Numerical Simulations Of Installation Effects Caused By Upstream Elbows On Single-path Transit-time Ultrasonic Flare Flow Meters

MARTINS, R. S.

23 May 2012

Made available in DSpace on 2016-08-29T15:32:56Z (GMT). No. of bitstreams: 1 tese_5744_Dissertation_MartinsRS20131108-144619.pdf: 9401224 bytes, checksum: 3db21435dc365ec6e0dd83f6c3b5e644 (MD5) Previous issue date: 2012-05-23 / A indústria de petróleo e gás requer medições de vazão com baixa incerteza, uma vez que são estabelecidas por lei. Contudo, curvas e outros obstáculos são comumente encontrados nesse cenário, o que pode afetar a qualidade da medição de vazão em função de perturbações no escoamento, tais como swirl e assimetrias no peril de velocidades. Medidores de vazão por ultrassom de um canal são frequentemente utilizados em instalações de gás de queimadores, apesar de serem sensíveis a tais perturbações. O presente trabalho usa códigos comerciais de CFD para obter o escoamento à jusante de instalações com uma curva e duas curvas, visando a investigar a magnitude e o comportamento de tais efeitos na medição de vazão. Integração numérica é utilizada para diversos arranjos de caminho acústico, simulando medidores de vazão por ultrassom de um canal em várias condições para avaliar o desvio do fator de correção em escoamentos perturbados. Números de Reynolds de 1 x 104 a 2 x 106 são considerados. Ângulos de montagem dos transdutores de 0° a 180° são testados e posições axiais até 80D à jusante do obstáculo são avaliadas. Os resultados indicam que medidores de vazão por ultrassom são sensíveis aos efeitos de acidente de linha. O desvio do fator de correção mostra-se, em geral, consideravelmente maior que 2% em distâncias menores que 20D, conforme recomendado por alguns fabricantes e por leis. Não obstante, tais desvios podem atingir 0,01% em algumas configurações específicas, o que sugere que a medição de vazão por ultrassom pode ser melhorada pelo rearranjo do aparato em posição angular favorável e, principalmente, pela implementação de funções específicas para fatores de correção em condições perturbadas.

ultrasonic flow meter

installation effects

correction fact

Ultrasonic Technique In Determination Of Grid-Generated Turbulent Flow Characteristics And Caustic Formation

Meleschi, Shangari B.

29 April 2004

The present study utilizes the ultrasonic travel time technique to diagnose grid generated turbulence. Ultrasonic flow metering technology relies on the measurement and computation of small perturbations in the travel time of acoustic ultrasonic waves through the dynamic medium. The statistics of the travel time variations of ultrasonic waves that are caused by turbulence probably affect the performance of ultrasonic flow meters. Motivation for the study stems from the large travel time variations observed in typical ultrasonic flow and circulation meters. Turbulent flow data was collected downstream of a grid introduced in a uniform flow in the wind tunnel using ultrasonic techniques. Grid turbulence is well defined in literature, and is nearly homogeneous and isotropic. The experimental investigation was performed under well-controlled laboratory conditions. The grid mesh sizes varied from 0.25-0.5in, and flow velocities from 0-20m/s. The ultrasonic transducers were of 100 kHz working frequency; and all of the data was collected with them oriented perpendicular to the mean flow. Path lengths were increased from 2-10in; and the data acquisition and control system featured a very high speed data acquisition card with an analog to digital converter that enabled excellent resolution of ultrasonic signals. Experimental data was validated by comparison to other studies. The work aims to investigate the influence of the grid-generated turbulent flow on acoustic wave propagation, in terms of the variance of the travel time. The effect of turbulence on acoustic wave propagation was observed. The experimental data was used to compute average travel times, acoustic travel time variances, and standard deviation amplitude fluctuations. The data was collected in the region estimated to be homogeneous and isotropic. Average travel time data support the assumption that only the large (as compared to the wavelength ) turbulent inhomogeneities influence acoustic wave propagation. Variance data confirm the presence of a non-linear trend in the acoustic travel times with increasing path length. Amplitude fluctuations data confirm a correlation between areas of caustic formation and large amplitude fluctuations.

caustics

turbulence

wave propagation

ultrasonic flow meter

Turbulence

Turbulent flow

Design of a clamp-on ultrasonic flow meter for wet gas pipelines

Vedapuri, Damodaran

January 2001

No description available.

Engineering, Chemical

clamp-on flow meter

ultrasonic flow meter

wet gas pipelines

Simulaçõeses numéricas de efeitos de acidentes de linha causados por curvas à montante de medidores de vazão por ultrassom de um canal por tempo de trânsito para gás de flare / Numerical simulations of installation effects caused by upstream elbows on single-path transit-time ultrasonic flare flow meters

Martins, Ramon Silva

23 May 2012

Made available in DSpace on 2016-12-23T14:08:08Z (GMT). No. of bitstreams: 1 Martins RS Part 1.pdf: 212782 bytes, checksum: 40ca14a4b97179f5b3af71f964306b97 (MD5) Previous issue date: 2012-05-23 / Oil and gas industry requires accurate flow measurements since they are stated by law. Nevertheless, curves and other obstacles are commonly found in such industry field, which may affect the quality of flow measurement due to flow disturbances, such as swirl and velocity profile asymmetries. Single-path ultrasonic flow meters are often used in flare gas installations, despite being sensitive to such disturbances. The present work use commercial CFD codes to obtain disturbed flow fields downstream from single and double elbow pipe installations, aiming to investigate both magnitude and behaviour of such effects on ultrasonic flow measurement. Numerical integration is applied for several acoustic path arrangements, simulating single-path ultrasonic flow meters in different situations in order to evaluate its correction factor deviation under disturbed conditions. Reynolds numbers from 1X10 4 to 2 X10 6 are considered. Transducers mounting angles from 0° to 180° are tested and axial positions up to 80D downstream from the curve are evaluated. Results indicate that single-path ultrasonic flow meters are sensitive to installation effects. Correction factor deviations usually showed to be significantly higher than 2% for axial positions shorter than 20D, as recommended by several manufacturers or regulations. Nevertheless, deviations may reach 0.01% in some specific configurations, which suggests that ultrasonic flow measurement might be improved by rearranging flow meter device in favourable angular position and mainly by implementation of specific functions for correction factors under disturbed conditions / A indústria de petróleo e gás requer medições de vazão de baixa incerteza, uma vez que são estabelecidas por lei. Contudo, curvas e outros obstáculos são comumente encontrados nesse cenário e podem afetar a qualidade da medição de vazão em função de perturbações no escoamento, tais como swirl e assimetrias no perfil de velocidades. Medidores de vazão por ultrassom de um canal são frequentemente utilizados em instalações de gás de queimadores, apesar de serem sensíveis a tais perturbações. O presente trabalho usa códigos comerciais de CFD para obter o escoamento à jusante de instalações com uma curva e duas curvas, visando a investigar a magnitude e o comportamento de tais efeitos na medição de vazão. Integração numérica é utilizada para diversos arranjos de caminho acústico, simulando medidores de vazão por ultrassom de um canal em várias condições para avaliar o desvio do fator de correção em escoamentos perturbados. Números de Reynolds de 1×10 4 a 2×10 6 são considerados. Ângulos de montagem dos transdutores de 0° a 180° são testados e posições axiais até 80D à jusante do obstáculo são avaliadas. Os resultados indicam que medidores de vazão por ultrassom são sensíveis aos efeitos de acidente de linha. O desvio do fator de correção mostra-se, em geral, consideravelmente maior que 2% em distâncias menores que 20D, conforme recomendado por alguns fabricantes e por leis. Não obstante, tais desvios podem atingir 0,01% em algumas configurações específicas, o que sugere que a medição de vazão por ultrassom pode ser melhorada pelo rearranjo do aparato em posição angular favorável e, principalmente, pela implementação de funções específicas para fatores de correção em condições perturbadas

Medidor de vazão por ultrassom

Efeitos de acidentes de linha

Fator de correção

Dinâmica dos fluidos computacional

Ultrasonic flow meter

Installation effects

Correction factor

Computational fluid dynamics

CNPQ::ENGENHARIAS::ENGENHARIA MECANICA

Optimisation of an Ultrasonic Flow Meter Based on Experimental and Numerical Investigation of Flow and Ultrasound Propagation

Temperley, Neil Colin, Mechanical & Manufacturing Engineering, Faculty of Engineering, UNSW

January 2002

This thesis presents a procedure to optimise the shape of a coaxial transducer ultrasonic flow meter. The technique uses separate numerical simulations of the fluid flow and the ultrasound propagation within a meter duct. A new flow meter geometry has been developed, having a significantly improved (smooth and monotonic) calibration curve. In this work the complex fluid flow field and its influence on the propagation of ultrasound in a cylindrical flow meter duct is investigated. A geometric acoustics (ray tracing) propagation model is applied to a flow field calculated by a commercial Computational Fluid Dynamics (CFD) package. The simulation results are compared to measured calibration curves for a variety of meter geometries having varying lengths and duct diameters. The modelling shows reasonable agreement to the calibration characteristics for several meter geometries over a Reynolds number range of 100...100000 (based on bulk velocity and meter duct diameter). Various CFD simulations are validated against flow visualisation measurements, Laser Doppler Velocimetry measurements or published results. The thesis includes software to calculate the acoustic ray propagation and also to calculate the optimal shape for the annular gap around the transducer housings in order to achieve desired flow acceleration. A dimensionless number is proposed to characterise the mean deflection of an acoustic beam due to interaction with a fluid flow profile (or acoustic velocity gradient). For flow in a cylindrical duct, the 'acoustic beam deflection number' is defined as M g* (L/D)^2, where: M is the Mach Number of the bulk velocity; g* is the average non-dimensionalised velocity gradient insonified by the acoustic beam (g* is a function of transducer diameter - typically g* = 0.5...4.5); L is the transducer separation; and D is the duct diameter. Large values of this number indicate considerable beam deflection that may lead to undesirable wall reflections and diffraction effects. For a single path coaxial transducer ultrasonic flow meter, there are practical limits to the length of a flow meter and to the maximum size of a transducer for a given duct diameter. The 'acoustic beam deflection number' characterises the effect of these parameters.

ultrasonic flow meter

ultrasonic flowmeter

flow meter shape

flow meter geometry

ray tracing

geometric acoustics

computational fluid dynamics

cfd

flow meters

ultrasonics

Energetické hodnocení systémů TZB / Energy Evaluation of Technical Services Systems

Cap, Petr

January 2013

This Master’s thesis deals with the energy evaluation of existing buildings sports-recreational company complex in Brušperk. For this purpose provides a comparison of selected fuels as an energy source for the heating in terms of economy and their impact on the environment. In addition, provides an overview of existing legislation for elaboration of an energy audit. To complement shows the calculation of return on investment in solar panels on the roof of one of the objects. Calculation is based on the results of performed experimental measurement. Finally, the thesis presents a comparison of energy performance of buildings simulated in the Bsim software with reality.