471 research outputs found
Nonlinear normal modes of a two degree of freedom oscillator with a bilateral elastic stop
A study of the non linear modes of a two degree of freedom mechanical system
with bilateral elastic stop is considered. The issue related to the
non-smoothness of the impact force is handled through a regularization
technique. In order to obtain the Nonlinear Normal Mode (NNM), the harmonic
balance method with a large number of harmonics, combined with the asymptotic
numerical method, is used to solve the regularized problem. These methods are
present in the software "package" MANLAB. The results are validated from
periodic orbits obtained analytically in the time domain by direct integration
of the non regular problem. The two NNMs starting respectively from the two
linear normal modes of the associated underlying linear system are discussed.
The energy-frequency plot is used to present a global vision of the behavior of
the modes. The dynamics of the modes are also analyzed comparing each periodic
orbits and modal lines. The first NNM shows an elaborate dynamics with the
occurrence of multiple impacts per period. On the other hand, the second NNM
presents a more simple dynamics with a localization of the displacement on the
first mass
PERSISTENT HIGH WATER LEVELS AROUND ANDAMAN & NICOBAR ISLANDS FOLLOWING THE 26 DECEMBER 2004 TSUNAMI
During the tsunami of 26th December 2004 in the Indian Ocean, media reports suggested that high water levels persisted around the Andaman & Nicobar Islands for several days. These persistent high water levels can be explained by invoking the existence of trapped and partially leaky modes on the shelves surrounding these islands. It has been known in the studies of tides in the global oceans, that there are two distinct types of oscillations, separated in their frequencies by the period of the pendulum day. One species are the gravity waves, and the others are the rotational waves, associated with earth's rotation. Both these species can be found in tidal records around islands as well as near coastlines. Essentially these are either trapped or partly leaky modes, partly trapped on the continental shelves. These two types of modes are usually found in the tsunami records on tide gauges. The tide gauge records as well as visual descriptions of the water levels during and after the occurrence of a tsunami clearly show the presence of these oscillations
Novel types of anti-ecloud surfaces
In high power RF devices for space, secondary electron emission appears as
the main parameter governing the multipactor effect and as well as the e-cloud
in large accelerators. Critical experimental activities included development of
coatings with low secondary electron emission yield (SEY) for steel (large
accelerators) and aluminium (space applications). Coatings with surface
roughness of high aspect ratio producing the so-call secondary emission
suppression effect appear as the selected strategy. In this work a detailed
study of the SEY of these technological coatings and also the experimental
deposition methods (PVD and electrochemical) are presented. The coating-design
approach selected for new low SEY coatings include rough metals (Ag, Au, Al),
rough alloys (NEG), particulated and magnetized surfaces, and also graphene
like coatings. It was found that surface roughness also mitigate the SEY
deterioration due to aging processes.Comment: 4 pages, contribution to the Joint INFN-CERN-EuCARD-AccNet Workshop
on Electron-Cloud Effects: ECLOUD'12; 5-9 Jun 2012, La Biodola, Isola d'Elba,
Italy; CERN Yellow Report CERN-2013-002, pp.153-15
Self-trapped electrons and holes in PbBr crystals
We have directly observed self-trapped electrons and holes in PbBr
crystals with electron-spin-resonance (ESR) technique. The self-trapped states
are induced below 8 K by two-photon interband excitation with pulsed
120-fs-width laser light at 3.10 eV. Spin-Hamiltonian analyses of the ESR
signals have revealed that the self-trapping electron centers are the dimer
molecules of Pb along the crystallographic a axis and the
self-trapping hole centers are those of Br with two possible
configurations in the unit cell of the crystal. Thermal stability of the
self-trapped electrons and holes suggests that both of them are related to the
blue-green luminescence band at 2.55 eV coming from recombination of spatially
separated electron-hole pairs.Comment: 8 pages (7 figures, 2 tables), ReVTEX; revised the text and figures
1, 4, and
New Bi-Mode Gate-Commutated Thyristor Design Concept for High-Current Controllability and Low ON-State Voltage Drop
© 2016 IEEE. A new design approach for bi-mode gatecommutated thyristors (BGCTs) is proposed for high-current controllability and low ON-state voltage drop. Using a complex multi-cell mixed-mode simulation model which can capture the maximum controllable current (MCC) of large area devices, a failure analysis was performed to demonstrate that the new design concept can increase the MCC by about 27% at room temperature and by about 17% at 400 K while minimizing the ON-state voltage drop. The simulations depict that the improvement comes from the new approach to terminate the GCT part in the BGCT way of intertwining GCT and diode regions for reverse conducting operation
Novel Approach Toward Plasma Enhancement in Trench-Insulated Gate Bipolar Transistors
In this letter, a trench-insulated gate bipolar transistor (IGBT) design with local charge compensating layers featured at the cathode of the device is presented and analyzed. The superjunction or reduced surface effect proves to be very effective in overcoming the inherited ON-state versus breakdown tradeoff appearing in conventional devices, such as the soft punch through plus or field stop plus (FS+) IGBTs. This design enhances the ON-state performance of the FS+IGBT by increasing the plasma concentration at the cathode side without affecting either the switching performance or the breakdown rating
The Stripe Fortified GCT:A new GCT design for maximizing the controllable current
In this paper we introduce a new GCT design, namely the Stripe Fortified GCT, for the purpose of maximizing the controllable current by optimizing the current flow path in the device during turn-off. The main design of the new device along with variants are introduced. The MCC performance of this novel structure is assessed with a developed two dimensional model for full wafer simulations. Our results show that this new design is a very good candidate for increasing the MCC to values more than 5000A
Numerical simulation of thermal buoyant wall jets
The main focus of this study is on the near field flow and mixing characteristics of the thermal
wall jets. A numerical study of the buoyant wall jets discharged from submerged outfalls from cooling
systems of power plants has hence been conducted. The effects of different RANS (Reynolds-Averaged
Navier-Stokes) turbulence models have been investigated. The standard k-ε, RNG k-ε, realizable k-ε and
SST k-ω turbulence models have been applied in this study. A finite volume method with structured grid
was used to simulate the flow and temperature fields. The results of temperature and velocity fields are
compared to both existing experimental and numerical data. It is found that the realizable k-ε performs the
best among the four investigated turbulence models. According to the results from different simulations,
relationships and comparative graphs are presented which are helpful for a better understanding of
buoyant wall jets.This publication was made possible by NPRP grant # 4-935-2-354 from the Qatar National Research
Fund (a member of Qatar Foundation)
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