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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Fibre-optic laser Doppler velocimetry

Pannell, C. N. January 1988 (has links)
No description available.
2

Vertical annular flow : the effects of physical properties

Jepson, D. M. January 1992 (has links)
No description available.
3

Fracture and flow in normal and anomalous glasses

Bache, M. R. January 1988 (has links)
No description available.
4

Hur kan jag komma närmare det intuitiva spelet? : En studie om att förena improvisationsövning med trumpetmetodik

Jonsson, Linnea January 2021 (has links)
In this thesis I have explored how to combine improvisation with technical trumpet studies by creating exercises that are based on my compositions. The goal was to develop a uniform practice routine in order to become more free as an improviser. This semester I have had the benefit to have Ingrid Jensen as a trumpet teacher and therefore the process is mainly inspired by her experience and advice. I have found new tools to incorporate in my practice routine such as practicing to a drone and applying Flow studies on self-composed phrases. I have not only noticed a difference in my playing, but also realized the importance of giving yourself time to make progress. / <p>Wheels, Fragments of Spring, New Beginnings, Morning Light, Hymn of the Forest (Linnea Jonsson är kompositör på samtliga låtar)</p><p>Medverkande:</p><p>Linnea Jonsson, trumpet</p><p>Britta Virves, piano</p><p>Bjarni Ingólfsson, gitarr</p><p>Ingrid Schyborger, kontrabas</p><p>Kristian Remnelius, trummor</p>
5

A theoretical and experimental investigation of the flow performance of automotive catalytic converters

Haimad, N. January 1997 (has links)
Considerable research is being carried out into the parameters that affect catalyst performance in order to meet the latest emission regulations. The conversion efficiency and the durability of automotive catalytic converters are significantly dependent on catalyst flow performance. Related investigations are commonly conducted using CFD techniques which represent an inexpensive and fast alternative to experimental methods. This thesis focuses on the flow performance of automotive catalytic converters using both experimental and computational techniques. The work describes the effects of inlet flow conditions on catalyst performance, the application of radial vanes to catalyst systems and the refinement of the CFD flow model which increases the accuracy of the predicted catalyst flow performance. the effects of inlet flow conditions on the flow maldistribution across the catalyst face and the total pressure loss through the system were assessed using a steady air flow rig. Tests were conducted over a range of Reynolds numbers typically encountered in automotive catalytic converters using a uniform and a fully-developed inlet flow condition. The results showed that the flow maldistribution significantly increases with Reynolds number notably in wide-angled diffusers. The catalyst flow performance is considerably improved when the inlet flow is uniform rather than fully-developed, the non-dimensional total pressure loss is reduced by 8% at Re=60000 and the flow maldistribution across the catalyst face is decreased by 12.5% and 15% respective Reynolds numbers of 30000 and 60000 when using a 60 degree diffuser. The total pressure loss through the system was found to be mostly associated with the monolith brick resistance. When the flow maldistribution is approximately 2, the pressure loss across the monolith brick represents 80% of the system pressure loss. The flow maldistribution across the catalyst face was improved by locating a system of radial splitters in the diffuser. The optimum flow performance was found to be a complex function of the vane design. A maximum improvement in the flow maldistrution indices M and Mi of 25% and 50% respectively was achieved at the expense of an increase in total pressure loss of 13.5% at Re = 60000. Both CFD and flow visualisation techniques were used as an aid to interpreting the flow field in the diffuser. Although a qualitative agreement was obtained using CFD, the flow maldistribution across the catalyst face was underpredected by up to 20%. The accuracy of the flow predictions was significantly improved by investigating the flow field in the monolith channels. Flow recirculation occurs in the channel entry length when the flow approaches the monolith channels at an angle which induces an additional implemented into four models of the flow through axisymmetric catalyst assemblies using various diffuser geometries and inlet flow conditions. By including the flow entrance effects in the porous media approach, the flow maldistribution was predicted within 8% instead of 15% when these effects are neglected. Further investigation of the flow in the monolith channels will be required to accurately model three-dimentional flows (racetrack catalysts) and to include various channel geometries and system flow rates.

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