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Dynamic response of small turbine flowmeters in pulsating liquid flowsLee, Betty January 2002 (has links)
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.
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[en] COMPARISON OF DIFFERENT APPROACHES FOR DETECTION AND TREATMENT OF OUTLIERS IN METER FACTORS DETERMINATION / [pt] COMPARAÇÃO DE DIFERENTES TÉCNICAS PARA DETECÇÃO E TRATAMENTO DE OUTLIERS NA DETERMINAÇÃO DE FATORES DE MEDIDORESANDERSON LUIZ DOS SANTOS FERREIRA 20 February 2018 (has links)
[pt] O objetivo da dissertação é analisar o comportamento das diferentes metodologias utilizadas para detecção e tratamento de outliers na determinação de fatores de prova de medidores do tipo turbina. A motivação desse trabalho é evitar tomadas de decisão equivocadas decorrentes de tratamento inadequado de outliers, comprometendo a confiabilidade na medição e consequentemente seu faturamento. A prova do fator de medidor pode ser considerada como um parâmetro de calibração, expressando a razão entre o volume de referência e o volume total de líquido que passa através do medidor. A Norma internacional recomenda o teste de Dixon para o tratamento de outliers para um conjunto de prova do fator de medidor. No entanto, a literatura é explícita quanto à avaliação do comportamento dos dados, a priori. A metodologia avalia se o comportamento dos dados do conjunto de prova do fator de medidor é Gaussiano, em seguida se comparam diferentes abordagens paramétricas e não paramétricas para a detecção e tratamento de outliers aplicados às provas dos fatores de medidores do tipo turbina para a transferência de custódia de gás liquefeito de petróleo. Posteriormente, este efeito é avaliado em relação ao número de outliers e como este manuseio afeta os critérios da amplitude variável para a incerteza expandida na prova do fator de medidor médio. Os resultados mostram que diferentes fatores de medidores médios podem ser alcançados para cada teste paramétrico e não paramétrico; de qualquer forma, conclui-se que estatisticamente não é observada diferença significativa entre eles. / [en] The objective of the dissertation is to analyze the behavior of the different methodologies used for the detection and treatment of outliers in the determination of meter proving factors of turbine type meters. The motivation of this work is to avoid mistaken decision-making as a result of inadequate treatment of outliers, compromising reliability in measurement and consequently its billing. A meter proving factor can be considered as a calibration parameter, by expressing the ratio the reference volume and the gross volume of liquid passed through a meter. The international guideline recommends Dixon s test for outliers to a meter proving factor set. However, the literature is explicit regarding the evaluation of data behavior, a priori. The methodology evaluates if the behavior of the meter proving factor set is Gaussian, then different parametric and nonparametric approaches for detection and treating outliers applied to turbine meter proving factors for custody transfer of liquefied petroleum gas are compared. Afterwards, this effect is evaluated in relation to the number of outliers and how this handling affects the variable range criteria for expanded uncertainty in average meter proving factor. The results show that different average meter factors can be reached for each nonparametric and parametric test; anyway, it is concluded that no statistically significant difference between them is noticed.
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