considered with the Level-Set function and the penalization method. After some necessary adaptation for the treatment of blades’ geometry, a compromise on CFD configuration is found to simulate a wind turbine rotor. To conclude, this design toolkit VALDAG is low time-costly, user-friendly and efficient. Associated with 3D simulations, a conception chain has been established. Pale éolienne Conception aérodynamique Disc Actif CFD Navier-Stokes Nelder- Mead Simplex WUI Level-Set Pénalisation Calcul parallèle Wind turbine blade Aerodynamical conception Actuator Disc CFD Navier-Stokes Nelder-Mead Simplex WUI Level-Set Penalization Parallel computing
85	Modeling Behaviour of Damaged Turbine Blades for Engine Health Diagnostics and Prognostics Van Dyke, Jason 12 October 2011 (has links) The reliability of modern gas turbine engines is largely due to careful damage tolerant design a method of structural design based on the assumption that flaws (cracks) exist in any structure and will continue to grow with usage. With proper monitoring, largely in the form of periodic inspections at conservative intervals reliability and safety is maintained. These methods while reliable can lead to the early retirement of some components and unforeseen failure if design assumptions fail to reflect reality. With improvements to sensor and computing technology there is a growing interest in a system that could continuously monitor the health of structural aircraft as well as forecast future damage accumulation in real-time. Through the use of two-dimensional and three-dimensional numerical modeling the initial goals and findings for this continued work include: (a) establishing measurable parameters directly linked to the health of the blade and (b) the feasibility of detecting accumulated damage to the structural material and thermal barrier coating as well as the onset of damage causing structural failure. Numerical method TBC thermal barrier coating turbine blade damage turbine blades damage FEA diagnostic system prognostic system structural health monitoring damage modeling damage indicators finite element method ABAQUS vibration deflection elongation
86	Modeling Behaviour of Damaged Turbine Blades for Engine Health Diagnostics and Prognostics Van Dyke, Jason 12 October 2011 (has links) The reliability of modern gas turbine engines is largely due to careful damage tolerant design a method of structural design based on the assumption that flaws (cracks) exist in any structure and will continue to grow with usage. With proper monitoring, largely in the form of periodic inspections at conservative intervals reliability and safety is maintained. These methods while reliable can lead to the early retirement of some components and unforeseen failure if design assumptions fail to reflect reality. With improvements to sensor and computing technology there is a growing interest in a system that could continuously monitor the health of structural aircraft as well as forecast future damage accumulation in real-time. Through the use of two-dimensional and three-dimensional numerical modeling the initial goals and findings for this continued work include: (a) establishing measurable parameters directly linked to the health of the blade and (b) the feasibility of detecting accumulated damage to the structural material and thermal barrier coating as well as the onset of damage causing structural failure. Numerical method TBC thermal barrier coating turbine blade damage turbine blades damage FEA diagnostic system prognostic system structural health monitoring damage modeling damage indicators finite element method ABAQUS vibration deflection elongation
87	A framework for conducting mechanistic based reliability assessments of components operating in complex systems Wallace, Jon Michael 02 December 2003 (has links) Reliability prediction of components operating in complex systems has historically been conducted in a statistically isolated manner. Current physics-based, i.e. mechanistic, component reliability approaches focus more on component-specific attributes and mathematical algorithms and not enough on the influence of the system. The result is that significant error can be introduced into the component reliability assessment process. The objective of this study is the development of a framework that infuses the influence of the system into the process of conducting mechanistic-based component reliability assessments. The formulated framework consists of six primary steps. The first three steps, identification, decomposition, and synthesis, are qualitative in nature and employ system reliability and safety engineering principles for an appropriate starting point for the component reliability assessment. The most unique steps of the framework are the steps used to quantify the system-driven local parameter space and a subsequent step using this information to guide the reduction of the component parameter space. The local statistical space quantification step is accomplished using two newly developed multivariate probability tools: Multi-Response First Order Second Moment and Taylor-Based Inverse Transformation. Where existing joint probability models require preliminary statistical information of the responses, these models combine statistical information of the input parameters with an efficient sampling of the response analyses to produce the multi-response joint probability distribution. Parameter space reduction is accomplished using Approximate Canonical Correlation Analysis (ACCA) employed as a multi-response screening technique. The novelty of this approach is that each individual local parameter and even subsets of parameters representing entire contributing analyses can now be rank ordered with respect to their contribution to not just one response, but the entire vector of component responses simultaneously. The final step of the framework is the actual probabilistic assessment of the component. Variations of this final step are given to allow for the utilization of existing probabilistic methods such as response surface Monte Carlo and Fast Probability Integration. The framework developed in this study is implemented to conduct the finite-element based reliability prediction of a gas turbine airfoil involving several failure responses. The framework, as implemented resulted in a considerable improvement to the accuracy of the part reliability assessment and an increased statistical understanding of the component failure behavior. Non-deterministic methods Canonical correlation Turbine blade failure Component reliability Joint probability Multivariate probability Turbines Blades Reliability Canonical correlation (Statistics) System analysis Statistical methods Airplanes Reliability
88	Modeling Behaviour of Damaged Turbine Blades for Engine Health Diagnostics and Prognostics Van Dyke, Jason 12 October 2011 (has links) The reliability of modern gas turbine engines is largely due to careful damage tolerant design a method of structural design based on the assumption that flaws (cracks) exist in any structure and will continue to grow with usage. With proper monitoring, largely in the form of periodic inspections at conservative intervals reliability and safety is maintained. These methods while reliable can lead to the early retirement of some components and unforeseen failure if design assumptions fail to reflect reality. With improvements to sensor and computing technology there is a growing interest in a system that could continuously monitor the health of structural aircraft as well as forecast future damage accumulation in real-time. Through the use of two-dimensional and three-dimensional numerical modeling the initial goals and findings for this continued work include: (a) establishing measurable parameters directly linked to the health of the blade and (b) the feasibility of detecting accumulated damage to the structural material and thermal barrier coating as well as the onset of damage causing structural failure. Numerical method TBC thermal barrier coating turbine blade damage turbine blades damage FEA diagnostic system prognostic system structural health monitoring damage modeling damage indicators finite element method ABAQUS vibration deflection elongation
89	Aero-thermal performance and enhanced internal cooling of unshrouded turbine blade tips Virdi, Amandeep Singh January 2015 (has links) The tips of unshrouded, high-pressure turbine blades are prone to significantly high heat loads. The gap between the tip and over-tip casing is the root cause of undesirable over-tip leakage flow that is directly responsible for high thermal material degradation and is a major source of aerodynamic loss within a turbine. Both must be minimised for the safe working and improved performance of future gas-turbines. A joint experimental and numerical study is presented to understand and characterise the heat transfer and aerodynamics of unshrouded blade tips. The investigation is undertaken with the use of a squealer or cavity tip design, known for offering the best overall compromise between the tip aerodynamics, heat transfer and mechanical stress. Since there is a lack of understanding of these tips at engine-realistic conditions, the present study comprises of a detailed analysis using a high-speed linear cascade and computational simulations. The aero-thermal performance is studied to provide a better insight into the behaviour of squealer tips, the effects of casing movement and tip cooling. The linear cascade environment has proved beneficial for its offering of spatially-resolved data maps and its ability to validate computational results. Due to the unknown tip gap height within an entire engine cycle, the effects of gap height are assessed. The squealer's aero-thermal performance has been shown to be linked with the gap height, and qualitative different trends in heat transfer are established between low-speed and high-speed tip flow regimes. To the author's knowledge, the present work is the first of its kind, providing comprehensive aero-thermal experimental research and a dataset for a squealer tip at engine-representative transonic conditions. It is also unique in terms of conducting direct and systematic validations of a major industrial computational fluid dynamics method for aero-thermal performance prediction of squealer tips at enginerepresentative transonic conditions. Finally, after recognising the highest heat loads are found on the squealer rims, a novel shaped squealer tip has been investigated to help improve the thermal performance of the squealer with a goal to improve its durability. It has been discovered that a seven percent reduction in tip temperature can be achieved through incorporating a shaped squealer and maximising the internal cooling performance.
90	Détection et caractérisation de fissures dans des aubes de turbine monocristallines pour l’évaluation de leurs durées de vie résiduelles / Detection and characterization of cracks in monocrystalline turbine blades for the evaluation of the durations of residual life Maffren, Thierry 05 April 2013 (has links) Les aubes TuHP équipant le M88 subissent des contraintes thermomécaniques extrêmes qui provoquent l’amorçage et la propagation de fissures. Ces fissures peuvent évoluer rapidement et devenir critiques pour la sécurité. Actuellement, ces aubes sont inspectées in-situ au moyen d’un endoscope ou d’un vidéoscope dans le domaine du visible. Cependant, ce mode d’inspection par voie visuelle laisse souvent planer un doute sur la présence ou non d’une fissure ou sur sa criticité. Le démontage du module pour une inspection approfondie au microscope est alors nécessaire,augmentant le coût et le délai de la maintenance.L’objectif de la thèse est double. Il s’agit d’une part de valider un nouveau moyen de détection, sans démontage, de la fissuration des aubes HP en complément de l’inspection visuelle classique in-situ, et d’autre part d’utiliser les données expérimentales pour simuler la propagation d’une fissure et évaluer le caractère prédictif du modèle utilisé (direction et vitesse de propagation). La solution proposée pour réduire, voire supprimer le démontage des aubes, consiste à détecter les fissures par thermographie active flying spot dans le très proche infrarouge, de 1 à 2 microns (bande SWIR) au travers d’un endoscope classique. Le premier volet de la thèse a consisté à mettre au point le dispositif flying spot dans une configuration représentative d’un endoscope, puis à valider ce procédé d’inspection par des essais sur des aubes TuHP en retour d’expérience.Le deuxième volet de la thèse est davantage tourné vers la simulation. Le travail a tout d’abord consisté à intégrer un modèle de propagation de fissures en régime de fatigue prenant en compte les effets du temps et de l’environnement, dans le code de calcul par éléments finis ZeBuLon. Ce modèle a ensuite été utilisé pour simuler la propagation de fissures dans des aubes TuHP soumises à des cycles de chargement et de température complexes et représentatifs d’une mission réelle. La dernière partie du travail a consisté à comparer les résultats des simulations numériques avec les observations réalisées sur des aubes TuHP en retour d’expérience, afin d’évaluer le caractère prédictif du modèle de propagation pour cette application (direction et vitesse). / High pressure turbine blades undergo heavy thermomechanical constraints which drive initiation and propagation of cracks. These cracks may propagate rapidly and become critical for safety. The inspection of blades is currently conducted with endoscopes or videoscopes in the visible range. However, this kind of control is not sufficient to distinguish a crack from a surface defect, and it can be difficult to assess the criticality of a crack. In these cases, the dismantling of the engine for an accurate inspection with a microscope is necessary but this operation is time consuming and costly.This study has two aims. The first aim consists in validating a new inspection system complementary to the observations in the visible range. The second aim consists in using the experimental results to simulate the propagation of a crack and evaluate the ability of the model to predict the trajectory of a crack in a blade.The proposed solution to improve the detection of cracks in situ was to use the flying spot active thermography process in the SWIR range (1-2μm – short wavelength infrared) through a classical endoscope. The first aim of the experimental work was to develop the flying spot process to work on an industrial endoscope, and to validate it with tests on a series of cracked blades. The second part of this study is focused on the numerical simulation of the cracks. First, this work consisted in integrating a fatigue crack propagation model which takes into account the effects of creep and oxidation, in the finite element software ZeBuLoN. Then, this model was used to simulate the propagation of a crack in blades undergoing a complex load and thermal cycle representative of a real aircraft mission. The last part of this work consisted in comparing the numerical results with the experimental observations on cracked blades, to check the ability of themodel to predict the direction and the velocity of a crack in a blade. Aube de turbine Superalliage Thermographie active SWIR Méthode Flying Spot Fatigue Fluage Oxydation Propagation de fissures Turbine blade Superalloy Active SWIR thermography Flying spot process Fatigue Creep Oxidation Crack propagation 621.366

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