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21	Inductive activation of magnetite filled shape memory polymers Vialle, Greg 09 April 2009 (has links) Thermally activated shape memory polymers are a desirable material for use in dynamic structures due to their large strain recovery, light weight, and tunable activation. The addition of ferromagnetic susceptor particles to a polymer matrix provides the ability to heat volumetrically and remotely via induction. Here, remote induction heating of magnetite filler particles dispersed in a thermoset matrix is used to activate shape memory polymer as both solid and foam composites. Bulk material properties and performance are characterized and compared over a range of filler parameters, induction parameters, and packaging configurations. Magnetite filler particles are investigated over a range of power input, in order to understand the effects of particle size and shape on heat generation and flux into the matrix. This investigation successfully activates shape memory polymers in 10 to 20 seconds, with no significant impact of filler particles up to 10wt% on mechanical properties of shape memory foam. Performance of different particle materials is dependent upon the amplitude of the driving magnetic field. There is a general improvement in heating performance for increased content of filler particles. Characterization indicates that heat transfer between the filler nanoparticles and the foam is the primary constraint in improved heating performance. The use of smaller, acicular particles as one way to improve heat transfer, by increasing interfacial area between filler and matrix, is further examined. Magnetite SMP Induction heating Smart materials Magnetite Polymers Ferromagnetic materials Heat Transmission
22	Contribution à l'étude et à la commande d'un système de chauffage par induction polyphasé / Contribution to the study and the control of multiphase induction heating system Souley Madougou, Abdoul Majid 06 October 2011 (has links) Le chauffage par induction est un procédé qui consiste à plonger un matériau conducteur d'électricité dans un champ magnétique variable, ayant ainsi pour effet, la création de FEM donc de courants de Foucault dont la circulation élève la température du matériau par effet Joule. Ce mode de chauffage est déjà implanté industriellement dans de nombreux secteurs parmi lesquels des fonderies et s'intègre bien dans les processus de traitement des matériaux en raison de ses divers avantages. Il permet notamment, l'atteinte de densités de puissances très élevées dont la distribution peut être contrôlée. Il est ainsi possible d'obtenir des chauffages localisés ou de l'ensemble du matériau suivant le traitement désiré. Cette souplesse du contrôle des profils de chauffe et une forte puissance de chauffe requièrent traditionnellement l'usage de systèmes comportant plusieurs bobines. Leur caractérisation aussi précise que possible et le contrôle des courants des inducteurs sont nécessaires. L'étude présentée ici recense dans un premier temps, les quelques solutions existantes dont la puissance est réglée en déplaçant des culasses et/ou des écrans magnétiques, permettant de mieux répartir les champs magnétiques produits, afin de disposer du profil de chauffe souhaité mais pour une faible gamme de tôles. Les rares solutions qui s'intéressent au contrôle électrique sont orientés vers du chauffage monophasé. La transposition directe de ces commandes aux cas multi-bobines ne suffit pas à résoudre le problème dans son intégralité car les inducteurs se perturbent mutuellement. Nous nous sommes donc orientés vers une solution ambitieuse qui permet de s'affranchir de pièces mobiles et rend le système plus fiable, plus précis et lui confère plus de souplesse pour s'adapter à différents profils de chauffe et différentes largeurs de matériaux. Cette solution se base sur une méthode qui consiste à contrôler les profils de chauffe par la seule action sur les courants d'alimentation des inducteurs tout en maitrisant les échanges d'énergie entre les inducteurs fortement couplés. Cette solution est appliquée sur un prototype construit par EDF. Dans un premier temps, nous avons modélisé le système dans son ensemble tant du point de vue électrique et magnétique que thermique, afin de disposer d'un modèle global simplifié qui permet de mieux en étudier le comportement. Une procédure d'optimisation permet de générer les amplitudes et les phases des courants inducteurs pour différents profils de chauffe. Après une étape d'identification paramétrique, nous avons défini et implanté un modèle simplifié dans le logiciel PSim, qui nous fournit des délais de simulation relativement courts. Les résultats obtenus ont été ensuite comparés à des expérimentations en boucle ouverte tout d'abord, qui nous ont conduits à une étude de sensibilité des grandeurs du système aux variations paramétriques. Il nous a été possible de commander le système grâce à un FPGA dans lequel nous avons implanté une commande numérique pour le contrôle des courants des inducteurs en vue du chauffage en statique d'un disque de tôle pour différents profils de consigne. Nous avons ensuite amélioré nos modèles dans différentes directions, par la prise en compte du rayonnement et de la conduction thermique, en les transposant à un système plus complexe à six phases et avec une prise en compte du défilé des matériaux. L'extension du principe de l'induction multi-bobines de 3 à 6 phases a révélé de fortes perturbations harmoniques des courants des inducteurs. Notre travail a permis de maîtriser les harmoniques en choisissant judicieusement les angles de commande et de caractériser les pertes dans les onduleurs. / Induction heating is a process that consists in immersing an electrically conductive material in a variable magnetic field, thus having the effect to create FEM and then eddy currents flow which heat up the material by Joule effect. This heating method is already established in many industrial sectors such as smelters and fits well in materials processing due to various advantages. In fact it allows particular achievement with very high power densities whose distribution can be controlled. It is then possible to obtain localized or complete heating subsequent to the desired treatment. This flexibility of temperature profile control and high power heating traditionally require the use of systems with multiple coils. For that, characterization as accurate as possible and currents control of the inductors are needed. As a first step, the present study identifies the few existing solutions whose power adjustment is made by moving magnetic yokes and / or magnetic screens. These adjustments allow a better distribution of magnetic fields produced in order to achieve the desired heating profile, but for a small range of metal sheet. The existing few works interested in electrical control solutions are geared toward single phase heating. Direct transposition of these commands in multi-coil case is not sufficient to solve the problem in its entirety because the coils have mutual influence. We therefore directed towards an ambitious solution that cancels the need of moving parts and makes the system more reliable, more accurate and gives more flexibility for adaption to different heating profiles and material widths. This solution is based on a method of controlling the heating profile by acting on coils currents while mastering the energy exchange between the strongly coupling of the inductors. This solution was applied on a prototype built by EDF. We modeled the whole system considering electrical, magnetic and thermal parts, in order to provide a global simplified model to better study the system behavior. An optimization procedure leads to coils current amplitudes and phase shift calculation for different heating profiles. After a parametric identification step, we defined and implemented a simplified model in PSIM software, which provides relatively short simulation times. The results were then compared to experiments in open loop first and led to a sensitivity analysis of the magnitudes of the system to parametric variations. The system control was made by an FPGA in which we implemented a digital command program for controlling inductors currents. It was thus possible to perform a static metal disc heating with different profiles. We then improved our models in different directions, by taking into account the radiation and heat conduction, transposing them to a more complex system with six phases for moving sheet heating. The extension of the principle of multi-phases induction heating from three to six phases showed high harmonic disturbances of inductors currents. Our work has helped to control harmonics by choosing judicious control angles; we also characterize the inverters losses. Modélisation Chauffage par induction Commande Couplage Induction heating Modelling Magnetic coupling Control
23	Microfabricated Devices For DNA Analysis Pal, Debjani 01 1900 (has links) (PDF) No description available. DNA - Microelectronic Devices Microelectronic Devices DNA Analysis Microchip Thermocycler Induction-Heating Microfabricated Devices Environmental Chemistry
24	Modelling, Simulation And Design Of A Single Switch Resonant Inverter For Induction Heating Lakshminarayanan, Sanjay 11 1900 (has links) (PDF) No description available. Converters - Inverters Electric Heating -Induction Single Switch Resonant Inverter Induction Heating Inverters Electrical Engineering
25	Optimalizace technologie perlitizace masivních vývalků / Optimization of heat treatement for steel beams Dyčka, Martin January 2017 (has links) This thesis deals with heat treatment of pearlitic steel beams with using of induction heating. The aim of this heat treatment is to improve mechanical properties of steel beams. In theoretical part are described pearlitic steels and theory of induction heating. In experimental part of this thesis analysis of current state of technology with its results was made. Numerical model describing current state of technology was assembled. Then this model was used to recommend adjustments in current technology of heat treatment, which leads to enlargement of heat treated depth. Experiments with adjusted parameters were executed on heat treating machine. Analysis of microstructure using LM and EM, measurement of hardness and fractographic analysis were done. The result of adjustments is enlargement of heat treated depth about half compared with current technology.
26	Měnič pro indukční ohřev / Induction heater converter Holcman, Marek January 2020 (has links) This thesis deals with the design of a power converter for induction heating of iron components designed for a power of at least 2.5 kW. The induction furnace forms a series resonant LC circuit. The thesis contains a description and a design of individual parts of the converter, including wiring diagrams and a design of printed circuit boards. At the end of the work are then described the mechanical construction, the course of recovery and testing the operation of the inverter.
27	Zařízení pro Indukční ohřev pro účely uměleckého kovářství / Induction heating apparatus for artistic blacksmithing purposes Šmarda, Vladislav January 2020 (has links) This Diploma thesis deals with the design of induction heating inverter. The main subject is optimalization for blacksmiths. There is described the designing procedure for power components and also designing of control part. Then prototype of 10 kW induction heater was made.
28	Návrh regulovatelného ohřevu spřádací hlavy a dohřevu vláken s řízeným prouděním vzduchu pro zařízení k odstředivému spřádání nanovláken / Design of controllable heating of the spinning head and reheating of fibers with controlled air flow for devices for centrifugal spinning of nanofibers Janošík, Lukáš January 2021 (has links) This Master thesis deals with the design and implementation of the spinning head heating for the fibers manufacturing. The first part of this thesis compares the problems of spinning head heating by means of radiant heat and electromagnetic induction. The next part of the thesis deals with the design and implementation of the selected induction heating of the spinning head together with its partial peripherals. The thesis continues with the design of a controlled air flow through the chambre and design of reheating fibers. In the following part of the thesis, functionality tests and partial measurements are performed on the device. At the end, the measurement results are evaluated and compared.
29	Zařízení pro indukční ohřev s výkonem 2,5kW / Device for induction heating with a power of 2,5kW Krist, Petr January 2014 (has links) This thesis deals with designing of an induction heating of small iron parts. This device should be primarily designed for a farrier practice or an artistic blacksmithing. Considering the practice, the referential heated iron part will be a horseshoe. The basis of this device is a power inverter with serial resonant circuit connected to inverter as a load. This thesis contains designing and development of electrical and mechanical parts of whole device. It means control circuits, resonant circuit, box for heated part, etc. At the end of this thesis is realization of the device, electrifying, optimization and testing. During the test the horseshoe was heated close to demanded temperature.
30	Development of Structural Steel Components Partially Strengthened by Induction Heating / 高周波誘導加熱により部分高強度化された鋼構造部材の開発 Liu, Yuan 23 March 2023 (has links) 京都大学 / 新制・課程博士 / 博士(工学) / 甲第24578号 / 工博第5084号 / 新制\|\|工\|\|1974(附属図書館) / 京都大学大学院工学研究科建築学専攻 / (主査)教授西山峰広, 教授聲高裕治, 准教授倉田真宏 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM Induction heating High-strength steel Brace Partial strengthening Curve shape 500

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