Global ETD Search

271	Design Automation Systems for Production Preparation : Applied on the Rotary Draw Bending Process Johansson, Joel January 2008 (has links) Intensive competition on the global market puts great pressure on manufacturing companies to develop and produce products that meet requirements from customers and investors. One key factor in meeting these requirements is the efficiency of the product development and the production preparation process. Design automation is a powerful tool to increase efficiency in these two processes. The benefits of automating the production preparation process are shortened led-time, improved product performance, and ultimately decreased cost. Further, automation is beneficial as it increases the ability to adapt products to new product specifications with production preparations done in few or in a single step. During the automation process, knowledge about the production preparation process is collected and stored in central systems, thus allowing full control over the design of production equipments. Three main topics are addressed in this thesis: the flexibility of design automation systems, knowledge bases containing conflicting rules, and the automation of the finite element analysis process. These three topics are discussed in connection with the production preparation process of rotary draw bending. One conclusion drawn from the research is that it is possible to apply the concept of design automation to the production preparation process at different levels of automation depending on characteristics of the implemented knowledge. In order to make design automation systems as flexible as possible, the concept of object orientation should be adapted when building the knowledge base and when building the products geometrical representations. It is possible to automate the process of setting up, running, and interpreting finite element analyses to a great extent and making the automated finite element analysis process a part of the global design automation system. Design automation Rotary draw bending Knowledge Based Engineering (KBE) and Finite Element Analysis (FEA) Other technology Övriga teknikvetenskaper
272	Design and analysis of the Hobby-Eberly Telescope Dark Energy Experiment bridge Worthington, Michael Scott 26 October 2010 (has links) A large structural weldment has been designed to serve as the new star tracker bridge for the Dark Energy Experiment upgrade to the Hobby-Eberly Telescope at McDonald Observatory. The modeling approach, analysis techniques and design details will be of interest to designers of large structures where stiffness is the primary design driver. The design includes detailed structural analysis using finite element models to maximize natural frequency response and limit deflections and light obscuration. Considerable fabrication challenges are overcome to allow integration of precision hardware required for positioning the corrector optics to a precision of less than 5 microns along the 4-meter travel range. This thesis provides detailed descriptions of the bridge geometry, analysis results and challenging fabrication issues. / text HET HETDEX Natural frequency Frequency response Large welded structure Finite element analysis FEA Beam theory Bridge design
273	Ausarbeitung eines Finite-Elemente-Simulationsmodells für die Belastungen beim Kuttern und Optimierung diverser Kuttermesser mit bionischen Strukturen / Formulation of a finite-element-simulation model for the loads during the cutting process in a bowl cutter and optimization of various cutter blades with bionic structures Morgenstern, Martin 08 May 2014 (has links) (PDF) In der fleischverarbeitenden Industrie gibt es eine Vielzahl von Schneidwerkzeugen. Kuttermesser stehen hierbei in der Prozesskette weit hinten und haben einen direkten Einfluss auf die Qualität des Endprodukts. Der Prozess des Kutterns ist bislang nicht komplett analytisch geklärt. Während des Vorgangs durchläuft das Schneidgut (i.A. das Fleisch bzw. das Brät) wechselnde Aggregatzustände von fester (leicht gefrorener) Form hin zum zähviskosen Zustand. Weiterhin ist es permanentem korrosiven Kontakt ausgesetzt. Die Komplexität macht eine analytische Herangehensweise äußerst aufwendig, sodass sich mittels der FEM durch numerisches Vorgehen und Lastannahmen aus Untersuchungen diesem Problem gewidmet wird. Dabei sind bislang nicht bekannte Potentiale zu erkennen. Hierbei wurden verschiedene Vernetzungsstrategien (p- und h-Methode) der FEM angewandt und verglichen. Es sind dabei Materialreduktionen bis knapp 30% ersichtlich. Kuttermesser FEM bionische Strukturen Industriemesser cutter blades FEA bionic structures topology optimization industrial blades ddc:629 Topologieoptimierung
274	Connecting casting simulation and FE software including local variation of physical properties. : Investigation on local material properties and microstructure in a grey iron cylinder head. Beckius, Fredrik, Gustafsson, Robin January 2016 (has links) No description available. Grey iron casting process simulation Finite element analysis (FEA) material testing modelling thermal conductivity
275	Quantification of uncertainty in the magnetic characteristic of steel and permanent magnets and their effect on the performance of permanent magnet synchronous machine Abhijit Sahu (5930828) 15 August 2019 (has links) <div>The numerical calculation of the electromagnetic fields within electric machines is sensitive to the magnetic characteristic of steel. However, the magnetic characteristic of steel is uncertain due to fluctuations in alloy composition, possible contamination, and other manufacturing process variations including punching. Previous attempts to quantify magnetic uncertainty due to punching are based on parametric analytical models of <i>B-H</i> curves, where the uncertainty is reflected by model parameters. In this work, we set forth a data-driven approach for quantifying the uncertainty due to punching in <i>B-H</i> curves. In addition to the magnetic characteristics of steel lamination, the remanent flux density (<i>B<sub>r</sub></i>) exhibited by the permanent magnets in a permanent magnet synchronous machine (PMSM) is also uncertain due to unpredictable variations in the manufacturing process. Previous studies consider the impact of uncertainties in <i>B-H</i> curves and <i>B<sub>r</sub></i> of the permanent magnets on the average torque, cogging torque, torque ripple and losses of a PMSM. However, studies pertaining to the impact of these uncertainties on the combined machine/drive system of a PMSM is scarce in the literature. Hence, the objective of this work is to study the effect of <i>B-H</i> and <i>B<sub>r</sub></i> uncertainties on the performance of a PMSM machine/drive system using a validated finite element simulator. </div><div>Our approach is as follows. First, we use principal component analysis to build a reduced-order stochastic model of <i>B-H</i> curves from a synthetic dataset containing <i>B-H</i> curves affected by punching. Second, we model the the uncertainty in <i>B<sub>r</sub></i> and other uncertainties in <i>B-H</i> characteristics e.g., due to unknown state of the material composition and unavailability of accurate data in deep saturation region. Third, to overcome the computational limitations of the finite element simulator, we replace it with surrogate models based on Gaussian process regression. Fourth, we perform propagation studies to assess the effect of <i>B-H</i> and <i>B<sub>r</sub></i> uncertainties on the average torque, torque ripple and the PMSM machine/drive system using the constructed surrogate models.</div> uncertainty quantification surrogate modeling Finite element analysis (FEA)
276	Damage Evolution and Frictional Heating in a PBX Microstructure Rohan K. Tibrewala (5930903) 16 August 2019 (has links) In this study, dynamic crack propagation in brittle materials has been studied using a regularized phase field approach.The phase field model used has been validated using specific experimental results of a dynamic in-plane fracture. The crack branching phenomena and existence of a limiting crack tip velocity has been validated using a mode I simulation set-up. A parametric study has also been performed so as to normalize the various numerical parameters that affect the velocity at the crack tip. Following the validation of the phase field model a stochastic analysis of a PBX microstructure has been performed. The microstructure has a high HMX volume fraction of 79\%. The energetic material is HMX and the binder used is Sylgard. Artificial defects are introduced in the system using phase field cracks. The analysis uses a finite element framework that accounts for various thermal-mechanical processes like deformation, heat generation, conduction, fracture and frictional heating at the crack surfaces. The effect on the temperature and damage field due to varying parameters like loading velocities and critical energy release rates is studied. Critical hotspot formation due to localized frictional heating is also studied. A concept of dirty binder is introduced to increase the grain volume fraction of the energetic in the composite. This amounts to a homogenized binder that accounts for the influence of the subsume particles that do not contribute to fracture but affect material properties of the binder. Mechanical Engineering Finite element analysis (FEA) phase field model Frictional heating Damage evolution Dynamic Simulations Energetic Materials
277	Metallurgical performance of hyper-joints in composite to metal joining Oluleke, Rotimi January 2015 (has links) The use of composites materials in aerospace applications can provide significant weight reduction. However, in airframe designs composites are frequently required to be joined to metal components, which is a challenging issue owing to the very different thermo-physical properties of the two classes of materials. In many cases adhesive bonding has insufficient durability and the requirement for large lapped areas and mechanical fasteners adds considerable weight, reducing the mass savings associated with the introduction of composite structures. A promising approach for improving joint performance is to surface engineer locking features on to the metal part which then integrate with the composite laminate to increase shear load transfer, both via better adhesion and also by mechanical "fit" throughout the thickness of the composite. Such hybrid joints are known as "hyper-joints". For this work, three main techniques are currently being investigated for generating the required surface features. These are; (i) sculpting surfaces using power beam local surface melting techniques (Surfi-Sculpt), (ii) building surface protrusions by additive layer manufacturing (AM) and (iii) arc percussive welding process. The present work aims to provide understanding of the critical metallurgical interactions during the growth/production of the surface engineered features and how some build parameters might affect the eventual joint integrity, durability and performance. To enable the use of the arc-percussive welding process as a viable manufacturing route for these hyper-joints, optimisation of its process parameters were studied in the course of this work. Further work on the effect of process parameters such as voltage, travel velocity, gap setting and time delay on the quality of the weld were also investigated in this study. Of the above mentioned process parameters, the voltage across the capacitor and travel velocity of the actuator have been found to have far greater effect on the weld quality. More importantly, the travel velocity of the actuator was also found to help determine the shape, size and distribution of the melt pool. Based on the systematic study and analysis of all of the process parameters involved, an optimised process window has now been proposed. Microstructural characterisations of hyper-joint samples made via the three manufacturing routes were performed in the course of the work. The observed microstructures were related to the process history and the process parameters. Most importantly it was for found that in common with most welding and AM processes, columnar prior β grains developed in all the samples studied by epitaxial-regrowth either along the build or weld directions. It was also found that the fusion zone of the similar titanium alloy (Ti-6Al-4V to Ti-6Al-4V) arc-percussive welded samples were characterised by extremely fine acicular alpha' martensitic platelets formed as a result of the high cooling rate associated with the process. On the other hand, the fusion zone of the dissimilar titanium alloy (Ti-6Al-4V to β21S) arc-percussive welded samples was characterised by an extremely fine cellular structure prompted by constitutional supercooling. Finally the microstructures observed in the Surfi-Sculpt samples were found to be dependant on the swipe pattern and duration. In order to assess the performance of hyper-joints made via two of the candidate manufacturing routes, tensile testing of standard and modified tensile samples was performed. The result indicated that on average the strength of these hyper-joint pins were within nominal values expected of the Ti-6Al-4V and β21S alloys. It was also found that with optimum weld conditions, failure occurred only along the gauge length for the arc-percussive welded samples whilst the strength of the AM samples degrade as the gauge diameter decreases as the effect of surface defects became prominent. Results are also reported on a novel method for testing the shear strength and properties of individual hyper-pins manufactured via this process. Interpretation of the shear test was assisted by finite element modelling. The shear test results indicated that the arc-percussive welded samples outperformed the SLM-AM samples thereby giving credence to the process as a viable means for making the pins. 620
278	Reducing unbalanced magnetic pull in induction machines Chuan, Haw Wooi January 2018 (has links) Induction machines are the most widely used type of electrical machines because of their robustness, simplicity, and relatively low cost. However, the small airgap in the induction machine makes them more susceptible to Unbalanced Magnetic Pull (UMP). This is because the magnitude of the UMP is a function of the degree of eccentricity, which is the ratio between the length of misalignment and the mean airgap length. The bearing-related failure accounts for approximately 41% of the total failures of induction machines; the percentages of bearing-related failure would be higher for applications in a harsher environment. In this thesis, the UMP caused by rotor eccentricity is investigated, because a small degree of rotor eccentricity is unavoidable due to the manufacturing tolerance and 80% of the mechanical faults could cause rotor eccentricity in electrical machines. When the rotor is not at the centre of the stator, the eccentric rotor causes an uneven airgap around the rotor, in which the magnetic permeance with the higher harmonics content will be created. The magnetomotive force (MMF) produces additional pole-pair ±1 magnetic flux around the airgap. The interaction between each magnetic flux with its pole pair ±1 magnetic flux produces UMP. As only the magnetic flux that crosses the airgap causes UMP, the magnetic flux is categorised into magnetising flux and airgap leakage flux, because both types of flux possess different characteristics at a different rotor slip. As the airgap leakage flux is difficult to calculate analytically, an empirical method is proposed to estimate the UMP caused by the airgap leakage flux. Then, the UMP caused by the magnetising flux can also be estimated by using the empirical method. The parameters for the empirical method can be found by using either the FEA or the experimental results. The damping effect of the magnetising flux in a parallel connected rotor bar is discussed and a damping coefficient is introduced to explain this scenario. The damping coefficient can also be used to calculate the UMP in a steady state analysis. UMP comparisons between the cage rotor and wound rotor induction machines are made. The wound rotor has a much higher UMP because the pole-specific wound rotor could not damp the additional pole pair ±1 magnetic flux. Therefore, a damper winding at the stator slot is also proposed in order to damp the UMP by producing a counteracting flux. In addition, analytical equations have also been derived for different scenarios, such as static eccentricity, dynamic eccentricity, axial-varying eccentricity, and skew rotor bars. Finite Element Analysis (FEA) and experimental work are used to demonstrate the derived analytical equation. Furthermore, the power losses caused by the rotor eccentricity are investigated. Iron losses, copper losses, and frictional loss are discussed and compared with both the analytical equation and the FEA results. In order to reduce the UMP in the induction machines, the two proposed methods are the slip control method and damper windings topology. The slip control method utilises the non-linearity characteristic of the UMP at different rotor slip. To find the optimum operating slip with the lowest UMP, the UMP/Torque ratio is introduced. The characteristics of the UMP/Torque ratio varies with the type and design of the induction machines. However, this method is only applicable when the machine is lightly loaded, because the magnetising flux is limited by the capped terminal voltage and the core saturation of the machine. For the damper winding topology, a circulating current flowing in the damper winding could produce a counteracting flux to damp the UMP. The proposed damper windings configuration is only suitable for the induction machine with an even pole pair number. Finally, comparisons between both UMP reduction methods are made.
279	The mechanism of leak-before-break fracture and its application in engineering critical assessment Bourga, Renaud January 2017 (has links) This thesis investigated the different aspects and mechanisms of leak-before-break (LBB) assessment. The main objective was to improve the understanding of the transition between surface and through wall defects. While existing procedures generally idealise the through-wall crack into a rectangular shape, in reality a crack propagates with a shape depending on the loading. Comparison between the related solutions from established procedures have been undertaken. The apparent variation depending on the solutions used in the assessment has been highlighted. Two different methodologies have been employed to investigate the transition of flaw: (i) non-ideal through-wall and (ii) surface-breaking flaw propagation. The first approach consists of numerical models of non-idealised flaws in order to assess the effect on LBB parameters. For the second approach, experiments have been first carried out to visualise the shape of defect growths. To further study surface-breaking flaws, both experimental and numerical studies were performed. Fatigue tests on deeply notched plates with two crack aspect ratios were carried out. Strain evolutions on the back surface were recorded along the axes parallel and perpendicular to the crack. Numerical models have been prepared to investigate a larger scope. Behaviour of growing surface-breaking defects was examined. Based on the work conducted in this research, the major findings can be summarised as follows: - The existing solutions to carry out a LBB assessment using available procedures were reviewed and discussed. For axial flaws, SIF solutions were found similar and in good agreement with FEA values. Reference stress solutions showed significant difference between BS 7910 and API 579-1/ASME FFS-1. When compared to experimental data, API's solutions were able to distinguish between leak and break cases. - Flaw geometry assumption for through-wall crack yet to become idealised did not always reflect the actual behaviour, especially for COA calculation. In this case, FEA can be used as a good predictive tool for LBB to estimate margins when assessing leak rate. - The experiment using metallic specimens showed that high stress/strain on back surface would provide a good estimate of the crack propagation as it approached break-through. This offers a more accurate monitoring mechanism. Strain-mapping devices such as gauges could be used.
280	In-plane Compressive Response of Sandwich Panels Lindström, Anders January 2009 (has links) The high specific bending stiffness of sandwich structures can with advantage be used in vehicles to reduce their weight and thereby potentially also their fuel consumption. However, the structure must not only meet the in-service requirements but also provide sufficient protection of the vehicle passengers in a crash situation. The in-plane compressive response of sandwich panels is investigated in this thesis, with the objective to develop a methodology capable of determining if the structural response is likely to be favourable in an energy absorption perspective. Experiments were conducted to identify possible initial failure and collapse modes. The initial failure modes of sandwich panels compressed quasi-statically in the in-plane direction were identified as global buckling, local buckling (wrinkling) and face sheet fracture. Global buckling promotes continued folding of the structure when compressed beyond failure initiation. Face sheet fracture and wrinkling can promote collapse in the form of unstable debond crack growth, stable end-crushing or ductile in-plane shear collapse. Both the unstable debond crack propagation and the stable end-crushing are related to debond crack propagation, whereas the ductile in-plane shear mode is related to microbuckling of the face sheets. The collapse behaviour of sandwich configurations initially failing due to wrinkling or face sheet fracture was investigated, using a finite element model. The model was used to determine if the panels were likely to collapse in unstable debond propagation or in a more stable end-crushing mode, promoting high energy absorption. The collapse behaviour is mainly governed by the relation between the fracture toughness of the core and the bending stiffness and strength of the face sheets. The model was successfully used to design sandwich panels for different collapse behaviour. The proposed method could therefore be used in the design process of sandwich panels subjected to in-plane compressive loads.During a crash situation the accelerations on passengers must be kept below life threatening levels. The extreme peak loads in the structure must therefore be limited. This can be achieved by different kind of triggering features.Panels with either chamfered face sheets or with grooves on the loaded edges were investigated in this thesis. The peak load was reduced with panels incorporating either of the two triggering features. Another positive effect was that the plateau load following failure initiation was increased by the triggers. This clearly illustrates that triggers can be used to promote favourable response in sandwich panels. Vehicles are harmful to the environment not only during in-serve use, but during their entire life-cycle. By use of renewable materials the impact on the environment can be reduced. The in-plane compressive response of bio-based sandwich panels was therefore investigated. Panels with hemp fibre laminates showed potential for high energy absorption and panels with a balsa wood core behaved particular well. The ductile in-plane shear collapse mode of these panels resulted in the highest energy absorption of all investigated sandwich configurations. / QC 20100728 Sandwich Finite Element Analysis (FEA) Fracture In-plane compression Other engineering mechanics Övrig teknisk mekanik Structural and vibration physics Struktur- och vibrationsfysik

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