The Shahre Javan Community Detailed Plan : Planning for a Climate Responsive and Sustainable Iranian Urban Quarter

Zugleich gedruckt veröffentlicht im Universitätsverlag der TU Berlin unter der ISBN 978-3-7983-2451-0.This report presents the major accomplishments of the ‘Shahre Javan Community’ pilot project as the main pilot project of the German-Iranian Young Cities research project,. ‘Shahre Javan’ is Farsi and stands for ‘Young City’. The pilot project uses an integrated planning and research process to explore aspects of energy and resource efficiency, climate and environmentally conscious solutions for urban form, architecture, landscape planning, transportation planning, water and energy management, and environmental assessment. It is about the upgraded Iranian detailed plan (‘Tarh-e Tafsili’) for a nearly 45 ha large pilot project area in the southern part of the Hashtgerd New Town, Iran. It includes innovations derived during the strategically integrative urban development and research process, in an effort to reach more climate responsive and more sustainable urban development. Thus, several of the presented solutions go above and beyond the standard content of an Iranian detailed plan. Hence, this publication does not present the or an approved formal Iranian detailed plan. Rather, it combines a reflection of research background, approach, and process with a kind of a hybrid detailed plan report which includes common Iranian detailed plan contents and new and innovative elements as well as research findings going beyond the detailed plan scale and content. Printed Version published by Universitätsverlag der TU Berlin (www.univerlag.tu-berlin.de), ISBN 978-3-7983-2451-

Flow Pattern and Heat Transfer in a Cylindrical Annulus Under 1 g and Low-g Conditions: Experiments

International audienceWe investigate the thermal convection in an annular cavity, with differentially heated inner and outer cylinders, under the influence of a dielectrophoretic (DEP) force. Applying a temperature gradient to a liquid creates buoyancy driven thermal convection. When additionally a radially acting DEP-force is applied by means of an alternating electric field, the pattern of this convective flow changes which also leads to a change in the heat transfer. Depending on the parameters, e.g. an axisymmetric structure with toroidal vortices appears. Another possible structure are columnar vortices, which extend through the annulus. To isolate the effect of the DEP-force, this experiment is not only conducted in the laboratory, but also in microgravity conditions during parabolic flights. By using DEP-induced convective flows in microgravity a comparable heat transfer as with buoyancy convection under Earth’s condition can be obtained. A better understanding of the heat transport mechanisms inside a dielectric liquid confined between two concentric cylinders can deliver solutions for the improvement of the heat transport in many technical applications

Taylor-Couette flow with asymmetric end-walls boundary conditions

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Study of transitional and turbulent flows in rotor/stator cavities

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Dielectrically driven convection in spherical gap geometry

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Flow Patterns and Heat Transfer in a Cylindrical Annulus under 1g and low-g Conditions: Theory and Simulation

International audienceA dielectric fluid is confined in a stationary vertical cylindrical annulus. A temperature difference is applied between the two cylinders, as well as an alternating electric potential. This configuration creates an active force called dielectrophoretic force, which acts as a thermal buoyancy force. Different axial gravity intensities are considered, so that two thermal buoyancies will affect the flow: the thermoelectric buoyancy intervenes in the radial direction and the Archimedean buoyancy acts in the axial direction. Linear stability analysis and direct numerical simulation are performed following experimental research that has been performed during parabolic flight campaigns