Global ETD Search

181	Stacking Sequence Optimization Of A Composite Pressure Vessel By Genetic Algorithm Kutay, Halil 01 September 2007 (has links) (PDF) Stacking sequence design is a combinatorial problem when the fiber orientations in each layer are restricted to certain angles. In addition, there often exist many optimal or nearoptimal designs for the stacking sequence of a composite pressure vessel under different loading conditions. Genetic algorithms are quite well suited for finding the optimal designs for such a combinatorial problem. In this thesis, a genetic algorithm code is developed in Matlab, optimizing the stacking sequence of a composite pressure vessel subjected to internal and external pressures, axial load and body force due to rotation. For testing of the code and identification of the effects of optimization parameters, a problem, whose optimum solution is obvious, is defined and the optimum design is tried to be found by using the developed code. The results have shown that the code was quite successful in finding the best design. Afterwards, the code is used for the optimization of the stacking sequence of a composite pressure vessel under different loading conditions. Again the code has proven its reliability in finding the optimal designs. The developed genetic algorithm optimization code also has the infrastructure to be easily adapted to the solution of different combinatorial problems.
182	Investigation Of Fluid Structure Interaction In Cardiovascular System From Diagnostic And Pathological Perspective Salman, Huseyin Enes 01 June 2012 (has links) (PDF) Atherosclerosis is a disease of the cardiovascular system where a stenosis may develop in an artery which is an abnormal narrowing in the blood vessel that adversely affects the blood flow. Due to the constriction of the blood vessel, the flow is disturbed, forming a jet and recirculation downstream of the stenosis. Dynamic pressure fluctuations on the inner wall of the blood vessel leads to the vibration of the vessel structure and acoustic energy is propagated through the surrounding tissue that can be detected on the skin surface. Acoustic energy radiating from the interaction of blood flow and stenotic blood vessel carries valuable information from a diagnostic perspective. In this study, a constricted blood flow is modeled by using ADINA finite element analysis software together with the blood vessel in the form of a thin cylindrical shell with an idealized blunt constriction. The flow is considered as incompressible and Newtonian. Water properties at indoor temperature are used for the fluid model. The diameter of the modeled vessel is 6.4 mm with 87% area reduction at the throat of the stenosis. The flow is investigated for Reynolds numbers 1000 and 2000. The problem is handled in three parts which are rigid wall Computational Fluid Dynamics (CFD) solution, structural analysis of fluid filled cylindrical shell, and Fluid Structure Interaction (FSI) solutions of fluid flow and vessel structure. The pressure fluctuations and consequential vessel wall vibrations display broadband spectral content over a range of several hundred Hz with strong fluid-structural coupling. Maximum dynamic pressure and vibration amplitudes are observed around the reattachment point of the flow near the exit of the stenosis and this effect gradually decreases along downstream of flow. Results obtained by the numerical simulations are compared with relevant studies in the literature and it is concluded that ADINA can be used to investigate these types of problems involving high frequency pressure fluctuations of the fluid and the resulting vibratory motion of the surrounding blood vessel structure. TJ Mechanical Engineering. 1-1570
183	The research of Taiwan offshore Tuna fishing industry after vessel-reduction by ICCAT Pan, Chun-wei 24 July 2008 (has links) ABSTRACT Our Atlantic Ultra-Low-Temperature Tuna Fishing fleets were under attack from Japan during the 2004 ICCAT (International Commission for the Conservation of Atlantic Tunas) Annual Meeting. Japan openly called for tough penalty for our fleet such as significantly cutting our fishing quotas in the Atlantic and revoking our national membership in the ICCAT for over-fishing, violating International Conservation Regulations and washing fish right on the ocean. This resulted in catastrophic damage in our Ultra-Low-Temperature fishing operation in the pacific and undue pressure from our international competitors. Under the strict monitoring of international conservation groups, our government was forced reform its regulations of the fishing industry and focus on the long-neglected area of offshore fishing. To express its sincerity in active management of the industry, the government offered a series of matching measures. The first of these measures was the reduction of the number of ships to achieve cutback in fishing capacity. The three-year plan spanning from 2005 to 2007 involved a joint venture by the government and the offshore industry with joint contribution of 12.5 million US dollars to disassemble 183 large Tuna Long line Fishing Vessels in the three oceans. Fishing vessels in the Atlantic were reduced from 100 to 76. The next measures were to improve the monitoring of the fishing industry and to end any and all illegal, unreported and unregulated fishing. How will our offshore fishing industry recover after a series of attack? How will our industry thrive in the austere environment of conservatism? Do we still possess any competitive advantage after the vessel-reduction measure? This thesis will cover the analysis of the competitive advantage of the Offshore Ultra-Low-Temperature Fishing Industry after the vessel-reduction, the analysis of the supply-and-demand of the Ultra-Low-Temperature market and SWOT analysis. It will also discuss in depth the post-reform fishing industry management strategy for reference. SWOT analysis fishing industry management strategy vessel-reduction Ultra-Low-Temperature Tuna Fishing international conservation groups
184	Biomechanics and biaxial mechanical stimulation of self-assembly tissue engineered blood vessels Zaucha, Michael Thomas 01 April 2011 (has links) Despite efforts by clinicians and scientists world-wide, coronary artery disease remains to be the leading cause of morbidity and mortality in industrialized nations. Development of a tissue engineered coronary by-pass graft with low thrombogenicity and immune responses, suitable mechanical properties, and a capacity to remodel to their environment could have a significant impact on the treatment of coronary artery disease. While many methods for the tissue engineering of blood vessels have been developed, one promising approach is the self-assembly method. Using autologous cells that produce an endogenous extracellular matrix (ECM), the potential for therapeutic success is high due to biocompatibility. However, despite these advantages, improvements can be made which will give the grafts an even higher rate of patency. This dissertation presents a study of the characterization of the biaxial mechanical properties of self-assembly tissue engineered blood vessels (SA-TEBV), as well as developing a framework for fabrication strategies of SA-TEBV. Native arteries are exposed to multiaxial mechanical loads, including (a pulsatile) blood pressure that causes the vessel to cyclically distend circumferentially, blood flow that induces a shearing load along the luminal surface, and an axial extending load; the latter is relieved upon excision, causing the vessel to retract. These mechanical loads introduce intramural wall stresses and flow induced wall shear stresses that play a key role in mechano-biological signaling and tissue homeostasis. Until now, the mechanical properties of SA-TEBV have only been characterized in the circumferential direction (i.e. burst pressure and circumferential elastic modulus). The objective of this work is to characterize the biaxial mechanical properties of SA-TEBV to quantify their mechanical behavior and local intramural stresses under physiological loading. The work will show that while the global mechanical response of the SA-TEBV is similar to that of native arteries (and potentially sufficient), the local intramural stresses (using the current fabrication techniques) differ greatly from native coronary arteries. Therefore, a novel approach to fabricate the self-assembly derived tissue sheets is developed and tested which utilizes biaxial mechanical stimulation to alter the microstructure, thereby controlling their mechanical response. Arteries TEBV Fibroblast Smooth muscle cells Self-organizing systems Micromechanics
185	Influence of hull configuration and vessel propulsion systems on sea turtle shell injuries Spurlock, Chad M. 02 July 2012 (has links) Loggerhead sea turtles in coastal waters often sustain injuries from vessel impacts. The influences of vessel hull configuration and propulsion system type on the incidence and severity of wounds in turtle/vessel interaction were investigated. Full-scale field tests using two vessels with deep-vee hulls were performed. An artificial carapace with a sandwich composite design of a closed-cell polyurethane foam core with faces constructed of polyester resin infused with glass microspheres was developed. As a basis for comparison, a number of cold-stunned green turtle carcasses were also used in the field experiments. Two vessels, a 5.4 m boat with an inboard jet-drive engine and a 7.3 m boat with an outboard 4-bladed propeller, were operated at planing speed, 40 km/h. The field test results revealed similar patterns and severity of injuries between the synthetic turtles and the green turtle carcasses. Statistical analysis of the field test results indicated the influence of hull type alone on the severity of turtle damage was minimal, and none of the tests conducted using a jet drive engine resulted in injuries to the shell that would be considered lethal, regardless of the vessel hull type, speed, or the animal's depth in the water at impact. Conversely, injuries occurring as a result of propeller and/or skeg impact at planing speed were always classified as fatal. A finite element analysis of the artificial turtle was performed to determine the force at which a carapace fractures from hull impact alone. The results of the finite element analysis suggest that hull impacts of common recreational jet-propulsion vessels are unlikely to cause lethal carapace fractures in loggerhead sea turtles. Loggerhead Vessel strikes Sea turtle Loggerhead turtle Endangered species Wildlife recovery
186	Untersuchungen an neutronenbestrahlten Reaktordruckbehälterstählen mit Neutronen-Kleinwinkelstreuung Ulbricht, Andreas 31 March 2010 (has links) (PDF) In dieser Arbeit wurde die durch Bestrahlung mit schnellen Neutronen bedingte Materialalterung von Reaktordruckbehälterstählen untersucht. Das Probenmaterial umfasste unbestrahlte, bestrahlte und ausgeheilte RDB-Stähle russischer und westlicher Reaktoren sowie Eisenbasis-Modelllegierungen. Mittels Neutronen-Kleinwinkelstreuung ließen sich bestrahlungsinduzierte Leerstellen/Fremdatom-Cluster unterschiedlicher Zusammensetzung mit mittlerem Radius um 1.0 nm nachweisen. Ihr Volumenanteil steigt mit der Strahlenbelastung monoton, aber im allgemeinen nicht linear an. Der Einfluss der Elemente Cu, Ni und P auf den Prozess der Clusterbildung konnte herausgearbeitet werden. Eine Wärmebehandlung oberhalb der Bestrahlungstemperatur reduziert den Anteil der Strahlendefekte bis hin zu deren vollständiger Auflösung. Die Änderungen der mechanischen Eigenschaften der Werkstoffe lassen sich eindeutig auf die beobachteten Gefügemodifikationen zurückführen. Die abgeleiteten Korrelationen können als Hilfsmittel zur Vorhersage des Materialverhaltens bei fortgeschrittener Betriebsdauer von Leistungsreaktoren mit herangezogen werden. small-angle neutron scattering irradiation-induced microstructure
187	Early Vessel Evolution and the Diversification of Wood Function: Insights from the Malagasy Canellales Hudson, Patrick Joseph 01 May 2010 (has links) Xylem vessels have long been proposed as a key innovation for the ecological diversification of angiosperms by providing a breakthrough in hydraulic efficiency to support high rates of photosynthesis and growth. However, recent studies demonstrated that angiosperm woods with structurally ‘primitive’ vessels did not have greater whole stem hydraulic capacities as compared to vesselless angiosperms. As an alternative to the hydraulic superiority hypothesis, the heteroxylly hypothesis proposes that subtle hydraulic efficiencies of primitive vessels over tracheids enabled new directions of functional specialization in the wood. However, the functional properties of early heteroxyllous wood remain unknown. We selected the two species of Canellales from Madagascar to test the heteroxylly hypothesis because Canellaceae (represented by <em>Cinnamosma madagascariensis</em>) produces wood with vessels of an ancestral form, while Winteraceae, the sister-clade (represented by <em>Takhtajania perrieri</em>) is vesselless. We found that heteroxylly correlated with increased wood functional diversity related mostly to biomechanical specialization. However, vessels were not associated with greater stem hydraulic efficiency or increased shoot hydraulic capacity. Our results support the heteroxylly hypothesis and highlight the importance integrating a broader ecological context to understand the evolution of vessels. Canellales heteroxylly xylem evolution vessel development Comparative and Evolutionary Physiology Evolution Plant Biology Structural Biology
188	Human Tissue Engineered Small Diameter Blood Vessels Arief, Melissa Suen 24 September 2010 (has links) The engineering of human vascular grafts is an intense area of study since there is crucial need for alternatives to native vein or artery for vascular surgery. This current study sought to prove that a tissue engineered blood vessel (TEBV) 1mm in diameter could be developed from human smooth muscle cells and that endothelial progenitor cells (EPCs) could be cultured and used to endothelialize these grafts. This project had four specific aims: the isolation and characterization of EPCs, the seeding of a novel scaffold with EPCs and exposure to physiologic shear stress in vitro, the development of TEBV from human smooth muscle cells that are strong enough to implant in vivo, and the in vivo implantation of TEBV into the rat aortic model with a comparison of EPC seeded TEBVs pretreated with shear stress and unseeded TEBVs. The results yielded isolation of four EPC lines and a flow system design capable of seeding EPCs onto a novel scaffold with preliminary studies indicating that it is capable of exposing the EPCs to physiologic shear stress, although further studies require more optimization. The development of mechanically strong TEBV was highly successful, yielding TEBVs comparable to native vessels in collagen density and burst pressure, but with much lower compliance. Current implantation studies indicated that unseeded TEBV grafts implanted into the rat aorta without anticoagulation is highly thrombogenic. However, anticoagulation using Plavix may be capable of maintaining graft patency. These TEBVs did not rupture or form aneurysm in vivo and the future completion of the in vivo studies are likely to demonstrate the high potential of these grafts. human blood vessels blood vessel prosthesis myocytes smooth muscle endothelial cells rat tissue engineering
189	ROx3: Retinal Oximetry Utilizing the Blue-Green Oximetry Method Parsons, Jennifer Kathleen Hendryx January 2014 (has links) The ROx is a retinal oximeter under development with the purpose of non-invasively and accurately measuring oxygen saturation (SO₂) in vivo. It is novel in that it utilizes the blue-green oximetry technique with on-axis illumination. ROx calibration tests were performed by inducing hypoxia in live anesthetized swine and comparing ROx measurements to SO₂ values measured by a CO-Oximeter. Calibration was not achieved to the precision required for clinical use, but limiting factors were identified and improved. The ROx was used in a set of sepsis experiments on live pigs with the intention of tracking retinal SO₂ during the development of sepsis. Though conclusions are qualitative due to insufficient calibration of the device, retinal venous SO₂ is shown to trend generally with central venous SO₂ as sepsis develops. The novel sepsis model developed in these experiments is also described. The method of cecal ligation and perforation with additional soiling of the abdomen consistently produced controllable severe sepsis/septic shock in a matter of hours. In addition, the ROx was used to collect retinal images from a healthy human volunteer. These experiments served as a bench test for several of the additions/modifications made to the ROx. This set of experiments specifically served to illuminate problems with various light paths and image acquisition. The analysis procedure for the ROx is under development, particularly automating the process for consistency, accuracy, and time efficiency. The current stage of automation is explained, including data acquisition processes and the automated vessel fit routine. Suggestions for the next generation of device minimization are also described. oxygen saturation retinal imaging retinal oximeter sepsis vessel profile analysis oximetry Optical Sciences
190	Imaging Tissue Engineered Blood Vessel Mimics with Optical Coherence Tomography Bonnema, Garret January 2008 (has links) Optical coherence tomography (OCT) is a technology that enables 2D cross-sectional images of tissue microstructure. This interferometric technique provides resolutions of approximately 10-20 um with a penetration depth of 1-2 mm in highly scattering tissues. With the use of fiber optics, OCT systems have been developed for intravascular imaging with a demonstrated improvement in both resolution and dynamic range compared to commercial intravascular ultrasound systems. OCT studies of normal, atherosclerotic, and stented arteries indicate the ability of OCT to visualize arterial structures. These results suggest OCT may be a valuable tool for studying luminal structures in tissue engineered constructs.In the present study, new endoscopic OCT systems and analysis techniques were developed to visualize the growth and response of the cellular lining within a tissue engineered blood vessel mimic (BVM). The BVM consists of two primary components. A biocompatible polymeric scaffold is used to form the tubular structure. Human microvessel cells from adipose tissue are sodded on to the inner surface of the scaffold. These constructs are then developed and imaged within a sterile bioreactor.Three specific aims were defined for the present study. First, an OCT longitudinal scanning endoscope was developed. With this endoscope, a study of 16 BVMs was performed comparing images from OCT and corresponding histological sections. The study demonstrated that endoscopic imaging did not visually damage the mimic cellular lining. OCT images showed excellent correlation with corresponding histologicalsections. Second, a concentric three element endoscope was developed to provide radial cross-sections of the BVM. OCT images using this endoscope monitored lining development on three types of polymeric scaffolds. In the third specific aim, automated algorithms were developed to assess the percent cellular coverage of a stent using volumetric OCT images.The results of the present study suggest that OCT endoscopic systems may be a valuable tool for assessing and optimizing the development of tissue engineered constructs. Conversely, the BVMs modeled the arterial response to deployed stents allowing the development of automated OCT analysis software. These results suggest that blood vessel mimics may be used to advance OCT technology and techniques. optical coherence tomography tissue engineering endoscopy bioreactor catheter blood vessel mimic

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