The present disclosure relates to apparatus or methods for measuring the mass flow and/or density of fluids wherein the fluid flows through the meter in continuous flow and to flow meters and flow measurement, Coriolis meters that employ multiple frequency oscillations and sonar flow measurements.
A Coriolis flow meter measures a parameter of a fluid, including but not limited to parameters like the mass flow and/or density of a fluid through a conduit. The same Coriolis meter can measure fluids of varying densities, flow rates, temperatures, phases and viscosity. The mass flow rate is the mass of a fluid moving past a given point per unit time. Volumetric flow rate is the volume of fluid moving past a given point per unit time. Coriolis meters report volumetric flow by dividing the measured mass flow rate by the measured fluid density. Coriolis meters are often used to measure a wide variety of fluids, including liquid and gases and mixtures of the liquid and gases and fluid conveyed solids. Coriolis meters are known as highly accurate mass and density meters for homogeneous fluids and fluids with low compressibility. However, as understood in the art, the accuracy of a Coriolis meter degrades with the introduction of inhomogeneities in the process-fluid and increases in process-fluid compressibility. For example, the introduction of entrained gases within a liquid, and other types of multiphase flows, introduces both inhomogeneities and increases the compressibility, and is known to cause errors in reported mass flow and/or process-fluid density
Coriolis meters measure the mass flow and density of the process-fluid by measuring the influence that the process-fluid has on the vibrational characteristics of vibrating, fluid-conveying, flow tubes. The influence of the process-fluid on the vibrational characteristics of the vibrating flow tubes depends on the homogeneity and the compressibility of the process-fluid. For a homogeneous, highly-incompressible fluid being conveyed within a vibrating flow tube the center of mass of the fluid essentially follows the center of mass of the vibrating, fluid-conveying flow tubes. In this case, the mass flow of the process fluid can be calibrated to be essentially proportional to a measured twist, or deformation, of the vibrational mode shape of the flow tube. The density of the process fluid can be calibrated to a change in the natural frequency of the fluid-conveying flow tube.
However, as fluid inhomogeneity and/or compressibility increase, the center-of-mass of the process-fluid increasingly departs from the center-of-mass of the flow tube when vibrated. This departure changes the relationship between said measured vibrational characteristics and said fluid properties, thereby resulting in a Coriolis meter, calibrated on essentially homogeneous, incompressible fluids, to incorrectly interpret the mass flow and/or density of a process-fluid with increased compressibility and/or inhomogeneity. Decoupling of an inhomogeneous fluid is said to occur within a fluid when one phase of a fluid vibrates differently than another phase. Bubbly liquids are an example of a broad class of fluids which can exhibit large and variable amounts of both decoupling due to inhomogeneities.
Sonar flow meters can measure the speed at which sound propagates through a fluid contained in a fluid-conveying conduit. Sonar flow measurement is effective in measuring the speed of sound in wide range of single and multiphase mixtures of gas and liquids, including fluids with conveyed solids. Sonar flow meter are also effective in measuring the speed of sound in bubbly mixtures and utilizing this speed of sound measurement in the determination of gas void fraction of bubbly fluids.
One skilled in the art understands that process fluid variability refers to the inhomogeneity of a fluid or the compressibility of a fluid, or any other fluid variability understood in the art.
Some improvements have been made in the application of Coriolis meters on multiphase flows by measuring the drive gain of tube vibration. The drive gain of a Coriolis meter is a measure of the oscillatory force required to vibrate the fluid-conveying flow tube to a prescribed amplitude. Since the introduction of entrained gases increases the damping of the vibrational mode of the fluid-conveying flow tubes, the drive gain of a Coriolis meter often correlates with the amount of entrained gas. Although this approach is often a reliable indicator of the presence of entrained gas, it does not typically reliably quantify the amount of entrained gas, nor has it been successfully used to correct the errors in the reported mass flow or density measurements due to the entrained gas.
In one example within the state of the art, a dual tube Coriolis meter has flow tubes driven at two different vibrational modes, each with a different frequency. The meter provides a measure of the density of the process fluid by measuring the natural frequency of each of the two modes of the fluid-conveying flow tubes and interpreting the natural frequency in terms of the density of the process-fluid utilizing a calibration determined for an essentially incompressible, homogeneous fluid. In this method, the difference in the measured densities is interpreted as a measure of the influence of the entrained gas present in the process-fluid.[.] This difference in conjunction with the difference in vibrational frequency is used to estimate the density of the liquid without the entrained gas.
The state of the art has yet to effectively quantify the combined effects of decoupling (due to inhomogeneities) and compressibility on the mass flow and/or density of a process-fluid reported by a multifrequency Coriolis meter. As a result, the state of the art exhibits a limited ability to correct for multiphase conditions on multi-frequency Coriolis meters, particularly in combination with varying pressure, gas void fraction and reduced frequency. Furthermore the state of the art multi-frequency Coriolis meters lacks the ability to output gas void fraction as a measured process parameter.
In accordance with example embodiments of the present disclosure, a method for determining parameters for, and application of, models that correct for the effects of fluid inhomogeneity and compressibility on the ability of Coriolis meters to accurately measure the mass flow and/or density of a process fluid on a continuous basis is disclosed. Example embodiments mitigate the effect of multiphase fluid conditions on a Coriolis meter.
In an example embodiment, at least one measurement of the propagation of the speed of sound through a process fluid is employed to determine the gas volume fraction and employed in the interpretation of vibrational characteristics of at least one conduit. Fluid properties, including, process-fluid density, mass flow rate, gas void fraction and liquid-phase density are interpreted using an empirical model in which parameters of said model are determined using an optimization algorithm. In combination with the measurement of the propagation of the speed of sound through the process-fluid, at least one conduit is vibrated at more than one frequency, or more than one conduits are vibrated at different frequencies. Measurement of the mass flow and/or density through at least one conduit vibrated at more than one frequency, or more than one conduits are vibrated at different frequencies, in combination with the measurement of the speed of sound propagating through the fluid supports an error reducing algorithm that provides continuous error correction in a flowing fluid of varying properties.
The method and apparatus of the disclosure improves the accuracy of multi-frequency Coriolis meters on both homogeneous and non-homogeneous flows. Homogeneous flows include single-phase flows. Moving fluid with entrained gas in which no significant decoupling occurs due to the inhomogeneity of the bubbles can effectively be treated as homogeneous flows. Measured speed of sound combined with the disclosed method may be used to account for compressibility in both homogeneous flows and non-homogeneous flows.
The present disclosure describes a method and apparatus that measures fluid density and mass flow rate with improved accuracy in the presence of varying levels of compressibility and/or inhomogeneity of a fluid flowing through vibrating conduits, also referred to as vibrating flow tubes.
An example embodiment accurately characterizes multiphase flows within a multi-frequency Coriolis meter. The example embodiment is a method for measuring process-fluid mass flow and/or density in a Coriolis meter having one or more flow tubes, with flow tube vibration occurring at at least two different resonant frequencies in combination with a measured sound speed through the process fluid to provide the basis for determination of parameters in a model used to correct for the effects of fluid inhomogeneity and compressibility
An optimization algorithm minimizes an error function to interpret the apparent mass flow rate and apparent densities measured at two frequencies in terms of the actual mass flow rate and actual density of a mixture flowing through a Coriolis meter. This error function is based on equating the interpreted mass flow rates at two frequencies and equating the interpreted process fluid densities. For this example, the error function is defined as a weighted sum of the square of the normalized difference in mass flow and densities at the two frequencies, for example:
error≡α{dot over (m)}(({dot over (m)}f1
In the above expression, the trial mass flows and densities are formed by correcting the measured, or apparent, mass flows and densities to actual mass flows and density using an over reading function determined by a mathematical model which incorporates the effects of process-fluid inhomogeneity and compressibility. The error is minimized by adjusting parameters within the mathematical model such that corrected mass flows and corrected densities predicted at the two frequencies match, respectively. To determine the parameters of the multiphase flow through the meter, the error function is then evaluated over a wide range of reduced frequency parameters; which in this model influences both compressibility and gas void fraction, and the gas damping ratio parameter, also referred to as decoupling parameter. Once the parameters of the model are optimized such that the error function is minimized, f, the optimized mass flow and mixture density are determined by utilizing the optimized parameters in the model to correct the measured process-fluid mass flow and density. One skilled in the art understands that the parameters of a model may be adjusted or optimized. The present disclosure may refer to adjusted or optimized interchangeably.
In another example embodiment, an empirical model for the effects of process fluid inhomogeneity and compressibility formulated by Hemp is used, where ρ measured and {dot over (m)}measured are the density and mass flow reported by a Coriolis meter operating on a process-fluid, and would be calibrated to accurately represent the density and mass flow if the process fluid was a homogeneous fluid with a sufficiently low, or known, reduced frequency.
ρ liquid and {dot over (m)}liquid are the actual liquid density and mixture mass flow rate. Note that for gas-entrained mixtures, the mass flow of the gas phase is typically negligible compared to the mass flow of the liquid, and therefore the mixture mass flow and the liquid mass flow rates are essentially identical.
Where
the reduced frequency, ftube is the vibrational frequency of flow tube (in Hz) D is the inner flow diameter of said flow tube, and amix is the mixture speed of sound.
Hemp's formulation provides a compact parametric model for correcting for the effects of inhomogeneity and compressibility on the mass flow and the density as reported by a Coriolis meter, calibrated on homogeneous process fluids operating at low reduced frequencies, but operating on process fluids with inhomogeneity and/or significant compressibility. Hemp's formulation also provides a model that explicitly identifies the role of the gas void fraction, αg, in quantifying decoupling effects associated with inhomogeneity and the reduced frequency in quantifying compressibility effects. Note that Hemp's model for the influence of inhomogeneity and compressibility is expressed in terms of gas void fraction and reduced frequency, each of which are readily determined from a process-fluid sound speed measurement in conjunction with other information typically available from Coriolis meters and other common process measurements.
The effect of compressibility as a function of frequency is captured in the model with the reduced frequency. Hemp proposes that the compressibility constants for density and mass flow are Gd=0.25 and Gm=0.5, respectively. The values suggested by Hemp's reduced order model can be applied directly, or these values could be determined through an optimization process. In the first example developed below, we assume the values for Gd and Gm suggested by Hemp.
As described by Hemp, the decoupling constant for bubbly flows can be a function of many parameters including bubble size, bubble size distribution, gas/liquid density ratio, vibration frequency, and other parameters, many of which are unknown in many applications. The literature indicates that decoupling effects will depend on the inverse Stokes number as seen in the following equation:
Where F indicates an undefined function, νƒ is the kinematic viscosity, ω[ν] is the vibration frequency of the mode of interest of the vibrating flow tube, and abubble is the radius of the bubbles.
Based on theory and data presented in literature, it is reasonable to assume that the decoupling constant, Kd, used in the interpretation of vibrating tube density measurements at two different frequencies, but on the same fluid, may differ. Additionally, it is reasonable to assume that the decoupling parameters would vary with varying fluid conditions.
Hemp's formulations rely on decoupling constants, (Kd, Km), and/or compressibility constants (Gd, Gm), which in general are unknown, and depend or details of the applications as fluid viscosity, surface tension, bubble size, tube vibrational frequency, etc. Not only is this information not typically available in most applications, this information likely changes significantly with process fluid variability.
An example embodiment of the disclosure provides a methodology to enable practical determination of relevant parameters in relevant correction models to mitigate the effects of multiphase conditions on Coriolis meters. Said parameters may be determined during the operation of the Coriolis meter. With the parameters of relevant models identified and updated as needed, said models can be applied to enable Coriolis meters to practically and accurately measure the mass flow and/or density as well as other parameters of the process fluid.
The methodology described below provides a method to leverage mass flow and/or density measurements made simultaneously within the same flow tube or at different times but under the same flow conditions, at two or more frequencies in conjunction with a process fluid sound speed to provide the basis for near real-time determination of said coupling parameters, and thereby, provides a practical method to accurately characterize multiphase flows within multi-frequency Coriolis meters.
Equating the expressions for the density of the liquid phase of a process-fluid as measured by the interpretation of the natural frequency of two modes of vibration of the process-fluid conduits, yields the following equation:
Rearranging the expression for the last equality yields the following:
The above equation may be applied at each instance in time for which the apparent density for each frequency is measured, along with the speed of sound, gas void fractions and resonant tube frequencies. Errors determined from measurements at multiple instances “i” can be expressed as a summation.
Similarly, following Hemp for the mass flow measurement:
Rearranging:
A composite error function can be defined as:
The example cases developed below utilize the density error function to optimize the density decoupling parameter and the mass flow error function to optimize the mass flow decoupling parameters, respectively. A composite error function, which includes contributions from both a mass flow error and a density error, could be used for cases in which a relationship between the mass flow and density decoupling parameters could be established, for example, if it were assumed that the mass flow and density decoupling parameters were equal, i.e. if kd1=km1, and/or kd2=km2.
It should be noted that the interpretation of a measured process-fluid sound speed in terms of gas void fraction using Wood's equation, or an approximation thereof, or similar, and requires some knowledge of the process-fluid density. Wood's equation for the process fluid speed of sound of a bubbly liquid can be expressed as:
The mixture density can be expressed as:
ρmix=(1−φg)ρliq+φgρgas
And using an ideal gas law and the expression for the speed of sound of a polytropic gas: p=ρRT and agas=√{square root over (KRT)}
And assuming the gas density is much less than the liquid density, and the compressibility of the gas component is far larger than the liquid component results in the following simplification of Wood's equation:
Which has the solution for gas volume fraction as follows.
In the examples developed herein, we minimize the density error function to determine the density of the liquid phase of a bubbly mixtures measured utilizing a two-frequency Coriolis meter at multiple instances. The example simulates “net oil” well test, which the liquid fluid density is varying due to varying watercut of the produced liquids and the gas void fraction is also varying. The liquid density at each instance is sought to determine measured watercut.
The minimization of the error function utilizes measured process fluid speed of sound, process fluid pressure, the measured densities at the two frequencies from the Coriolis meter, the measured tube vibration frequency, the ratio of specific heats (K) for the gas, and “trial” values for the decoupling and compressibility parameters to determine gas void fraction as part of the optimizations process.
The simulation utilizes Hemp's model for density errors to simulate the measured densities from a two-frequency Coriolis meter operating on a mixture 55% to 85% watercut with measured mixture sound speeds of 100 to 700 m/sec, operating at a process pressure of 200 psia, with entrained gas with a ration of specific heats of 1.3, where the density of the water is 1000 kg/m{circumflex over ( )}3 and the density of the oil phase is 930 kg/m{circumflex over ( )}3. The Coriolis meter had 2 inch diameter flow tubes which one frequency of vibration at 78 Hz, and one frequency at 420 Hz, with decoupling constants of Kd1=1.2 and Kd2=2.5 and a compressibility parameter of Gd=0.25. Note that the simulation assumes that decoupling parameters and the compressibility parameters remain constant for each of the instances.
The data for the simulation was simulated at 10 instances in which the watercut and the speed of sound of the process fluid were selected randomly between the listed extremes. The measured values for the density measured at the two frequencies, the error factor in the measured densities due to decoupling and compressibility, the reduced frequencies and the process-fluid sound speed are plotted versus gas void fraction in the graph depicted in
The graph in
The graph in
The graph in
The graph in
The mass flow measured at two frequencies can also be used to determine the mass flow decoupling constants Hemp's models. In the example, the simulation utilizes Hemp's model for mass flow errors to simulate the measured mass flows from a two-frequency Coriolis meter operating on a mixture 55% to 85% watercut with measured mixture sound speeds of 200 to 700 m/sec, operating at a process pressure of 200 psia, with entrained gas with a ration of specific heats of 1.3, where the density of the water is 1000 kg/m{circumflex over ( )}3 and the density of the oil phase is 930 kg/m{circumflex over ( )}3. The Coriolis meter had 2 inch diameter flow tubes which one frequency of vibration at 78 Hz, and one frequency at 420 Hz, with density decoupling constants of Kd1=1.2 and Kd2=2.5 and a density compressibility parameter of Gd=0.25. The mass flow decoupling parameters were Km1=2.0 and Km2=2.5 with the mass flow compressibility parameter of Gm=0.5. The mass flow rate was randomly varying between 1.5 and 1.8 kg/sec as described in the graph in
Note that for the mass flow optimization, the liquid phase density remains a necessary input for interpreting the measured process fluid speed of sound, and other parameters of the mixture, in terms of gas void fraction. In this simulation, it is assumed that the density decoupling and compressibility parameters are known prior to the mass flow optimization, by for example, performing a density parameter optimization prior to the optimization to determine the mass flow decoupling parameters.
The graph in
The graph in
The graph in
The graph in
As developed above, the addition of a speed of sound measurement in a process-fluid improves the accuracy of a multiple frequency Coriolis meter operating on either homogeneous flows or nonhomogeneous flows for which compressibility effects can be significant and where decoupling effects are negligible. Decoupling effects approach zero for gas entrained flows for large inverse Stokes numbers, in highly viscous flows or in flows with small bubble sizes. In Hemp's formulation, setting Kd1=Kd2=1 and Km1=Km2=1 eliminates any decoupling between gas and liquid phases.
The compressibility constant in Hemp's formulation can be determined for each vibrational frequency through an optimization process, similar to that developed above for the decoupling constants.
Other objects and features will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed as an illustration and not as a definition of the limits of the invention.
To assist those of skill in the art in making and using the disclosed invention and associated methods, reference is made to the accompanying figures, wherein: Example figure descriptions follow:
Referring to
Referring to
Referring to
One skilled in the art understands that any empirical or computational model that characterizes the relationship between the measured vibrational characteristics of the fluid-conveying flow tube, i.e. tube phase shift and tube natural frequency, and the multiphase flow properties within the meters could be used in similar manner.
In this example the reduced order model of Gysling was used to calculate the apparent mass flow and density “measured” by a dual frequency Coriolis meter operating on a bubbly mixture. The first in-vacuum bending frequency of the tube was set to 300 Hz, and the second was set at 1100 Hz. The tube diameter was 2 inches. The simulated operating conditions for the process fluid for this test case was bubbly mixture of air and water at ambient pressure with 2% gas void fraction. The actual mass flow through the meter was set at 4.0 kg/sec and the liquid density was set at 1000 kg/m{circumflex over ( )}3. The reduced frequency of tube 1 is 0.57 and tube 2 is 2.09. The gas damping ratio, termed the decoupling parameter in the model, was set to 0.5 for both frequencies. The apparent mass flow and mixture density for tube 1 was 4.44 kg/sec and 1038 kg/m{circumflex over ( )}3, and for tube 2, 14.18 kg/sec and 1927 kg/m{circumflex over ( )}3.
Referring to the aforementioned equation:
error≡α{dot over (m)}(({dot over (m)}f1
The trial mass flows and densities are formed by correcting the measured, or apparent, mass flows and densities to actual mass flows and density using the over reading function shown as a surface in
Referring to
Referring to
Referring to
Referring to
Referring to
Referring to
While example embodiments have been described herein, it is expressly noted that these embodiments should not be construed as limiting, but rather that additions and modifications to what is expressly described herein also are included within the scope of the invention. Moreover, it is to be understood that the features of the various embodiments described herein are not mutually exclusive and can exist in various combinations and permutations, even if such combinations or permutations are not made express herein, without departing from the spirit and scope of the invention.
This application is a continuation of co-pending U.S. patent application Ser. No. 16/946,497, filed Jun. 24, 2020, which claims priority to U.S. provisional patent application Ser. No. 62/865,445, filed Jun. 24, 2019, both of which are herein incorporated by reference in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
7134320 | Gysling | Nov 2006 | B2 |
7152460 | Gysling | Dec 2006 | B2 |
7299705 | Gysling | Nov 2007 | B2 |
20190154486 | Zhu | May 2019 | A1 |
Number | Date | Country | |
---|---|---|---|
20220307885 A1 | Sep 2022 | US |
Number | Date | Country | |
---|---|---|---|
62865445 | Jun 2019 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16946497 | Jun 2020 | US |
Child | 17806492 | US |