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Etude et réalisation d'une micropompe et de microvalves intégrées tout siliciumSBIAA, Zouhair 30 January 1997 (has links) (PDF)
Les domaines du génie biologique et médicale sont considérés, à terme, comme l'un des secteurs privilégiés d'application des microsystèmes. Le sujet de thèse consiste en la conception et la réalisation d'une unité d'analyse chimique comprenant une micropompe actionnée par une résistance thermique dont le rôle est de permettre l'acheminement d'un fluide vers un multi-capteur d'analyse physico-chimique (pression, ISFET, température,...). Le projet européen Barmint (1) nous sert de support dans la conception et la réalisation d'un démonstrateur intégrant notamment les composants ci-dessus. L'originalité d'un tel procédé est de réaliser, sur un même substrat de silicium poli double face, une membrane (micro-usinée grâce à une solution chimique) et de deux microvalves à sens unique qui contrôlent l'entrée et la sortie du fluide. Ces valves sont obtenues après dépôts LPCVD et gravures par plasma du silicium polycristallin. Nous aborderons en détails toutes les étapes technologiques de réalisation de la micropompe et des microvalves. Nous nous intéresserons surtout aux problèmes de compatibilités de ces technologies avec les techniques VLSI. La réalisation d'un démonstrateur sera présentée. Les aspects simulations et modélisations thermiques et mécaniques de la micropompe seront abordes pour l'optimisation . Ce travail ouvre des perspectives quant à la conception et la réalisation de futurs microsystèmes pour des applications spatiales, médicales.
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Modeling of frictional gas flow in a piezoelectrically actuated high-pressure microvalve for flowrate controlJohnson, Christopher Alan, January 2005 (has links) (PDF)
Thesis(M.S.)--Auburn University, 2005. / Abstract. Vita. Includes bibliographic references.
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Heterogeneous Integration of Shape Memory Alloysfor High-Performance MicrovalvesGradin, Henrik January 2012 (has links)
This thesis presents methods for fabricating MicroElectroMechanical System (MEMS) actuators and high-flow gas microvalves using wafer-level integration of Shape Memory Alloys (SMAs) in the form of wires and sheets. The work output per volume of SMA actuators exceeds that of other microactuation mechanisms, such as electrostatic, magnetic and piezoelectric actuation, by more than an order of magnitude, making SMA actuators highly promising for applications requiring high forces and large displacements. The use of SMAs in MEMS has so far been limited, partially due to a lack of cost efficient and reliable wafer-level integration approaches. This thesis presents new methods for wafer-level integration of nickel-titanium SMA sheets and wires. For SMA sheets, a technique for the integration of patterned SMA sheets to silicon wafers using gold-silicon eutectic bonding is demonstrated. A method for selective release of gold-silicon eutectically bonded microstructures by localized electrochemical etching, is also presented. For SMA wires, alignment and placement of NiTi wires is demonstrated forboth a manual approach, using specially built wire frame tools, and a semiautomatic approach, using a commercially available wire bonder. Methods for fixing wires to wafers using either polymers, nickel electroplating or mechanical silicon clamps are also shown. Nickel electroplating offers the most promising permanent fixing technique, since both a strong mechanical and good electrical connection to the wire is achieved during the same process step. Resistively heated microactuators are also fabricated by integrating prestrained SMA wires onto silicon cantilevers. These microactuators exhibit displacements that are among the highest yet reported. The actuators also feature a relatively low power consumption and high reliability during longterm cycling. New designs for gas microvalves are presented and valves using both SMA sheets and SMA wires for actuation are fabricated. The SMA-sheet microvalve exhibits a pneumatic performance per footprint area, three times higher than that of previous microvalves. The SMA-wire-actuated microvalve also allows control of high gas flows and in addition, offers benefits of lowvoltage actuation and low overall power consumption. / QC 20120514
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Wafer-level heterogeneous integration of MEMS actuatorsBraun, Stefan January 2010 (has links)
This thesis presents methods for the wafer-level integration of shape memory alloy (SMA) and electrostatic actuators to functionalize MEMS devices. The integration methods are based on heterogeneous integration, which is the integration of different materials and technologies. Background information about the actuators and the integration method is provided. SMA microactuators offer the highest work density of all MEMS actuators, however, they are not yet a standard MEMS material, partially due to the lack of proper wafer-level integration methods. This thesis presents methods for the wafer-level heterogeneous integration of bulk SMA sheets and wires with silicon microstructures. First concepts and experiments are presented for integrating SMA actuators with knife gate microvalves, which are introduced in this thesis. These microvalves feature a gate moving out-of-plane to regulate a gas flow and first measurements indicate outstanding pneumatic performance in relation to the consumed silicon footprint area. This part of the work also includes a novel technique for the footprint and thickness independent selective release of Au-Si eutectically bonded microstructures based on localized electrochemical etching. Electrostatic actuators are presented to functionalize MEMS crossbar switches, which are intended for the automated reconfiguration of copper-wire telecommunication networks and must allow to interconnect a number of input lines to a number of output lines in any combination desired. Following the concepts of heterogeneous integration, the device is divided into two parts which are fabricated separately and then assembled. One part contains an array of double-pole single-throw S-shaped actuator MEMS switches. The other part contains a signal line routing network which is interconnected by the switches after assembly of the two parts. The assembly is based on patterned adhesive wafer bonding and results in wafer-level encapsulation of the switch array. During operation, the switches in these arrays must be individually addressable. Instead of controlling each element with individual control lines, this thesis investigates a row/column addressing scheme to individually pull in or pull out single electrostatic actuators in the array with maximum operational reliability, determined by the statistical parameters of the pull-in and pull-out characteristics of the actuators. / QC20100729
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