Abstract
We evaluate the energy conversion efficiency of an electrical exploding foil accelerator that accelerates a thin dielectric foil (called the flyer) to more than 1 km/s, which is propelled by electrically exploded bridge material. The effective flyer mass ejected from the accelerator is estimated by impulse measurements obtained using a gravity pendulum as well as by time-resolving flyer velocity measurements obtained using a photonic Doppler velocimetry system. For two different bridge sizes (0.2 and 0.4 mm), the flyer velocity and impulse increase with the input energy at the bridge section. The maximum flyer velocity and impulse, that is, 4.0 km/s and 67 µN s, respectively, are obtained by supplying 0.33 J of input energy. Upon increasing the input energy, the effective flyer mass also increases and exceeds the designed-bridge mass for both bridge sizes. The energy conversion efficiency from input electrical energy to flyer kinetic energy is calculated based on the effective flyer mass, velocity, and input energy. Both bridge sizes show comparable efficiencies: 27% and 30% for 0.2 and 0.4 mm bridges, respectively. The efficiency increases with increasing specific input energy at least up to 15 MJ/kg for the 0.4 mm bridge, whereas the efficiency of the 0.2 mm bridge above 30 MJ/kg decreases. This is owing to the excessively high input energy density in the 0.2 mm bridge, which causes the effective flyer mass to increase by including surrounding materials. These results indicate that the specific input energy should be optimized for obtaining maximum efficiency.
Highlights
An electrical exploding foil accelerator is a unique smallscale device for accelerating a thin dielectric foil to high velocities (∼20 km/s1)
We quantitatively investigated the energy conversion efficiency of an electrical exploding foil accelerator for two different bridge sizes (0.2 and 0.4 mm square) based on the flyer velocity and induced impulse measurements
The effective explodedbridge mass calculated from the velocity and impulse data increased with input energy and was up to 2.5 times greater than that of the designed-bridge mass
Summary
An electrical exploding foil accelerator is a unique smallscale device for accelerating a thin dielectric foil to high velocities (∼20 km/s1). The flyer terminal velocity of a given material and/or electrical configuration and the conversion efficiency of input energy to material acceleration are essential considerations.. Rigorous modeling of the flyer acceleration by bridge explosion typically involves the use of a hydrocode with detonation equations.. Few studies have quantitatively investigated the energy conversion efficiency of the flyer acceleration process.. We use a gravity pendulum-type impulse stand, which is typically used in space propulsion research.. We use a gravity pendulum-type impulse stand, which is typically used in space propulsion research.14 Combining this measurement with the velocity measurement obtained using a PDV system, the correlation between the specific input energy and flyer kinetic energy for two different bridge sizes is described and discussed with respect to the input electrical energy
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