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291	Process-induced damage evolution and management in resin transfer molding of composite panels / Kuan, Yean-Der, January 2000 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 2000. / Typescript. Vita. Includes bibliographical references (leaves 153-159). Also available on the Internet.
292	Process-induced damage evolution and management in resin transfer molding of composite panels Kuan, Yean-Der, January 2000 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 2000. / Typescript. Vita. Includes bibliographical references (leaves 153-159). Also available on the Internet.
293	A study on the marketing of injection moulding machines : an analysis of the buying behaviour of industrial buyers / Chung, Kwok Kwong, Albert. January 1980 (has links) Thesis (M.B.A.)--University of Hong Kong, 1980.
294	Microprocessor control system for the injection molding process Haber, Andrew. January 1982 (has links) No description available. Microprocessors.
295	Analyse expérimentale et numérique de la fabrication de pièces composites par le procédé RTM Agogué, Romain 17 February 2011 (has links) (PDF) Cette thèse s'intéresse à la fabrication de pièces composites par le procédé Resin Transfert Molding (ou RTM), appliquée à des tubes de protection thermiques. Plus particulièrement, cette thèse vise à démontrer la faisabilité d'utiliser ce procédé pour la fabrication cette pièce complexe. La phase d'imprégnation de préformes sèches est plus particulièrement étudiée. Après mise en oeuvre, cette pièce peut présenter des défauts tels que de la porosité ou des déplacements de plis constituant la préforme. L'objectif de cette thèse est donc de comprendre l'origine de ces défauts et de minimiser voire de d'empêcher leur apparition. Pour cela, une démarche expérimentale a été mise en place. Celle ci comprend la réalisation d'un pilote de laboratoire permettant d'appliquer différentes conditions d'imprégnation aux préformes considérées. La perméabilité des renforts considérés a aussi été évaluée à différentes échelles grâce à l'utilisation de moyen dédiés à l'échelle macroscopique (banc de perméabilité planaire et transverse), et grâce à l'utilisation d'un code de calcul se basant sur des images de tomographie synchrotron à l'échelle microscopique. Enfin, une analyse de la qualité des prototypes réalisés a été menée en suivant des procédures mises en place lors de ce projet et les résultats analysés et mis en relation avec les conditions de mise en oeuvre. Cette approche expérimentale est couplée aux simulations numériques de la phase d'imprégnation que nous avons aussi mise en oeuvre au cours de cette thèse. Par l'utilisation combinée de la simulation numérique et des essais expérimentaux, nous avons défini des critères estimant le risque d'apparition des défauts. Ces critères ont montré leur efficacité sur les solutions innovantes que nous avons proposées puisque répondant aux exigences du cahier des charges industriel. [SPI] Engineering Sciences [SPI] Sciences de l'ingénieur Tubes de protection thermiques Procédé resin transfert molding Couplage hydromécanique
296	Design and manufacturing of composite structures using the resin transfer molding technique Keulen, Casey James 22 December 2007 (has links) Composite materials have the potential to revolutionize life in the 21st century. They are contributing significantly to developments in aerospace, hydrogen fuel cells, electronics and space exploration today. While a number of composite material processing methods exist, resin transfer molding (RTM) has the potential of becoming the dominant low-cost process for the fabrication of large, high-performance products. RTM has many advantages over alternative processes, including the capability of producing complex 3D shapes with a good surface finish, the incorporation of cores and inserts, a tight control over fiber placement and resin volume fraction and the possibility of embedding sensors into manufactured components for structural health monitoring. Part of the reason RTM has not received widespread use is due to its drawbacks such as its relatively trial and error nature, race tracking, washout, high cycle time and void formation. The basic operation of the process involves loading a fiber reinforcement preform into a mold cavity, closing the mold, injecting resin into the mold and allowing the resin to cure. To study the resin transfer molding process and issues affecting it, a laboratory containing an experimental RTM apparatus has been established. The apparatus has a glass window to observe the mold filling process and can incorporate various mold shapes such as a quasi-2D panel, a 3-D rectangular section and a 3-D semicircular section. To characterize the flow through the molds a commercial CFD software has been used. This thesis describes the establishment of this laboratory and preliminary studies that have been conducted. Composite Materials Resin Transfer Molding RTM
297	Process and structural health monitoring of composite structures with embedded fiber optic sensors and piezoelectric transducers Keulen, Casey James 24 August 2012 (has links) Advanced composite materials are becoming increasingly more valuable in a plethora of engineering applications due to properties such as tailorability, low specific strength and stiffness and resistance to fatigue and corrosion. Compared to more traditional metallic and ceramic materials, advanced composites such as carbon, aramid or glass reinforced plastic are relatively new and still require research to optimize their capabilities. Three areas that composites stand to benefit from improvement are processing, damage detection and life prediction. Fiber optic sensors and piezoelectric transducers show great potential for advances in these areas. This dissertation presents the research performed on improving the efficiency of advanced composite materials through the use of embedded fiber optic sensors and surface mounted piezoelectric transducers. Embedded fiber optic sensors are used to detect the presence of resin during the injection stage of resin transfer molding, monitor the degree of cure and predict the remaining useful life while in service. A sophisticated resin transfer molding apparatus was developed with the ability of embedding fiber optics into the composite and a glass viewing window so that resin flow sensors could be verified visually. A novel technique for embedding optical fiber into both 2- and 3-D structures was developed. A theoretical model to predict the remaining useful life was developed and a systematic test program was conducted to verify this model. A network of piezoelectric transducers was bonded to a composite panel in order to develop a structural health monitoring algorithm capable of detecting and locating damage in a composite structure. A network configuration was introduced that allows for a modular expansion of the system to accommodate larger structures and an algorithm based on damage progression history was developed to implement the network. The details and results of this research are contained in four manuscripts that are included in Appendices A-D while the body of the dissertation provides background information and a summary of the results. / Graduate composite materials structural health monitoring fiber bragg grating resin transfer molding
298	Modelling Of Resin Transfer Molding For Composites Manufacturing Ipek, Hakan 01 December 2005 (has links) (PDF) The resin transfer molding (RTM ) process, in which a thermosetting resin is injected into a mold cavity preloaded with a porous fiber preform, is a manufacturing method for producing advanced continuous fiber reinforced composite products with complex geometries. Numerical simulation of resin transfer molding process is an often needed tool in manufacturing design, in order to analyze the process before the mold is constructed. In this study, a numerical simulation of the resin impregnation process in RTM of composite materials is performed by using and modifying an existing simulation program. The parts that are molded in the simulations have their planar dimensions much larger than their thicknesses. Therefore, the mold filling process can be modeled as two dimensional by neglecting the variations along the thickness direction. The program is capable of simulating two-dimensional, isothermal impregnation processes through orthotropic fiber preforms of planar but complex geometries. The formulations of the physical problem, used in this study, were taken from the theory of macroscopic flow through anisotropic porous media. The formulated governing equation and boundary conditions are solved in a regular-geometry computational domain by transformation through boundary fitted coordinate system. The discretization for numerical solution is performed by the finite difference method. The current study extends the existing capabilities of the simulation program by enabling the simulation of impregnation through non-homogeneous fiber preforms. Furthermore, the capability to simulate injection from two gates (as opposed to a single gate injection that existed before) is developed and added to the program. Various one-dimensional impregnation simulations (as parametric studies) are performed to assess the influence of process parameters. Results are also compared with analytical solutions and found to be in agreement with them. Two-dimensional impregnation simulations are performed for a planar, complex geometry mold. The two-dimensional results are compared with experimental results from the literature and are found to be in acceptable agreement with them. In addition to the study of various parametric variations in two-dimensional impregnation, double-gate resin injection simulations are performed and discussed as well. TJ Mechanical Engineering. 1-1570
299	Metal-transfer-molding (MTM) technique for micromachined RF components Zhao, Yanzhu 08 July 2008 (has links) This dissertation reports a metal-transfer-molding (MTM) technique for simultaneous implementation of air-lifted RF passive components, as well as coplanar waveguide (CPW) structures, in a high performance and potentially cost-effective fashion. A metal transfer mechanism is introduced into the conventional micro-molding process to realize polymer-core RF passive components and integration. A system-on-package (SOP) integration scheme of front-end RF components can be realized by this process. Several air-lifted RF components based on MTM technology have been presented with excellent performance. As an integration application of the MTM technology, a novel wireless passive airflow sensor based on the RF evanescent-mode cavity resonators has been also presented. The sensor makes use of RF technology to measure wind velocity through changes in the resonant frequency with applied airflow. Compared with reported wireless sensors based on conventional RF cavity resonator, this design has advantages such as compact size and greatly improved sensitivity. Wireless interrogating has also been demonstrated for the passive sensor. Overall, the RF components developed in this thesis illustrate the great potential of MTM technology in both wireless communication and sensor areas. MEMS Micromachining RF Wireless Sensor Molding Polymer Radio frequency integrated circuits Passive components Wave guides Micromachining
300	Rapid production of polymer microstructures Nagarajan, Pratapkumar 25 August 2008 (has links) The goal of this research is to develop an integrated polymer embossing module, with which difficult-to-emboss polymer microstructures and microparts can be fabricated in a cost-effective manner. In particular, the research addresses three major limitations of the hot embossing process, namely, long cycle time, difficulty in producing shell patterns, and difficulty in building up a high embossing pressure on thick substrates. To overcome these limitations, three new technical approaches two-station embossing, rubber-assisted embossing, and through-thickness embossing were developed and investigated. Fundamental understanding of these new embossing techniques were achieved through extensive experimental and theoretical studies involving parametric experiments, rheological characterization, surface investigation, mathematical modeling, and computer simulation. Rubber embossing Micro molding Hot embossing Polymers Mechanical properties Microstructure Design and construction Embossing (Printing)

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