1,162 research outputs found
A NASTRAN investigation of simulated projectile damage effects on a UH-1B tail boom model
A NASTRAN model of a UH-1B tail boom that had been designed for another project was used to investigate the effect on structural integrity of simulated projectile damage. Elements representing skin, and sections of stringers, longerons and bulkheads were systematically deleted to represent projectile damage. The structure was loaded in a manner to represent the flight loads that would be imposed on the tail boom at a 130 knot cruise. The deflection of four points on the rear of the tail boom relative to the position of these points for the unloaded, undamaged condition of the tail boom was used as a measure of the loss of structural rigidity. The same procedure was then used with the material properties of the aluminum alloys replaced with the material properties of T300/5208 high strength graphite/epoxy fibrous composite material, (0, + or - 45, 90)s for the skin and (0, + or - 45)s for the longerons, stringers, and bulk heads
VHS notes
https://orc.library.atu.edu/atu_vhs020_2/1004/thumbnail.jp
Generation of pure spin currents by superconducting proximity effect in quantum dots
We investigate electronic transport in a three-terminal hybrid system,
composed by an interacting quantum dot tunnel coupled to one superconducting,
one ferromagnetic, and one normal lead. Despite the tendency of the charging
energy to suppress the superconducting proximity effect when the quantum dot is
in equilibrium, the non-equilibrium proximity effect can give rise to a large
Andreev current. The presence of the ferromagnet can lead to a finite spin
accumulation on the dot. We find that the interplay of the Andreev current and
spin accumulation can generate a pure spin current, with no associated charge
transport, in the normal lead. This situation is realised by tuning the
quantum-dot spectrum by means of a gate voltage.Comment: 6 pages, 5 figure
VHS notes
https://orc.library.atu.edu/atu_vhs017_7/1005/thumbnail.jp
CD notes
https://orc.library.atu.edu/atu_cdda0011/1004/thumbnail.jp
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Control of convection by dfferent buoyancy forces
This paper was presented at the 3rd Micro and Nano Flows Conference (MNF2011), which was held at the Makedonia Palace Hotel, Thessaloniki in Greece. The conference was organised by Brunel University and supported by the Italian Union of Thermofluiddynamics, Aristotle University of Thessaloniki, University of Thessaly, IPEM, the Process Intensification Network, the Institution of Mechanical Engineers, the Heat Transfer Society, HEXAG - the Heat Exchange Action Group, and the Energy Institute.Thermal convection in vertical concentric cylinders under the influence of di erent buoyancy force fields is the focus
of the experimental project ’CiC’(Convection in Cylinders). The objectives are to investigate thermal convective flow in natural gravity with axial buoyancy and in micro-gravity environment of a parabolic flight with radial buoyancy, and additionally also the superposition of both buoyancy force fields. The radial buoyancy is forced by the dielectrophoretic effect due to applying a high-voltage potential Vapp between the two cylinders. The experiment contains two separately fully automated experiment cells, which differ only in their radius ratio η = b/a. The convective flow is observed with tracer particles and laser light sheet illumination. For the case of natural convection, there exists a stable single convective cell over the whole Rayleigh number domain with Ra ~ ΔT with increasing the temperature difference between the inner and outer cylindrical boundaries. For the case of a pure dielectrophoretic driven convection in micro-gravity environment, stratification effects are described with RaE ~ Vapp with increasing the high voltage potential. The superposition of both buoyancy forces indicates the disturbance of the single convective cell and therewith the onset of instabilities at very low Ra for the smaller η. The presented results demonstrate that the dielectrophoretic effect can be used for flow control and enhancement of heat transfer applications in space as well as on Earth.The “Convection in Cylinders (CiC)” project is funded by the German Aerospace Center DLR within the “GeoFlow” project (grant no. 50 WM 0122 and 50 WM 0822). The authors would also like to thank ESA (grant no. AO-99-049) for funding “GeoFlow” and the “GeoFlow” Topical Team (grant no. 18950/05/NL/VJ)
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