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MEMS-enabled micro-electro-discharge machining (M³EDM)Alla Chaitanya, Chakravarty Reddy 11 1900 (has links)
A MEMS-based micro-electro-discharge machining technique that is enabled by the
actuation of micromachined planar electrodes defined on the surfaces of the workpiece is
developed that eliminates the need of numerical control machines. First, the planar
electrodes actuated by hydrodynamic force is developed. The electrode structures are
defined by patterning l8-µm-thick copper foil laminated on the stainless steel workpiece
through an intermediate photoresist layer and released by sacrificial etching of the resist layer.
The planer electrodes are constructed to be single layer structures without particular features
underneath. All the patterning and sacrificial etching steps are performed using dry-film
photoresists towards achieving high scalability of the machining technique to large-area
applications. A DC voltage of 80-140 V is applied between the electrode and the workpiece
through a resistance-capacitance circuit that controls the pulse energy and timing of spark
discharges. The parasitic capacitance of the electrode structure is used to form a resistance
capacitance circuit for the generation of pulsed spark discharge between the electrode and the
workpiece. The suspended electrodes are actuated towards the workpiece using the
downflow of dielectric machining fluid, initiating and sustaining the machining process.
Micromachining of stainless steel is experimentally demonstrated with the machining voltage
of 90V and continuous flow of the fluid at the velocity of 3.4-3.9 m/s, providing removal
depth of 20 µm. The experimental results of the electrode actuation match well with the
theoretical estimations. Second, the planar electrodes are electrostatically actuated towards
workpiece for machining. In addition to the single-layer, this effort uses double-layer
structures defined on the bottom surface of the electrode to create custom designed patterns
on the workpiece material. The suspended electrode is electrostatically actuated towards the
wafer based on the pull-in, resulting in a breakdown, or spark discharge. This instantly
lowers the gap voltage, releasing the electrode, and the gap value recovers as the capacitor is
charged up through the resistor. Sequential pulses are produced through the self-regulated
discharging-charging cycle. Micromachining of the stainless-steel wafer is demonstrated
using the electrodes with single-layer and double-layer structures. The experimental results
of the dynamic built-capacitance and mechanical behavior of the electrode devices are also
analyzed.
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MEMS-enabled micro-electro-discharge machining (M³EDM)Alla Chaitanya, Chakravarty Reddy 11 1900 (has links)
A MEMS-based micro-electro-discharge machining technique that is enabled by the
actuation of micromachined planar electrodes defined on the surfaces of the workpiece is
developed that eliminates the need of numerical control machines. First, the planar
electrodes actuated by hydrodynamic force is developed. The electrode structures are
defined by patterning l8-µm-thick copper foil laminated on the stainless steel workpiece
through an intermediate photoresist layer and released by sacrificial etching of the resist layer.
The planer electrodes are constructed to be single layer structures without particular features
underneath. All the patterning and sacrificial etching steps are performed using dry-film
photoresists towards achieving high scalability of the machining technique to large-area
applications. A DC voltage of 80-140 V is applied between the electrode and the workpiece
through a resistance-capacitance circuit that controls the pulse energy and timing of spark
discharges. The parasitic capacitance of the electrode structure is used to form a resistance
capacitance circuit for the generation of pulsed spark discharge between the electrode and the
workpiece. The suspended electrodes are actuated towards the workpiece using the
downflow of dielectric machining fluid, initiating and sustaining the machining process.
Micromachining of stainless steel is experimentally demonstrated with the machining voltage
of 90V and continuous flow of the fluid at the velocity of 3.4-3.9 m/s, providing removal
depth of 20 µm. The experimental results of the electrode actuation match well with the
theoretical estimations. Second, the planar electrodes are electrostatically actuated towards
workpiece for machining. In addition to the single-layer, this effort uses double-layer
structures defined on the bottom surface of the electrode to create custom designed patterns
on the workpiece material. The suspended electrode is electrostatically actuated towards the
wafer based on the pull-in, resulting in a breakdown, or spark discharge. This instantly
lowers the gap voltage, releasing the electrode, and the gap value recovers as the capacitor is
charged up through the resistor. Sequential pulses are produced through the self-regulated
discharging-charging cycle. Micromachining of the stainless-steel wafer is demonstrated
using the electrodes with single-layer and double-layer structures. The experimental results
of the dynamic built-capacitance and mechanical behavior of the electrode devices are also
analyzed.
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MEMS-enabled micro-electro-discharge machining (M³EDM)Alla Chaitanya, Chakravarty Reddy 11 1900 (has links)
A MEMS-based micro-electro-discharge machining technique that is enabled by the
actuation of micromachined planar electrodes defined on the surfaces of the workpiece is
developed that eliminates the need of numerical control machines. First, the planar
electrodes actuated by hydrodynamic force is developed. The electrode structures are
defined by patterning l8-µm-thick copper foil laminated on the stainless steel workpiece
through an intermediate photoresist layer and released by sacrificial etching of the resist layer.
The planer electrodes are constructed to be single layer structures without particular features
underneath. All the patterning and sacrificial etching steps are performed using dry-film
photoresists towards achieving high scalability of the machining technique to large-area
applications. A DC voltage of 80-140 V is applied between the electrode and the workpiece
through a resistance-capacitance circuit that controls the pulse energy and timing of spark
discharges. The parasitic capacitance of the electrode structure is used to form a resistance
capacitance circuit for the generation of pulsed spark discharge between the electrode and the
workpiece. The suspended electrodes are actuated towards the workpiece using the
downflow of dielectric machining fluid, initiating and sustaining the machining process.
Micromachining of stainless steel is experimentally demonstrated with the machining voltage
of 90V and continuous flow of the fluid at the velocity of 3.4-3.9 m/s, providing removal
depth of 20 µm. The experimental results of the electrode actuation match well with the
theoretical estimations. Second, the planar electrodes are electrostatically actuated towards
workpiece for machining. In addition to the single-layer, this effort uses double-layer
structures defined on the bottom surface of the electrode to create custom designed patterns
on the workpiece material. The suspended electrode is electrostatically actuated towards the
wafer based on the pull-in, resulting in a breakdown, or spark discharge. This instantly
lowers the gap voltage, releasing the electrode, and the gap value recovers as the capacitor is
charged up through the resistor. Sequential pulses are produced through the self-regulated
discharging-charging cycle. Micromachining of the stainless-steel wafer is demonstrated
using the electrodes with single-layer and double-layer structures. The experimental results
of the dynamic built-capacitance and mechanical behavior of the electrode devices are also
analyzed. / Applied Science, Faculty of / Electrical and Computer Engineering, Department of / Graduate
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Optimisation d’un procédé d’usinage par microélectroérosion / Optimization of micro electrical discharge machiningDahmani, Rabah 06 May 2015 (has links)
L’objet de cette thèse est d’étudier un procédé de fraisage par microélectroérosion (μEE), qui est un procédé sans contact permettant d’usiner tous les matériaux durs conducteurs d’électricité à l’aide d’un micro-outil cylindrique ultrafin. Le principe consiste à créer des micro-décharges électriques entre le micro-outil et une pièce conductrice immergés dans un diélectrique liquide. En faisant parcourir à l’outil un parcours 3D, il est possible de creuser une forme complexe dans la pièce avec des détails à fort rapport d’aspect. Dans ce travail, nous avons tout d’abord amélioré un procédé d’élaboration de microoutils cylindriques ultrafins par gravure électrochimique de barreaux de tungstène. Des outils de diamètre 32,6 ± 0,3 μm sur une longueur de 3 mm ont été obtenus de manière automatique et reproductible. L’écart type a été divisé par 2 par rapport à l’état de l’art antérieur. Des outils de diamètre inférieur ont été obtenus avec une intervention de l’opérateur, et ce jusqu’à 3 μm de diamètre. Puis ces micro-outils ont été mis en oeuvre pour usiner des pièces avec le procédé de fraisage par microélectroérosion. Pour ce faire, une machine de 2ème génération a été entièrement développée sur la base de travaux antérieurs. Il a été possible d’usiner de l’acier inoxydable dans de l’eau déionisée avec des micro-outils de 3 μm de diamètre sans détérioration de l’outil. Par ailleurs, Le procédé de μEE a été caractérisé en termes de résolution d’usinage, taux d’enlèvement de matière et usure de l’outil. Un générateur de décharges original a permis d’usiner avec des micro-décharges de 1 à 10 nJ / étincelle avec une diminution très sensible de l’usure de l’outil par rapport à l’état de l’art. Un procédé original de caractérisation en ligne des décharges et de cartographie dans l’espace a aussi été développé / This work aims at studying Micro Electrical Discharge Milling (μEDM milling), which is a non-contact process allowing machining all hard and electrically conductive materials with a cylindrical ultrathin tool. The principle is based on the creation of electrical micro discharges between the tool and an electrically conductive part immersed in a liquid dielectric. By means of a 3D path, the tool machines a complex shape in the part with high aspect ratio details. In this work, we have firstly improved a process for making cylindrical ultrathin micro-tools by electrochemical etching of tungsten rods. Tools with a diameter of 32.6 ± 0.3 μm and a length of 3 mm have been obtained with an automated and reproducible process. Standard deviation has been divided by 2 by comparison with the previous state of the art. Tools with diameter as low as 3 μm have been fabricated with the help of the machine operator Then these micro-tools have been used for machining parts with the μEDM milling process. To do so, a second generation machine has been entirely developed on the basis of previous work. It has been possible to machine stainless steel in deionized water with 3 μm micro-tools without damaging the tools. In other respects, the μEDM milling process has been characterized in terms of machining resolution, material removal rate and tool wear. An innovative generator of discharges allow machining with 1 to 10 nJ / spark with a reduced tool wear by comparison to the state of the art. An innovative process for the on line characterization of discharges with spatial distribution capability has been developed
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