G. Avrillaud scite author profile

High power pulsed electrical discharges into liquids are investigated for new industrial applications based on the efficiency of controlled shock waves. We present here new experimental data obtained by combination of detailed high speed imaging equipments. It allows the visualization of the very first instants of plasma discharge formation, and then the pulsations of the gaseous bubble with an accurate timing of events. The time history of the expansion/compression of this bubble leads to an estimation of the energy effectively transferred to water during the discharge. Finally, the consecutive shock generation driven by this pulsating bubble is optically monitored by shadowgraphs and schlieren setup. These data provide essential information about the geometrical pattern and chronometry associated with the shock wave generation and propagation.

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Niobium superconducting rf cavity fabrication by electrohydraulic forming

Cantergiani

Atieh

Léaux

et al. 2016

Phys. Rev. Accel. Beams

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Superconducting rf (SRF) cavities are traditionally fabricated from superconducting material sheets or made of copper coated with superconducting material, followed by trim machining and electron-beam welding. An alternative technique to traditional shaping methods, such as deep-drawing and spinning, is electrohydraulic forming (EHF). In EHF, half-cells are obtained through ultrahigh-speed deformation of blank sheets, using shockwaves induced in water by a pulsed electrical discharge. With respect to traditional methods, such a highly dynamic process can yield interesting results in terms of effectiveness, repeatability, final shape precision, higher formability, and reduced springback. In this paper, the first results of EHF on high purity niobium are presented and discussed. The simulations performed in order to master the multiphysics phenomena of EHF and to adjust its process parameters are presented. The microstructures of niobium halfcells produced by EHF and by spinning have been compared in terms of damage created in the material during the forming operation. The damage was assessed through hardness measurements, residual resistivity ratio (RRR) measurements, and electron backscattered diffraction analyses. It was found that EHF does not worsen the damage of the material during forming and instead, some areas of the half-cell have shown lower damage compared to spinning. Moreover, EHF is particularly advantageous to reduce the forming time, preserve roughness, and to meet the final required shape accuracy.

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GEPI : An Ice Generator for Dynamic Material Characterisation and Hypervelocity Impact

Héreil¹,

Lassalle²,

Avrillaud³

2004

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A coupled experimental/numerical approach for the characterization of material behaviour at high strain-rate using electromagnetic tube expansion testing

Jeanson¹,

Bay²,

Jacques³

et al. 2016

International Journal of Impact Engineering

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G. Avrillaud

High-Velocity Flyer-Plate Developments on Two High-Pulsed-Power Generators Based on a Strip-Line Design (GEPI and CEPAGE)

Experimental characterization of plasma formation and shockwave propagation induced by high power pulsed underwater electrical discharge

Niobium superconducting rf cavity fabrication by electrohydraulic forming

GEPI : An Ice Generator for Dynamic Material Characterisation and Hypervelocity Impact

A coupled experimental/numerical approach for the characterization of material behaviour at high strain-rate using electromagnetic tube expansion testing

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