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Novel processing methods and mechanisms to control the cast microstructure in Al based alloys -- 390 and wrought alloysSaha, Deepak. January 2005 (has links)
Thesis (M.S.) -- Worcester Polytechnic Institute. / Keywords: liquid mixing; CDS; casting' wrought; AI-Si; AI alloys; AI; aluminum; Includes bibliographical references (p.11-9).
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The continuous rheoconversion process Scale-up and optimization.Bernard, William J. January 2005 (has links)
Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: CRP; Thixocasting; Rheocating; Semisolid. Includes bibliographical references (leaves 46-48).
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Antecedent diet effect on thermogenic and cardiovascular responses to different mealsHabas, Elmukhtar M. A. January 1996 (has links)
No description available.
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Development of twin screw Rheo extrusion technologyCassinath, Zen January 2013 (has links)
Twin Screw Rheo Extrusion (TSRE) is a novel semisolid extrusion process developed at BCAST for producing simple profiles such as rods and wires of light alloys directly from melts with refined microstructures and improved mechanical properties. The process represents a shortened manufacturing route with great savings in investment, energy consumption and operation space. Research was carried out to investigate the feasibility of processing magnesium and aluminium alloys, to obtain the operations for the optimized microstructures and mechanical properties of the final product and to understand the mechanisms governing the evolution of microstructures. Experiments were conducted using an AZ91D magnesium alloy and several aluminium alloys on two specially made twin screw rheo extrusion machines and a range of conditions were tested. Results showed that the TSRE process was feasible for the AZ91D magnesium alloy and aluminium alloys, although modifications were required for processing aluminium alloys as the twin screw material used was found to react with aluminium. Analysis revealed that the extruded samples of both alloys had a uniform fine microstructure in both transversel and longitudinal directions and liquid segregation was limited, due to the application of intensive shearing during slurry making and extrusion. Low extrusion temperature was found to refine the structure and suppress the formation of the eutectic. The eutectic was easily dissolved upon heat treatment resulting in reasonable mechanical properties. Numerical analysis on thermal management was carried out and the results showed that a steady state thermal profile with a temperature gradient between the slurry feeding point and extrusion die could be established, promoting nucleation and preventing the formed solid particles from extensive growth during extrusion, which was confirmed by microstructural observations.
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In situ synchrotron tomographic quantification of semi-solid properties of aluminum-copper alloysCai, Biao January 2015 (has links)
Semi-solid deformation mechanisms are important in a range of manufacturing and natural phenomena, which range from squeeze casting to magma flows. In this thesis, using high speed synchrotron X-ray tomography and a bespoke precision thermo-mechanical rig, a four dimensional (3D plus time) quantitative investigation was performed to study the mechanical / rheological behavior of semi-solid Al-Cu alloys. Various deformation techniques, namely, isothermal semi-solid compression, extrusion and indentation were used. The time-resolved dynamic 3D images were analyzed with the help of novel image quantification techniques including digital volume correlation and image-based simulations of fluid flow. The quantified dynamics at a microstructural scale was then linked with macroscopic mechanical properties. The qualitative and quantitative analyses revealed a range of important semi-solid micromechanical mechanisms including the occurrence and effects of dilatancy, associated liquid flow through the equiaxed microstructure, intra-dendritic deformation, and strain localization during semi-solid deformation, not only shedding new insights into the mechanisms of deformation-induced solidification defect formation (solute segregation, porosity and hot tearing) of semi-solid alloys at both a macroscopic and microscopic level, but also providing benchmark cases for semi-solid deformation models and theories. The experimental methodology, techniques and analysis procedures developed in this thesis are generic in nature and can be applied to a wide range of research fields.
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Semi-solid slurry formation via liquid metal mixingFindon, Matthew M. January 2003 (has links)
Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: thixocasting; SSM; semi-solid processing; liquid metal mixing; rheocasting. Includes bibliographical references (p. 88-90).
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Semi-Solid Slurry Formation Via Liquid Metal MixingFindon, Matthew M. 21 July 2003 (has links)
"New, economical semi-solid metal (SSM) processes rely on forced convection during solidification to influence non-dendritic growth. The fundamental mechanisms that produce SSM microstructures in the presence of forced convection (due to fluid flow) are not fully understood. The objective of this work is to elucidate these mechanisms through the use of a new semi-solid slurry-making technique. Employing an apparatus developed at WPI, two alloy melts are mixed within a static reactor that induces convection and rapid cooling. Experiments carried out with this apparatus, named the “Continuous Rheoconversion Process†(CRP), result in globular semi-solid microstructures throughout a wide range of processing conditions. These conditions include the superheat in the melts before mixing, cooling rate of the slurry through the SSM range, and the presence or absence of inoculants in the melts. The results comprise repeatable sets of semi-solid microstructures having fine particle size and shape factors approaching unity. Even in the absence of melt inoculants, uniform distributions of α-Al particle sizes of about 60µm are attainable. Entrapped liquid is not present in the majority of the samples obtained with the CRP, and irregular particles that form in the process are of a limited distribution. Variation of slurry analysis methods indicates that these structures can be obtained consistently for both thixocasting and rheocasting applications. The design of the mixing reactor leads to turbulent fluid flow just as solidification commences. The results suggest that the following factors must be considered in identifying the mechanisms operating under the above conditions: copious nucleation of the primary phase; dispersion of nuclei throughout the bulk liquid; and inhibited remelting of nuclei due to temperature uniformity. In the CRP, these factors consistently lead to suppression of dendritic growth, significant grain refinement, and globular slurries. The exact fundamental mechanism leading to this effect is yet to be uncovered; however it is clear that temperature gradients ahead of the liquid are such that a cellular, non-dendritic morphology is the most stable growth form. Through further exploration of the process and identification of the operating mechanisms, future development of economical, continuous rheocasting methods will be facilitated."
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Effect of Semi-Solid Processing on Microstructural Evolution and Mechanical Behavior of Austenitic Stainless SteelSamantaray, Diptimayee January 2015 (has links) (PDF)
In view of the significant advantages offered by semi-solid processing, such as reduction in number of intermediate processing steps and energy input, and the potential for improving component complexity, it is of paramount interest to develop indigenous technology for semi-solid forming of steels, especially nuclear grade steels. For adopting semisolid processing as an alternative method of manufacturing of steels, it is essential to study the amenability of the steel for the process, understand the fundamental mechanisms of micro structural evolution and evaluate the mechanical properties of the steel after processing. To achieve this goal, the present work attempts to appraise the amenability of a low-carbon variant of 18%Cr-8%Ni austenitic stainless steel (304L SS) for semi-solid processing.
Among the many requirements of the feedstock in semi-solid processing, a key feature that makes it amenable for semi-solid processing is the unique microstructure containing solid spheroids in a liquid matrix, thereby enabling thixo-tropic behaviour in the alloy. To understand the micro structural evolution in the steel, during major steps of semi-solid processing (partial melting, soaking and solidification), several experiments are carried out by varying the key parameters such as temperature, soaking time and cooling rate. Experimental results are analyzed in details to specify the effects of these parameters on the microstructure of semi-solid processed steel. The analysis indicates different phase transformation sequences during solidification of the steel from its semi-solid state. On the basis of experimental results, mechanism for micro structural evolution during partial melting and subsequent solidification of 304L SS is proposed. The effect of soaking time on the size and shape of the solid globules is analyzed using the theory of anisotropic Ostwald ripening. The semi-solid processing parameters, such as soaking time and temperature, are found to have significant influence on the globule distribution, globule shape, ferrite distribution and dislocation density, which in turn govern the tensile behaviour and mechanical properties of the steel after processing. Semi-solid processed 304L SS exhibits lower yield strength, ultimate tensile strength and higher strain hardening in temperature range 303–873K compared to as-received (rolled and subsequently annealed) 304L SS. However, semi-solid processed steel shows higher uniform elongation and fracture strain compared to the as-received steel. A pronounced effect of semi-solid processing is also found on the high temperature plasticity and dynamic recrystallization pattern.
This work demonstrates the amenability of 300 series austenitic stainless steels for semi-solid processing. The investigation provides the significant insight into the mechanism of micro structural evolution in austenitic stainless steels during semi-solid processing and the important information on the mechanical properties and plastic flow behavior of the semi-solid processed steel. The results give crucial inputs for the optimization of processing parameters for obtaining the desired property in the product, and also for deciding the potential industrial application of the process.
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Study Of Solidification And Microstructure Produced By Cooling Slope MethodKund, Nirmala Kumar 09 1900 (has links) (PDF)
In most casting applications, dendritic microstructure morphology is not desired because it leads to poor mechanical properties. Forced convection causing sufficient shearing in the mushy zone of the partially solidified melt is one of the means to suppress this dendritic growth. The dendrites formed at the solid-liquid interface are detached and carried away due to strong fluid flow to form slurry. This slurry, consisting of rosette or globular particles, provides less resistance to flow even at a high solid fraction and can easily fill the die-cavity. The stated principle is the basis of a new manufacturing technology called “semi-solid forming” (SSF), in which metal alloys are cast in the semi-solid state. This technique has numerous advantages over other existing commercial casting processes, such as reduction of macrosegregation, reduction of porosity and low forming efforts. Among all currently available methods available for large scale production of semisolid slurry, the cooling slope is considered to be a simple but effective method because of its simple design and easy control of process parameters, low equipment and running costs, high production efficiency and reduced inhomogeneity. With this perspective, the primary objective of the present research is to investigate, both experimentally and numerically, convective heat transfer and solidification on a cooling slope, in addition to the study of final microstructure of the cast billets.
Some key process parameters are identified, namely pouring temperature, slope angle, slope length, and slope cooling rate. A systematic scaling analysis is performed in order to understand the relative importance of the parameters in influencing the final properties of the slurry and microstructure after solidification. A major part of the present work deals with the development of an experimental set up with careful consideration of the range of process parameters involved by treating the cooling slope as a heat exchanger. Subsequently, a comprehensive numerical model is developed to predict the flow, heat transfer, species concentration solid fraction distribution of aluminum alloy melt while flowing down the cooling slope. The model uses a variable viscosity relation for slurry. The metal-air interface at the top during the melt flow is tracked using a volume of fluid (VOF) method. Solidification is modeled using an enthalpy based approach and a volume averaged technique. The mushy region is modeled as a multi-layered porous medium consisting of fixed columnar dendrites and mobile equiaxed or fragmented grains. In addition, the solidification model also incorporates a fragmentation criterion and solid phase movement.
The effects of key process parameters on flow behavior involving velocity distribution, temperature distribution, solid fractions at the slope exit, and macrosegregation, are studied numerically and experimentally for aluminium alloy A356. The resulting microstructures of the cast billets obtained from the experiments are studied and characterized. Finally the experimental results are linked to the model predictions for establishing the relations involving interdependence of the stated key process parameters in determining the quality of the final cast products. This study is aimed towards providing the necessary guidelines for designing a cooling slope and optimizing the process parameters for desirable quality of the solidified product.
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Processamento e propriedades de tiras metálicas fundidas da liga Al-Si A413 produzidas por reolaminação /Oliveira Neto, Pedro Barbosa de. January 2019 (has links)
Orientador: Antonio de Pádua Lima Filho / Resumo: A liga Al-Si A413 foi utilizada para fabricação de tiras metálicas fundidas por cilindro único e por cilindro duplo, aqui chamado processo de reolaminação. Esta liga não é adequada para obtenção de tiras metálicas por laminação convencional devido às partículas frágeis de Si. Por outro lado, a reolaminação é um processo viável para obter tiras metálicas dessa liga. Neste trabalho, a liga Al-Si A413 foi fundida e vazada com diferentes temperaturas em uma calha metálica inclinada a 20º numa vazão de 14 cm³/s para se obter um material semissólido que alimenta um bocal cerâmico (150 cm³) junto ao cilindro inferior. Na reolaminação, o espaçamento entre os cilindros foi de 1,5 mm. Os cilindros na cadeira de laminação são feitos de aço ao carbono comum e têm aproximadamente 105 mm de diâmetro e 100 mm de largura. A região coquilhada/colunar formada no cilindro inferior arrasta a lama metálica a uma velocidade de 0,2 m/s para ser processada tanto por cilindro único como por reolaminação. Para ambos os processos as tiras metálicas fundidas têm uma espessura de 2 mm, aproximadamente. Na saída da cadeira de laminação, as tiras são resfriadas até a temperatura ambiente por chuveiros de água. O equipamento utilizado para a fabricação das tiras metálicas, chamado de “Strip Caster”, passou por inovações durante este trabalho de mestrado: molas de alívio de pressão foram instaladas no cilindro superior e o cilindro inferior foi substituído por um outro cilindro com refrigeração interna. O “S... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The Al-Si A413 alloy was used in order to produce metallic strips with the single roll and twin roll processes, this last one is known as rheolamination. This alloy is not suitable to obtain metallic strips with the conventional lamination due to the brittle particles of silicon. On the other hand, the rheolamination is a suitable process to obtain metallic strips of this alloy. In this work, Al-Si A413 alloy was melted and poured at 680 ºC on a cooling slope at 20º with a flow rate of 14 cm³/s in order to obtain a semisolid material feeding the ceramic nozzle (150 cm³) at the lower roll. The two rolls of the roll stand are separated with a gap of approximately 1.5 mm, have approximately 105 mm in diameter and are made of carbon steel. The chill/columnar layer formed at the lower roll drags the metallic slurry at a rate of 0.2 m/s to be processed by single roll or twin-roll. Both processes obatin a metallic cast strip with a thickness of 2 mm, approximately. At the exit of the stand roll, the strips are cooled to the room temperature with water showers. The equipment used to produce metallic strips, called “Strip Caster”, suffered some inovations during this work: springs was attached to the upper roll in order to reduce the lamination pressure and the lower roll was substituted with an other roll with internal cooling. The Strip Caster was instrumented with two load cell in order to measure the forming forces and with thermocouples to measure the temperatures during the fabr... (Complete abstract click electronic access below) / Mestre
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