Your search keyword '"Bruschewski, Martin (author)"' showing total 2 results

1. Experimental investigation of shear-induced migration in particle-laden pipe flow using MRI

Author

Hogendoorn, W.J. (author), Frank, David (author), Bruschewski, Martin (author), Poelma, C. (author), Hogendoorn, W.J. (author), Frank, David (author), Bruschewski, Martin (author), and Poelma, C. (author)

Abstract

Using magnetic resonance imaging we are able to obtain average velocity and volume fraction profiles in a pipe flow with a neutrally buoyant suspension. In this experimental work, the effect of increasing Reynolds number and particle volume fraction on shear-induced migration is studied. For increasing bulk volume fraction, the initially nearly homogeneous suspension gradually changes to a strongly non-homogeneous suspension. This is observed for all studied Reynolds numbers. In contrast to the majority of previous (MRI) studies, experiments are also performed for suspension Reynolds numbers of approximately 5000 in order to study inertial effects on shear-induced migration., Multi Phase Systems, Process and Energy

Published

2022

2. Magnetic resonance velocimetry in high‑speed turbulent flows: sources of measurement errors and a new approach for higher accuracy

Author

John, Kristine (author), Jahangir, S. (author), Gawandalkar, U.U. (author), Hogendoorn, W.J. (author), Poelma, C. (author), Grundmann, Sven (author), Bruschewski, Martin (author), John, Kristine (author), Jahangir, S. (author), Gawandalkar, U.U. (author), Hogendoorn, W.J. (author), Poelma, C. (author), Grundmann, Sven (author), and Bruschewski, Martin (author)

Abstract

This study focuses on the measurement accuracy of Magnetic Resonance Velocimetry (MRV) in high-speed turbulent flows. One of the most prominent errors in MRV is the displacement error, which describes the misregistration of spatial coordinates and velocity components in moving fluids. Displacement errors are particularly critical for experiments with high flow velocity and high spatial resolution. The degree of displacement error also depends on the sequence structure of the MRV technique. In this study, two MRV sequence types are examined regarding their measurement capabilities in high-speed turbulent flows: a conventional MRV sequence based on the popular “4D FLOW” technique, and a newly developed sequence, named “SYNC SPI”. Compared to conventional MRV, SYNC SPI is designed for high measurement accuracy, and not for imaging speed, which limits its application to statistically stationary flows. Both sequence types are evaluated in a flow experiment with a converging–diverging nozzle. Time-averaged results are presented for velocities up to 12 m/s at the throat. Supported by Particle Imaging Velocimetry, it is shown that SYNC SPI is capable of acquiring accurate velocity data in these highly turbulent flows. In contrast, the data from the conventional MRV sequence exhibits substantial displacement errors with a maximum displacement of 21 mm. The long acquisition time is the main disadvantage of the SYNC SPI sequence. Therefore, it is examined if undersampling and non-linear reconstruction, known as Compressed Sensing, can be utilized to make data acquisition more efficient. In the presented measurements, Compressed Sensing is successfully applied to shorten the acquisition time by up to 70% with almost no reduction in measurement accuracy., Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Fluid Mechanics, Multi Phase Systems

Published

2020