Coriolis flowmeters: A review of developments over the past 20 years, and an assessment of the state of the art and likely future directions

This paper starts from a brief revisit of key early published work so that an overview of modern Coriolis flowmeters can be provided based on a historical background. The paper, then, focuses on providing an updated review of Coriolis flow measurement technology over the past 20 years. Published research work and industrial Coriolis flowmeter design are both reviewed in details. It is the intention of this paper to provide a comprehensive review study of all important topics in the subject, which include interesting theoretical and experimental studies and innovative industrial developments and applications. The advances in fundamental understanding and technology development are clearly identified. Future directions in various areas together with some open questions are also outlined.This is the accepted manuscript version. The final version is available from Elsevier at http://dx.doi.org/10.1016/j.flowmeasinst.2014.08.01

Industrial flow measurement

This thesis discusses the intrinsic worth of a published work, ‘Industrial Flow Measurement’ (Appendix A), a handbook written and revised by the author over a period of 30 years. The author first discusses the need to measure flow and then moves on to the raison d’être of the handbook before looking at a brief history of flow measurement. Although not claiming that any single attribute of the handbook is unique, the author nonetheless postulates that because it incorporates several distinctive features, at a number of different levels, these agents combine to make it one-of-a- kind. The author moves on to an overview of existing flow metering technologies discussed within the handbook. Finally, he looks at what he considers is a major gap in the collected body of knowledge – the field of multiphase and water-cut metering and provides a justification, not only for its inclusion in the future but for future investigation

Dynamic response of small turbine flowmeters in pulsating liquid flows

This thesis was submitted for the degree of Doctor of Philosophy and awarded by Brunel University, 27/08/2002.The dynamic response of turbine flowmeters in low pressure gas flows (i. e. where the rotational inertia of the fluid is negligible) is well understood and methods for correcting meter signals for a lack of response are available. For liquid flows there has been a limited amount of experimental work on the response of meters to step changes but no reports have been found of the response of meters to sinusoidally pulsating flows. "Small" turbine meters are expected to behave differently from "large" meters for a number of reasons: a smaller meter would generally have: (1) a larger percentage of tip clearance leakage flow; (2) less fluid momentum between the meter blading; and, (3) less fluid friction forces on the effective surface area. In this research, arbitrarily, meters up to size 25 mm were defined as small; and within this study, meters of size 6 mm to 25 mm were investigated. The aim of the research was to investigate and to understand the response of small turbine meters to pulsating liquid flows and to provide methods for correction. Three approaches were used: (1) application of an existing theoretical model of turbine meter behaviour; (2) an experimental investigation of meter performance in pulsating flows; and (3) simulation of flow behaviour through one selected meter using CFD and extending the simulation to predict the rotor dynamics and, hence, the response of this meter to specified cases of pulsating flow. A theoretical model developed by Dijstelbergen (1966) assumes frictionless behaviour and that flow is perfectly guided by meter blading through the rotor and that fluid within the rotor envelope rotates as a "solid body". Results from this theoretical model applied for pulsating flows showed that there was likely to be positive error in predicted mean flow rate (over-registration) and negative error for predicted values of the amplitude of the pulsations (amplitude attenuation). This behaviour is due to the fundamental asymmetry between flows with increasing and decreasing angle of attack relative to the meter blades, throughout a pulsation cycle. This qualitative behaviour was confirmed by experimental work with meters up to size 25mm working with pulsation frequencies up to 300 Hz. For low frequency pulsations (below 10 Hz), the over-registration errors were within the limits of specified meter accuracy. At higher frequencies and larger pulsation amplitudes, the largest over-registration observed was 5.5 % and amplitude attenuation could be as large as 90 %. The dependence of these errors on both the flow pulsation amplitude and frequency were investigated. The theoretical model was also used as a basis for generating correction procedures, to be applied to both the mean flow and the pulsation amplitude measurements. The results from the CFD simulation showed qualitative good agreement with the experimental data. The same kind of meter error trends were observed and it was shown to provide a better correlation with the experimental trends than the theoretical model derived from Dijstelbergen. From the CFD simulation, the causes of over-registration and amplitude attenuation in turbine flowmetering were understood through the investigation of rotor dynamics coupled with fluid behaviour around meter blading within the pulsation cycle. The CFD results were used to evaluate fluid angular momentum flux and to review the validity of the assumption that fluid within the rotor "envelope" rotated as a solid body. For the case investigated, whilst the assumption that flow is perfectly guided is not inappropriate, the volume of fluid assumed to rotate as a "solid body" was found to be significantly less than the rotor envelope volume

High efficiency dynamic pressure based flow measurement

Over the past few decades considerable attention have been directed towards the development of different types of flow-metering techniques. High pressure drop after passing the metering device and partial obstruction of the flow represent the two most common problems for the majority of the existing flow-metering devices. The main intention of the current study was to overcome or minimize these two issues. The principle objectives were developing a low-cost measurement system and setup to measure the flow in pipes of small diameters (0.5” to 4”), and performing an analytical / numerical model that enables to extract the distinction of the dynamic pressure throughout the flow. Both analytical and numerical solutions of the fluid flow inside the pipe indicate forming of a parabolic velocity profile across the pipe in the fully developed flow region. Dynamic pressure variation due to velocity change across the pipe is used as the fundamental measurement principle in this work. The equipped cantilever beams with piezo-resistive materials are used as sensor for detecting the induced signals in three different levels across the pipe. The collected signals are used to reconstruct the parabolic velocity profile. Further, the integration of the parabolic profile in the cross-section area of the pipe will yield to the flow value. The constructed sensors with strain gages are connected to a Wheatstone-Bridge. The resistance variation due to the strain changing in cantilever platform converts to voltage variation by the Wheatstone-Bridge. Signal amplification and filtering are carried out by a dedicated circuit board. The work was extended to inkjet-printing of the conductive ink which is introduced as an alternative method for piezoresistive sensor fabrication. Easiness and fast-fabrication process are two important factors which give ability to mass production of low-cost piezoresistive sensors

Low frequency strip waveguide array for flow measurement in hostile environments

A low frequency, waveguide array transducer, for operation in hostile environments, is studied and optimised for operation in fluids. The design consists of multiple stainless steel, rectangular cross-section strips which are used to support Lamb-like guided waves, which with appropriate delays allows the steering of the emitted beam. Wave propagation within the waveguide strips is discussed and the effect of the strip geometry on the supported wave modes is studied using comprehensive finite element modelling that is validated experimentally. Deviations from Lamb wave behaviour is observed due to coupling that occurs across the finite width of the strip, leading to dispersive behaviour that is slightly different to that of Lamb waves in a plate of the same thickness. As a result of this study, suggestions are made for modifications to the waveguide geometry that may favourably change this dispersive behaviour, over a desired frequency range. The effect of thermal gradients on the propagation of ultrasonic waves within the waveguide strips is also studied. Using Lamb waves as a basis for the analysis, general trends in the wave behaviour were identified before a series of experiments were conducted to demonstrate similar effects in the waveguide strips. Computational fl uid dynamics models were also used to study the heat distribution within the waveguide strips of the transducer to allow the in uence of these effects in a practical application to be assessed. Finally, the phased array capabilities of the strip waveguide array transducer were demonstrated. Initially, finite element modelling was conducted to allow the optimisation of the array geometry before the construction of a prototype. Using this prototype and a custom low frequency phased array controller, experimental steering of the beam emitted from the transducer was demonstrated up to angles of 45°

Introduction to modern instrumentation: for hydraulics and environmental sciences

Preface Natural hazards and anthropic activities threaten the quality of the environment surrounding the human being, risking life and health. Among the different actions that must be taken to control the quality of the environment, the gathering of field data is a basic one. In order to obtain the needed data for environmental research, a great variety of new instruments based on electronics is used by professionals and researchers. Sometimes, the potentials and limitations of this new instrumentation remain somewhat unknown to the possible users. In order to better utilize modern instruments it is very important to understand how they work, avoiding misinterpretation of results. All instrument operators must gain proper insight into the working principles of their tools, because this internal view permits them to judge whether the instrument is appropriately selected and adequately functioning. Frequently, manufacturers have a tendency to show the great performances of their products without advising their customers that some characteristics are mutually exclusive. Car manufacturers usually show the maximum velocity that a model can reach and also the minimum fuel consumption. It is obvious for the buyer that both performances are mutually exclusive, but it is not so clear for buyers of measuring instruments. This book attempts to make clear some performances that are not easy to understand to those uninitiated in the utilization of electronic instruments. Technological changes that have occurred in the last few decades are not yet reflected in academic literature and courses; this material is the result of a course prepared with the purpose of reducing this shortage. The content of this book is intended for students of hydrology, hydraulics, oceanography, meteorology and environmental sciences. Most of the new instruments presented in the book are based on electronics, special physics principles and signal processing; therefore, basic concepts on these subjects are introduced in the first chapters (Chapters 1 to 3) with the hope that they serve as a complete, yet easy-to-digest beginning. Because of this review of concepts it is not necessary that the reader have previous information on electronics, electricity or particular physical principles to understand the topics developed later. Those readers with a solid understanding of these subjects could skip these chapters; however they are included because some students could find them as a useful synthesis. Chapter 4 is completely dedicated to the description of transducers and sensors frequently used in environmental sciences. It is described how electrical devices are modified by external parameters in order to become sensors. Also an introduction to oscillators is presented because they are used in most instruments. In the next chapters all the information presented here is recurrently referred to as needed to explain operating principles of instruments. Unauthenticated Download Date | 10/12/14 9:29 PM VIII Preface Chapters 1 to 4 are bitter pills that could discourage readers interested in the description of specific instruments. Perhaps, those readers trying this book from the beginning could abandon it before arriving at the most interesting chapters. Therefore, they could read directly Chapters 5 to 11, going back as they feel that they need the knowledge of the previous chapters. We intended to make clear all the references to the previous subjects needed to understand each one of the issues developed in the later chapters. Chapter 5 contributes to the understanding of modern instrumentation to measure flow in industrial and field conditions. Traditional mechanical meters are avoided to focus the attention on electronic ones, such as vortex, electromagnetic, acoustic, thermal, and Coriolis flowmeters. Special attention is dedicated to acoustic Doppler current profilers and acoustic Doppler velocimeters. Chapter 6 deals with two great subjects; the first is devoted to instruments for measuring dynamic and quasi static levels in liquids, mainly water. Methods to measure waves at sea and in the laboratory are explained, as well as instruments to measure slow changes such as tides or piezometric heads for hydrologic applications. The second subject includes groundwater measurement methods with emphasis on very low velocity flowmeters which measure velocity from inside a single borehole. Most of them are relatively new methods and some are based on operating principles described in the previous chapter. Seepage meters used to measure submarine groundwater discharge are also presented. Chapter 7 presents methods and instruments for measuring rain, wind and solar radiation. Even though the attention is centered on new methods, some traditional methods are described not only because they are still in use, and it is not yet clear if the new technologies will definitely replace them, but also because describing them permits their limitations and drawbacks to be better understood. Methods to measure solar radiation are described from radiation detectors to complete instruments for total radiation and radiation spectrum measurements. Chapter 8 is a long chapter where we have tried to include most remote measuring systems useful for environmental studies. It begins with a technique called DTS (Distributed Temperature Sensing) that has the particularity of being remote, but where the electromagnetic wave propagates inside a fibre optic. The chapter follows with atmosphere wind profilers using acoustic and electromagnetic waves. Radio acoustic sounding systems used to get atmospheric temperature profiles are explained in detail as well as weather radar. Methods for ocean surface currents monitoring are also introduced. The chapter ends with ground penetrating radars. Chapter 9 is an introduction to digital transmission and storage of information. This subject has been reduced to applications where information collected by field instruments has to be conveyed to a central station where it is processed and stored. Some insight into networks of instruments is developed; we think this information will help readers to select which method to use to transport information from field to office, by means of such diverse communication media as fibre optic, digital telephony, Unauthenticated Download Date | 10/12/14 9:29 PM Preface IX GSM (Global System for Mobile communications), satellite communications and private radio frequency links. Chapter 10 is devoted to satellite-based remote sensing. Introductory concepts such as image resolution and instrument?s scanning geometry are developed before describing how passive instruments estimate some meteorological parameters. Active instruments are presented in general, but the on-board data processing is emphasized due to its importance in the quality of the measurements. Hence, concepts like Synthetic Aperture Radar (SAR) and Chirp Radar are developed in detail. Scatterometers, altimeters and Lidar are described as applications of the on-board instruments to environmental sciences. Chapter 11 attempts to transfer some experiences in field measuring to the readers. A pair of case studies is included to encourage students to perform tests on the instruments before using them. In this chapter we try to condense our ideas, most of them already expressed throughout the book, about the attitude a researcher should have with modern instruments before and after a measuring field work. As can be inferred from the foregoing description the book aims to provide students with the necessary tools to adequately select and use instruments for environmental monitoring. Several examples are introduced to advise future professionals and researchers on how to measure properly, so as to make sure that the data recorded by the instruments actually represents the parameters they intend to know. With this purpose, instruments are explained in detail so that their measuring limitations are recognized. Within the entire work it is underlined how spatial and temporal scales, inherent to the instruments, condition the collection of data. Informal language and qualitative explanations are used, but enough mathematical fundamentals are given to allow the reader to reach a good quantitative knowledge. It is clear from the title of the book that it is a basic tool to introduce students to modern instrumentation; it is not intended for formed researchers with specific interests. However, general ideas on some measuring methods and on data acquisition concepts could be useful to them before buying an instrument or selecting a measuring method. Those readers interested in applying some particular method or instrument described in this book should consider these explanations just as an introduction to the subject; they will need to dig deeper in the specific bibliography before putting hands on.Fil: Guaraglia, Dardo Oscar. Universidad Nacional de la Plata. Facultad de Ingeniería. Departamento de Hidraulica. Area Hidraulica Basica; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata; ArgentinaFil: Pousa, Jorge Lorenzo. Universidad Nacional de La Plata. Facultad de Ciencias Naturales y Museo. Laboratorio de Oceanografía Costera y Estuarios; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - La Plata; Argentin

Development and application of microtechnologies in the design and fabrication of cell culture biomimetic systems

“Lab-On-a-chip” systems have proved to be a promising tool in the field of biology. Currently, cell culture is performed massively on Petri dishes, which have traditionally been used in cell culture laboratories and tissue engineering. However, having proved to be a widely used tool until now, the scientific community has largely described the lack of correlation between the results obtained in the laboratory and the clinical results. This lack of connection between what has been studied in the laboratories and what has been observed in the clinic has led to the search for more advanced alternative tools that allow results to be obtained closer to reality. Thus, the use of microtechnologies in the field of biomedical engineering, presents itself as the perfect tool as an alternative to obsolete traditional media. Thanks to the low volumes of liquid it presents for its use, it also makes it an essential technology for the testing of drugs, new compounds and materials. By being able to more accurately reproduce the biomimetic environment of cell cultures and tissues, they make this technique fundamental as an intermediate step between basic in vitro laboratory tests and preclinical animal tests, resulting from this way in the best alternative for the reduction of both the use of animal models, as in times and costs. For a biomimetic system to be as such, it also needs another series of complementary devices for its better functioning. Micro-valves, micro pumps, flow sensors, O2 sensors, pH, CO2 are fundamental for the correct functioning andsophistication of biomimetic systems. This complexity, on the other hand, is often not perceived by the user since the miniaturization of all these components makes “Lab-On-a-Chip” systems smaller every day, despite numerous control components that can be incorporated.This thesis presents some examples of different microfluidic devices designed and manufactured through the use of microtechnologies, with all applications, focused on their use in biomimetic systems.<br /

Innovative contributions on calibration methodologies towards reliable microflow measurements

Flow measurement is critical in healthcare, chemistry and pharmaceutics, to mention a few. In fact, there are several applications in the microflow and nanoflow range, such as scaled-down process technology, drug development, and special health-care applications, as organ-on-a- chip technology. Nevertheless, the majority of the instruments used for the specified applica- tions are not sufficiently studied regarding their flow accuracy and traceability. Hence these fluid applications at the micro and nanoscale still lack well defined calibration methodologies for the devices working at the mentioned flow range with adequate uncertainty values. The work presented in this thesis focuses on the development and improvement of in- novative applications of calibration methodologies for microflow measuring instruments. The gravimetric method already implemented at IPQ from 120 L/h to 2000 mL/h was used and improved for low flow rates down to 10 L/h. Additionally, other 4 methods were developed to enable the calibration of micro/nano flows in a non-intrusive way. They are interferometry, pending drop, front track and comparison method (where a calibrated flow generator is used as the reference standard). The methodology that is best suited for each specific instrument and each measurement range, with the lowest uncertainty, was successfully identified along with the relevant influence factors in microflow measurements. A specific objective of this work was to increase the measuring range of IPQ-LVC down to 5 nL/min (0.3 L/h) with a 3% target uncertainty (k=2). This objective was possible to achieve and even surpass with the use of the interferometric method, where measurements were per- formed down to 1.6 nL/min (0.1 L/h) with 2 % uncertainty(k=2). This method was internally validated by comparison with the gravimetric method and is now in the process of external validation by EURAMET project 1508.A medição de caudal é extremamente importante em áreas como a saúde, a indústria química ou farmacêutica. Caudais à escala micro/nanométrica são já utilizados em várias aplicações, nomeadamente, processos tecnológicos de redução de escala, desenvolvimento de fármacos e especialmente em novas aplicações na área da saúde, tais como a tecnologia de órgãos-em- chip. Os sistemas de medição utilizados nas aplicações indicadas, por serem relativamente recentes, não estão ainda suficientemente estudados quanto a sua exatidão e rastreabilidade. É, assim, necessário desenvolver metodologias de calibração específicas para os referidos cau- dais com incertezas de medição adequadas. Este trabalho irá focar-se no desenvolvimento e melhoramento de metodologias de cali- bração de instrumentos utilizados na medição de micro/nanocaudal de fluidos. O método gra- vimétrico já implementado no IPQ numa gama de medição de 120 L/h a 2000 mL/h foi me- lhorado de forma se realizarem calibrações até 10 L/h. Foram ainda desenvolvidos 4 novos métodos, a interferometria, o método da gota pendente, o método do deslocamento de me- nisco e o método comparativo (onde um gerador de caudal é utilizado como referência). A metodologia que melhor se aplica a cada instrumento e a gama de medição, com a melhor incerteza foi identificada, assim como fatores de influência na medição de microcaudal. Um objetivo específico deste trabalho foi aumentar o intervalo de medição do IPQ-LVC para 5 nL/min (0.3 L/h) com uma incerteza de (k=2). Isso foi possível e até ultrapassável com a utilização do método interferométrico, em que as foram realizadas medições até 1.6 nL/min (0.1 L/h) com 2% de incerteza (k=2). Este método foi validado internamente por comparação com o método gravimétrico e está agora em processo de validação externa através do projeto EURAMET 1508

Flow and heat transfer in rotating ducts

Imperial Users onl