1,773 research outputs found
Annular synthetic jet used for impinging flow mass-transfer
An annular synthetic jet was investigated experimentally, both with and without an
opposing impingement wall. The experiments involved smoke visualization and mass
transfer measurement on the wall by means of naphthalene sublimation technique.
Two qualitatively different flow field patterns were identified, depending upon the
driving amplitude level. With small amplitudes, vortical puffs maintain their identity
for a relatively long time. If the amplitudes are large, breakdown and coalescence of
the vortical train is much faster. Also the resultant mass transfer to the impingement
wall is then much higher. Furthermore, a fundamental change of the whole flow field
was observed at the high end of the investigated frequency range, associated with
radical reduction of the size of the recirculation bubble
The near wall effect of synthetic jets in a boundary layer
Copyright @ 2007 Elsevier Inc. All rights reserved.An experimental investigation to analyse the qualitative near wall effect of synthetic jets in a laminar boundary layer has been undertaken for the purpose of identifying the types of vortical structures likely to have delayed separation on a 2D circular cylinder model described in this paper. In the first instance, dye visualisation of the synthetic jet was facilitated in conjunction with a stereoscopic imaging system to provide a unique quasi three-dimensional identification of the vortical structures. Secondly, the impact of synthetic jet structures along the wall was analysed using a thermochromic liquid crystal-based convective heat transfer sensing system in which, liquid crystals change colour in response to the thermal footprints of a passing flow structure. Of the different vortical structures produced as a result of varying actuator operating and freestream conditions, the footprints of hairpin vortices and stretched vortex rings revealed a marked similarity with the oil flow pattern of a vortex pair interacting with the separation line on the cylinder hence suggesting that either of these structures was responsible in delaying separation. Conditions were established for the formation of the different synthetic jet structures in non-dimensional parameter space
Orthostasis test in the practice of the cardiologist
The orthostasis test makes it possible to evaluate neurohumoral regulation and reaction of the circulatory system and to detect changes in the function of a number of internal organs (especially the kidney). Simultaneous recording of the ECG in an orthostatic position despite nonspecificity, makes it possible to detect hidden damage (organic or metabolic) or increased sensitivity of the myocardium to stressor sympathetico-adrenal effects, stability of therapeutic effect, and the action mechanism of a number of drugs
State of gas exchange in recumbent and orthostatic positions and under physical load in healthy persons of varying age, sex and body build
Age effect on gas exchange was studied in the recumbent and orthostatic positions and under physical load. In the case of the older age group and for normal as compared with hypersthenic persons, oxygen consumption during rest and during moderate physical overload diminishes. When the vertical position is assumed oxygen consumption in persons of various age groups is distinctly increased, particularly in the elderly group. There is a reduction in the amount of oxygen consumption, oxygen pulse, recovery coefficient, and work efficiency under moderate overload. In persons over 50, physical labor induces a large oxygen requirement and a sharp rise in the level of lactic acid and the blood's lactate/pyruvate ratio. No distinct difference was noted in the amount of oxygen consumed during rest and during physical overload in men and women of the same physical development and age
An experimental study of a turbulent vortex ring
A turbulent vortex ring having a relatively thin core is formed in water by a
momentary jet discharge from an orifice in a submerged plate. The necessary impulse
is provided by a pressurized reservoir and is controlled by a fast programmable
solenoid valve. The main aim of the research is to verify the similarity properties of
the mean flow, as defined by ensemble averaging, and to find the distribution of mean
vorticity, turbulent energy, and other quantities in the appropriate non-steady
similarity coordinates. The velocity field of the vortex is measured for numerous
realizations with the aid of a two-channel tracking laser-Doppler velocimeter. The
problem of dispersion in the trajectories of the individual rings is overcome by
development of a signature-recognition technique in two variables. It is found that
the turbulence intensity is largest near the vortex core and that at least the radial
component is not negligible in the near wake. The slow growth of the ring structure
is controlled by a slight excess of entrainment over de-entrainment. An important
inference is that the growth process and the process of turbulence production
probably involve secondary vortices wrapped around the core in azimuthal planes
A Conceptual Model of an Intelligent Catalogue Search System (ICSS)
Electronic catalogues are a major tool for developing Electronic Commerce (EC) applications. From a customer’s perspective, however, the variety and heterogeneity of electronic catalogues create a major problem in integrating information from various sources. There have been several attempts to overcome this problem using architectures and protocols that enable interoperabilty of electronic catalogues. The extant architectures and protocols emphasize semantic integration of different catalogues as a mean for achieving interoperability. In this paper we expand the previous work on this topic by proposing a comprehensive agent-based conceptual model of an Intelligent Catalogue Search System (ICSS). The ICSS incorporates knowledge in order to analyze, enhance, filter and synthesize a raw query and replies provided by various electronic catalogues or intercatalogue search systems. The benefit of the proposed architecture is an increase in the capability of a customer to locate and compare relevant products from various sources
A two-grating method for combined beam splitting and frequency shifting in a two-component laser-Doppler velocimeter
The use of a rotating radial phase grating to carry out beam splitting and frequency shifting in a laser-Doppler velocimeter is briefly reviewed. This technique is not new. However, the present design adds a substantial new element by using two overlapping radial gratings to produce a two-channel system in which channel separation can be accomplished by electronic filtering of the signal from a single detector
The Development of Novel, High-Flux, Heat Transfer Cells for Thermal Control in Microgravity
In order to meet the future needs of thermal management and control in space applications such as the Space Lab, new heat-transfer technology capable of much larger heat fluxes must be developed. To this end, we describe complementary numerical and experimental investigations into the fundamental fluid mechanics and heat-transfer processes involved in a radically new, self contained, heat transfer cell for microgravity applications. In contrast to conventional heat pipes, the heat transfer in this cell is based on a forced droplet evaporation process using a fine spray. The spray is produced by a novel fluidic technology recently developed at Georgia Tech. This technology is based on a vibration induced droplet atomization process. In this technique, a liquid droplet is placed on a flexible membrane and is vibrated normal to itself. When the proper drop size is attained, the droplet resonates with the surface motion of the membrane and almost immediately bursts into a shower of very fine secondary droplets. The small droplets travel to the opposite end of the cell where they impact a heated surface and are evaporated. The vapor returns to the cold end of the cell and condenses to form the large droplets that are fragmented to form the spray. Preliminary estimates show that a heat transfer cell based on this technology would have a heat-flux capacity that is an order of magnitude higher than those of current heat pipes designs used in microgravity applications
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