Aerodynamic Performance of Cables with Spiral Protuberances in Strong Winds / 強風下におけるスパイラル突起付きケーブルの空力特性

Dao, Minh Thu

25 March 2024

京都大学 / 新制・課程博士 / 博士(工学) / 甲第25236号 / 工博第5195号 / 京都大学大学院工学研究科社会基盤工学専攻 / (主査)教授 八木 知己, 教授 KIM Chul-Woo, 教授 高橋 良和 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

circular cylinder

spiral protuberance

drag reduction

wake induced vibrations

wake galloping

dry galloping

500

Spiral ljuddämpare för kompressorer i HVAC-system i bilar

Njim, Ilyan

January 2024

Studiens syfte är att undersöka potentialen och effektiviteten av spiralljuddämpare jämfört med standardljuddämpare för kompressorer i Värme och luftkonditionerings system i bilar. Den ökande efterfrågan på kompakta och effektiva lösningar inom fordonsindustrin, ledde till utforskning av alternativa tekniker som kan bidra till att förbättra bilens prestanda och passagerarkomfort. En ljuddämpartyp som vore intressant att nyttja för denna tillämpning är spiralformade ljuddämpare. Dessa enheter är mer kompakta jämfört med standardljuddämpare, vilket gör dem till ett attraktivt alternativ för biltillverkare som strävar efter att optimera utrymmesanvändningen inom fordonet. Dessutom, tidigare studier visade att spiralformade ljuddämpare kan erbjuda effektiv akustisk dämpning, vilket kan bidra till en mer bekväm och tyst körupplevelse. I denna studie kommer vi att genomföra en omfattande litteraturöversikt över befintliga modeller och prestanda för spiralljuddämpare. Vi kommer sedan att genomföra en jämförande analys mellan spiralformade ljuddämpare och standardljuddämpare en s.k. expansionskammare. Resultaten från denna analys kommer att presenteras och diskuteras i detalj, med syftet att dra slutsatser om effektiviteten av spiralformade ljuddämpare och deras potential för framtida tillämpningar inom fordonsindustrin. Denna studie kommer att genomföras i samarbete med Volvo Cars i Göteborg.

ljuddämpare

spiral

expansionskammare

Herschel Quincke-rör

interfirens

tryckfall.

Engineering and Technology

Teknik och teknologier

Removal of phenol from wastewater using spiral-wound reverse osmosis process: model development based on experiment and simulation

Al-Obaidi, Mudhar A.A.R., Kara-Zaitri, Chakib, Mujtaba, Iqbal

31 May 2017

Yes / The removal of the ubiquitous phenol and phenolic compounds in industrial wastes is a critical environmental issue due to their harmful threats to wildlife and potential adverse human health effects. The removal of such compounds is therefore of significant importance in water treatment and reuse. In recent years, reverse osmosis (RO) has been successfully utilised in several industrial processes and wastewater treatment including phenol removal. In this paper, a new model based on a spiral-wound RO process is developed for the removal of phenol from wastewater. A simplified mathematical algorithm using an irreversible thermodynamic approach is developed. This results in a set of non-linear Differential and Algebraic Equations (DAEs), which are solved based on a number of optimised model parameters using a combined methodology of parameter estimation and experimental phenol-water data derived from the literature. The effects of several operational parameters on the performance (in terms of removal of phenol) of the process are explored using the model.

Wastewater treatment

Spiral-wound reverse osmosis

Distributed model

Irreversible thermodynamic model

Phenol removal

Performance evaluation of multi-stage reverse osmosis process with permeate and retentate recycling strategy for the removal of chlorophenol from wastewater

Al-Obaidi, Mudhar A.A.R., Kara-Zaitri, Chakib, Mujtaba, Iqbal

11 October 2018

Yes / Reverse Osmosis (RO) is one of the most widely used technologies for wastewater treatment for the removal of toxic impurities, such as phenol and phenolic compounds from industrial effluents. In this research, performance of multi-stage RO wastewater treatment system is evaluated for the removal of chlorophenol from wastewater using model-based techniques. A number of alternative configurations with recycling of permeate, retentate, and permeate-retentate streams are considered. The performance is measured in terms of total recovery rate, permeate product concentration, overall chlorophenol rejection and energy consumption and the effect of a number of operating parameters on the overall performance of the alternative configurations are evaluated. The results clearly show that the permeate recycling scheme at fixed plant feed flow rate can remarkably improve the final chlorophenol concentration of the product despite a reduction in the total recovery rate.

Mathematical modelling

Chlorophenol removal

Permeate-retentate recycling design

Performance of reverse osmosis based desalination process using spiral wound membrane: Sensitivity study of operating parameters under variable seawater conditions

Aladhwani, S.H., Al-Obaidi, Mudhar A.A.R., Mujtaba, Iqbal

28 March 2022

Yes / Reverse Osmosis (RO) process accounts for 80% of the world desalination capacity. Apparently, there is a rapid increase of deploying the RO process in seawater desalination due to its high efficiency in removing salts at a reduced energy consumption compared to thermal desalination technologies such as MSF and MED. Among different types of membranes, spiral would membranes is one of the most used. However, there is no in-depth study on the performance of spiral wound membranes in terms of salt rejection, water quality, water recovery and specific energy consumption subject to wide range of seawater salinity, temperature, feed flowrate and pressure using a high fidelity but a realistic process model which is therefore is the focus of this study. The membrane is subjected to conditions within the manufacturer's recommendations. The outcome of this research will certainly help the designers selecting optimum RO network configuration for a large-scale desalination process.

Modelling

Reverse osmosis desalination

Sensitivity analysis

Spiral wound membrane

Variable seawater conditions

Scope and limitations of modelling, simulation, and optimisation of a spiral wound reverse osmosis process-basedwater desalination

Alsarayreh, Alanood A., Al-Obaidi, Mudhar A.A.R., Patel, Rajnikant, Mujtaba, Iqbal

31 March 2022

Yes / The reverse osmosis (RO) process is one of the best desalination methods, using membranes to reject several impurities from seawater and brackish water. To systematically perceive the transport phenomena of solvent and solutes via the membrane texture, several mathematical models have been developed. To date, a large number of simulation and optimisation studies have been achieved to gauge the influence of control variables on the performance indexes, to adjust the key variables at optimum values, and to realise the optimum production indexes. This paper delivers an intensive review of the successful models of theROprocess and both simulation and optimisation studies carried out on the basis of the models developed. In general, this paper investigates the scope and limitations of the RO process, as well as proving the maturity of the associated perspective methodologies.

Modelling

Optimisation

Reverse osmosis process

Simulation

Spiral wound module

Water desalination

Optimierung der koronaren Plaquedarstellung in der Magnetresonanztomographie

Huber, Steffen

02 March 2005

Die Plaqueruptur in der Koronararterie ist nach heutiger Vorstellung Ursache des akute Koronarsyndrom. Ziel der Arbeit war die Optimierung der koronaren Plaquedarstellung in der Magnetresonanztomographie. Um dieses Ziel zu erreichen, wurden zwei spezifische Probleme der koronaren Plaquedarstellung bearbeitet: Erstens die ateminduzierte Herzbewegung und zweitens die hohe Auflösung, die erforderlich ist, um Plaques in den Koronarien darstellen zu können. Die prospektive Navigator-Gating-Technik wird eingesetzt, um ateminduzierte Artefakte der Herzbewegungen zu korrigieren. Die Herzbewegung wird dabei anhand der craniocaudalen Bewegung des Diaphragmas korrigiert. Durch Unterschiedliche Lagerung des Probanden wurde versucht, die Bewegung des Herzens während der Atmung zu minimieren und die anteroposteriore Komponente der Atmung, die nicht korrigiert werden kann, zu unterdrücken. Die Bewegungsmessungen wurden mit Navigatoren durchgeführt. Die extrem hohen Auflösungen die für eine Plaquedarstellung erforderlich sind erzeugen, durch das geringe Volumen was pro Voxel angeregt wird, sehr wenig Signal. Durch den Einsatz der Spiral-Technik kann theoretisch mehr Signal erzeugt werden. Es wurden Plaquedarstellung der Karotiden und der Koronarien in konventioneller Technik und in Spiral -Technik durchgeführt und das Signal und Kontrast zu Rauschverhältnis verglichen. Das Ergebnis der Bewegungsmessung des Herzens war, dass die Rückenlage die beste Lagerungsmethode für die prospektive Navigator-Gating-Technik ist. Die Plaquedarstellung in den Karotiden zeigte ein statistisch signifikant höheres Signal und Kontrast zu Rauschverhältnis in Spiral-Technik als in konventioneller Technik. Eine Plaquedarstellung in den Koronarien war mit einer Auflösung von 0,273mm mal 0,273mm bei einer Schichtdicke von 0,2mm nur in Spiraltechnik möglich. / The main cause of the acute coronary syndrome is plaque rupture. The aim of the study was to optimize magnetic resonance coronary plaque imaging. To achieve this goal tow specific problems of coronary plaque imaging were investigated. First the heart motion during breathing and second the high spatial resolution, which is necessary to display coronary plaque. The prospective navigator gating technique is used in cardiac magnetic resonance to suppress respiratory motion of the heart. The respiratory heart motion is corrected on the basis of the feed to head motion of the diaphragm. Different patient position were tested to suppress the anterior posterior breathing motion of the heart, because this motion component can not be corrected for. The motion measurements were done with navigators. High spatial resolutions result in a low signal. The spiral technique acquires theoretical more signal than standard techniques. Plaque imaging of the carotid arteries and the coronary arteries were done in spiral and in standard technique. The signal to noise were compared for both techniques. The results of the motion measurements of the heart were: the supine position should be preferred in cardiac magnetic resonance imaging. The spiral technique in the carotid arteries had a significant higher signal to noise ration compared to the standard technique. Coronary plaque imaging was only possible in spiral technique, with a resolution of 0.273 times 0.273mm and slice thickness of 0.2mm.

Magnetresonanztomographie

Herz

Plaque

Navigator

Spiral-Technik

Koronararterie

magnetic resonance imaging

plaque

heart

navigator

spiral technique

coronary artery

610 Medizin

33 Medizin

YB 9504

YC 1104

YC 1114

YR 2520

ddc:610

Magnetresonanztomographie, Mehrschicht-Spiral-CT und Elektronenstrahl-CT zur morphologischen und funktionellen Diagnostik der koronaren Herzkrankheit

Rodenwaldt, Jens

27 March 2003

Die Magnetresonanztomographie (MRT), die Mehrschicht-Spiral-Computertomographie (MSCT) und die Elektronenstrahl-Computertomographie (EBCT) sind nichtinvasive diagnostische Verfahren, welche die bisherige kardiale Bildgebung zumindest in Teilbereichen ersetzen oder ergänzen können. MR-Perfusions- und MR-Funktionsuntersuchungen konnten in der vorgelegten Arbeit direkte Parameter der myokardialen Vitalität regional erfassen. Die Signalintensitäten im Blut und im Herzmuskel dienten zur quantitativen Bestimmung der Myokardperfusion. Die Ortsauflösung ermöglichte eine Differenzierung der subendo- und der subepikardialen Durchblutung. Zusätzliche Streßuntersuchungen steigerten die Sensitivität des Verfahrens. Relativ geringgradige Koronarstenosen ließen sich durch vornehmlich subendokardial lokalisierte Perfusionsdefekte nachweisen. MR-Tagging- Funktionsanalysen konnten durch ein artifizielles Markierungsgitter zwischen endokardial lokalisiertem Narbengewebe und epikardial liegendem vitalem Gewebe differenzieren. Die Dehnungen, Stauchungen und Rotationen des Myokardverbandes wurden registriert und ausgewertet. Die MSCT und die EBCT wurden als Röntgenverfahren für die nichtinvasive Koronarangiographie verglichen. Bei der Definition der Gefäßkonturschärfe über die Anstiegssteilheit der CT-Dichtewerte zeigte sich eine bessere Abbildungsqualität der MSCT gegenüber der EBCT. Die Bestimmung der Segmenterkennbarkeit zeigte, dass mit der MSCT signifikant mehr erkannt werden konnten. Die vorgestellten kardialen MR- und CT-Untersuchungen konnten aus Gründen der Reproduzierbarkeit sowie aufgrund des Strahlenschutzes nur tierexperimentell durchgeführt werden. Die Validität der unterschiedlichen Tiermodelle ist in vorausgegangenen Studien belegt worden. Die in der Literatur verfügbaren Ergebnisse am Menschen bestätigen in vieler Weise die vorgelegten Daten. / Magnetic resonance imaging (MRI), multislice spiral computed tomography (MSCT), and electron-beam computed tomography (EBCT) are noninvasive imaging modalities that may supplement or in part even replace established diagnostic procedures for assessment of the heart. MRI perfusion and functional studies were shown to enable determination of direct parameters of regional myocardial vitality. The signal intensities of blood and myocardium served to quantify myocardial perfusion. The spatial resolution allowed for differentiating subendocardial and subepicardial perfusion. Additional stress tests improved the sensitivity of the procedure. Relatively low-grade coronary artery stenoses were identified by the presence of perfusion gaps primarily in subendocardial location. Functional analysis by means of MRI tagging using an artificial grid allowed for differentiating endocardial scar tissue from epicardial vital tissue. Extension, compression, and rotation of the myocardial complex were recorded and analyzed. MSCT and EBCT were compared as radiographic procedures for noninvasive coronary angiography. MSCT was found to be superior to EBCT in terms of image quality defined as vascular contour sharpness determined as the steepness of the increase in CT densities. Assessment of segment identification showed that significantly more segments were visualized by MSCT. The cardiac MRI and CT studies presented here could only be performed in animals because of the radiation exposure involved and to ensure reproducibility of the results. The validity of the different animal models used has been demonstrated in preceding studies. The results of the present animal experiments are in agreement with many of the human data published in the literature.

Magnetresonanztomographie

Kardiovaskuläre Erkrankung

Myokardiale Ischämie

Stenosierte Koronararterien

Cardiovascular disease

Myocardial Ischemia

Magnetic Resonance Imaging

Stenotic Coronary Arteries

610 Medizin

33 Medizin

YB 9500

ddc:610

Studies Of Spiral Turbulence And Its Control In Models Of Cardiac Tissue

Shajahan, T K

02 1900

There is a growing consensus that life-threatening cardiac arrhythmias like ventricular tachycardia (VT) or ventricular fibrillation (VF) arise because of the formation of spiral waves of electrical activation in cardiac tissue; unbroken spiral waves are associated with VT and broken ones with VF. Several experimental studies have shown that inhomogeneities in cardiac tissue can have dramatic effects on such spiral waves. In this thesis we try to understand these experimental results by carrying out detailed and systematic studies of the interaction of spiral waves with different types of inhomogeneities in mathematical models for cardiac tissue. In Chapter 1 we begin with a general introduction to cardiac arrhythmias, the cardiac conduction system, and the connection between electrical activation waves in cardiac tissue and cardiac arrhythmias. As we have noted above, VT and VF are believed to be associated with spiral waves of electrical activation on cardiac tissue; such spiral waves form because cardiac tissue is an excitable medium. Thus we give an overview of excitable media, in which sub-threshold perturbations decay but super-threshold perturbations lead to an action potential that consists of a rapid stage of depolarization of cardiac cells followed by a slow phase of repolarization. During this repolarization phase the cells are refractory. We then give an overview of earlier studies of the effects of inhomogeneities in cardiac tissue; and we end with a brief description of the principal problems we study here. Chapter 2 describes the models we use in our work. We start with a general introduction to the cable equation and then discuss the Hodgkin-Huxley-formalism for the transport of ions across a cell membrane through voltage-gated ion channels. We then describe in detail the three models that we use for cardiac tissue, which are, in order of increasing complexity, the Panfilov model, the Luo Rudy Phase I (LRI) model, and the reduced Priebe Beuckelmann (RPB)model. We then give the numerical schemes we use for solving these model equations and the initial conditions that lead to the formation of spiral waves. For all these models we give representative results from our simulations and compare the states with spiral turbulence. In Chapter 3 we investigate the effects of conduction inhomogeneities (obstacles) in the three models introduced in Chapter 2. We outline first the experimental results that have provided the motivation for our study. We then discuss how we introduce obstacles in our simulations of the Panffilov, LRI, and RPB models for cardiac tissue. Next we present the results of our numerical studies of the effects, on spiral-wave dynamics, of the sizes, shapes, and positions of the obstacles. Our Principal result is that spiral-wave dynamics in these models depends sensitively on the position of the obstacle. We find, in particular, that, merely by changing the position of a conduction inhomogeneity, we may convert spiral turbulence (the analogue in our models of VF) to a single rotating spiral (the analogue of VT) anchored to the obstacle or vice versa; even more exciting is the possibility that, at the boundary between these two types of behaviour, we find a quiescent state Q with no spiral waves. Thus our study obtains all the possible qualitative behaviours found in experiments, namely, (1) VF might persist even in the presence of an obstacle, (2) it might be suppressed partially and become VT, or (3) it might be eliminated completely. In Chapter 4 we extend our work on conduction inhomogeneities (Chapter 3) to ionic inhomogeneities. Unlike conduction inhomogeneities, ionic inhomogeneities allow the conduction of activation waves. We find, nevertheless, that they too can lead to the anchoring of spiral waves or even the complete elimination of spiral-wave turbulence. Since spiral waves can enter the region in which there is an ionic inhomogeneity, their behaviours in the presence of such an inhomogeneity are richer than those with conduction inhomogeneities. We find, in particular, that a single spiral wave anchored at an ionic inhomogeneity can show temporal evolution that may be periodic, quasiperiodic, or even chaotic. In the last case the spiral wave shows a chaotic pattern inside the ionic inhomogeneity and a regular one outside it. Defibrillation is the control of arrhythmias such as VF. Most often defibrillation is effected electrically by administering a shock, either externally or via an internally implanted defibrillator. The development of low-amplitude defibrillation schemes, which minimise the deleterious effects of the applied shock, is a major challenge in the treatment of cardiac arrhythmias. Numerical studies of models for cardiac tissue provide us with convenient means of studying the elimination of spiral-wave turbulence by the application of external electrical stimuli; this is the numerical analogue of defibrillation. Over the years some low-amplitude defibrillation schemes have been suggested on the basis of such numerical studies. In Chapter 5 we discuss two such schemes that have been shown to suppress spiral-wave turbulence in two-dimensional models for cardiac tissue and also scroll-wave turbulence in three-dimensional models. One of these schemes uses local electrical pacing, typically in the centre of the simulation domain; the other applies the external electrical stimuli over a mesh. We study the efficacy of these schemes in the presence of conduction inhomogeneities. We find, in particular, that the local-pacing scheme, though effective in a homogeneous simulation domain, fails to control spiral turbulence in the presence of an obstacle and, indeed, might even facilitate spiral-wave break up. By contrast, the second scheme, which uses a mesh, succeeds in eliminating spiral-wave turbulence even in the presence of an obstacle. We end with some concluding remarks about the possible experimental implications of our study in Chapter 6.

Turbulence

Spiral Turbulence

Fluid Mechanics

Cardiac Tissue

Tissues

Chest Tissues

Cardiac Arrhythmias

Ventricular Tissue - Inhomogeneities

Cardiac Tissues - Models

Biomedical Engineering

Inhomogeneity

Panfilov Model

Ventricular Fibrillation (VF)

Spiral-Wave Turbulence

Ventricular Tachycardia (VT)

Biophysics

Analysis and Design of a Multifunctional Spiral Antenna

Chen, Teng-Kai

2012 August 1900

The Archimedean spiral antenna is well-known for its broadband characteristics with circular polarization and has been investigated for several decades. Since their development in the late 1950's, establishing an analytical expression for the characteristics of spiral antenna has remained somewhat elusive. This has been studied qualitatively and evaluated using numerical and experimental techniques with some success, but many of these methods are not convenient in the design process since they do not impart any physical insight into the effect each design parameter has on the overall operation of the spiral antenna. This work examines the operation of spiral antennas and obtains a closed-form analytical solution by conformal mapping and transmission line model with high precision in a wide frequency band. Based on the analysis of spiral antenna, we propose two novel design processes for the stripline-fed Archimedean spiral antenna. This includes a stripline feed network integrated into one of the spiral arms and a broadband tapered impedance transformer that is conformal to the spiral topology for impedance matching the nominally-high input impedance of the spiral. A Dyson-style balun located at the center facilitates the transition between guided stripline and radiating spiral modes. Measured and simulated results for a probe-fed design operating from 2 GHz to over 20 GHz are in excellent agreements to illustrate the synthesis and performance of a demonstration antenna. The research in this work also provides the possibility to achieve conformal integration and planar structural multi-functionality for an Unmanned Air Vehicle (UAV) with band coverage across HF, UHF, and VHF. The proposed conformal mapping analysis can also be applied on periodic coplanar waveguides for integrated circuit applications.

Antenna feeds

balun

spiral antenna

stripline

multifunctional

impedance transformer

Archimedean spiral antennas

input impedance

coplanar waveguides

transmission line modeling

common mode radiation

conformal mapping

Babinet?s principle

unmanned aerial vehicle