Abstract:
A Coriolis flowmeter is operable as a vibrating tube densitometer where a flowtube is driven to vibrate at a fundamental frequency from which density of the material flowing through the flowtube may be calculated. The drive gain is monitored as an indicator of multiphase flow including gas and liquid components where a substantial increase in drive gain indicates gas damping of the flowtube vibrations due to a transient bubble entering the flowtube. The gas damping effects of the transient bubble and the correspondingly reduced density readings are remediated by the use of historical density measurements corresponding to periods of flow when no transient bubble has entered the flowtube.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention pertains to Coriolis effect mass flowmeters. More particularly, the Coriolis effect mass flowmeters contain self diagnostics that improve the accuracy obtainable from the meters in measuring two phase flow including mixtures of gas and liquid, or in identifying measurements that may be affected by the deposition of scale or wax inside the meter. 
     2. Statement of the Problem 
     Coriolis flowmeters directly measure the rate of mass flow through a conduit. As disclosed in the art, such as in U.S. Pat. No. 4,491,025 (issued to J. E. Smith et al. on Jan. 1, 1985 and hereinafter referred to as the U.S. Pat. No. 4,491,025) and Re. 31,450 (issued to J. E. Smith on Feb. 11, 1982 and hereinafter referred to as the U.S. Pat. No. Re. 31,450), these flowmeters have one or more flowtubes of straight or curved configuration. Each flowtube configuration in a Coriolis mass flowmeter has a set of natural vibration modes, which may be of a simple bending, torsional or coupled type. Fluid flows into the flowmeter from the adjacent pipeline on the inlet side, is directed through the flowtube or tubes, and exits the flowmeter through the outlet side of the flowmeter. The natural vibration modes of the vibrating, fluid filled system are defined in part by the combined mass of the flowtubes and the fluid within the flowtubes. Each flow conduit is driven to oscillate at resonance in one of these natural modes. 
     When there is no flow through the flowmeter, all points along the flowtube oscillate with identical phase. As fluid begins to flow, Coriolis accelerations cause each point along the flowtube to have a different phase. The phase on the inlet side of the flowtube lags the driver, while the phase on the outlet side leads the driver. Sensors can be placed on the flowtube to produce sinusoidal signals representative of the motion of the flowtube. The phase difference between two sensor signals is proportional to the mass flow rate of fluid through the flowtube. A complicating factor in this measurement is that the density of typical process fluids varies. Changes in density cause the frequencies of the natural modes to vary. Since the flowmeter&#39;s control system maintains resonance, the oscillation frequency varies in response. Mass flow rate in this situation is proportional to the ratio of phase difference and oscillation frequency. 
     U.S. Pat. No. Re. 31,450 discloses a Coriolis flowmeter that avoids the need of measuring both phase difference and oscillation frequency. Phase difference is determined by measuring the time delay between level crossings of the two sinusoidal signals. When this method is used, the variations in the oscillation frequency cancel, and mass flow rate is proportional to the measured time delay. This measurement method is hereinafter referred to as a time delay measurement. 
     A problem in currently available Coriolis flow measurement apparatus is a limited suitability to gas applications. Gases are less dense than liquids and consequently, at the same flow velocities, smaller Coriolis accelerations are generated. This situation requires a higher sensitivity flowmeter. Alternatively, a flowmeter with conventional sensitivity could be used, if the flow velocity is increased to achieve the same Coriolis accelerations. Unfortunately, this alternative leads to a flowmeter having a sensitivity that is not constant. 
     The problems with gas flow through Coriolis flowmeters are exacerbated in systems with multiphase flow including liquids and gas. The gas damps the system with the effect of reducing sensitivity to measurement. This damping effect can be so severe that the meter cannot perform flow measurements. 
     Situations involving the use of Coriolis flowmeters to measure multiphase flow often arise in the petroleum industry where oil wells produce oil, gas, and water. Gas wells similarly produce gas, condensate and water. U.S. Pat. No. 5,654,502 describes a well test system where a manifold is configured to flow a selected well through a test separator, which separates the production from the well into respective portions including gas, oil or condensate, and water. A Coriolis flowmeter is used to measure the mass flow rate of the respective oil and water components. The accuracy of the flowmeter measurements is enhanced by using an electronically derived water cut measurement to correct the measured density of the segregated oil phase for residual water content. This correction process is difficult or impossible to use, in some situations, because not all wells are coupled with a test separator. It is sometimes desirable to measure the flow from a well directly and without the use or expense of a test separator. In these situations, the presence of gas in the system can be a critical limiting factor in the accuracy of measurements that are obtainable from the meter. 
     U.S. Pat. No. 5,029,482 teaches the use of empirically-derived correlations that are obtained by flowing combined gas and liquid flow streams having known mass percentages of the respective gas and liquid components through a Coriolis meter. The empirically-derived correlations are then used to calculate the percentage of gas and the percentage of liquid in a combined gas and liquid flow stream of unknown gas and liquid percentages based upon a direct Coriolis measurement of the total mass flow rate. The &#39;482 patent does not address remediation of the effects of gas damping in the system measurements, though this damping effect may have an effect upon the empirical correlations. 
     Accordingly, there is a true need for a Coriolis flowmeter that is less sensitive to the effects of gas damping upon density measurements in multiphase flow. 
     SOLUTION 
     The present invention overcomes the problems outlined above and advances the art by providing a Coriolis flowmeter that is less sensitive to the effects of gas damping upon density measurements in multiphase flow. The meter electronics are programmed for special processing that compares drive gain against a threshold value as an indicator of multiphase flow. 
     The Coriolis flowmeter is broadly capable of use as a vibrating densitometer in multiphase flow environments including combinations of gas and liquids, gas and solids, or solids and liquids. The flowmeter includes at least one flowtube and a driver for vibrating the flowtube at a fundamental frequency corresponding to a density of material flowing through the flowtube. The meter electronics monitor drive gain in the vibrating flowtube for a change in value to determine the existence of multiphase flow through said flowtube. This change in value is typically a comparison against a threshold value where multiphase flow including gas and liquid is indicated by the drive gain exceeding the threshold value. A second comparison may be made against a second threshold value to indicate the existence of multiphase flow including gas and solids, liquid and solids, or liquid, gas and solids, which may exhibit similar damping effects to those of gas and liquid systems. The meter electronics respond to the existence of multiphase flow in said flowtube for the duration of the multiphase flow. This response is typically the provision of historical density data for use in determining volumetric flow rates from real time mass flow rate data from said meter. Other useful density values for use during the interval of damped multiphase flow may include density measurements obtained from selected components of the multiphase fluid. 
     The historical density values for use during the interval of damped multiphase flow are typically averaged over an interval of time to provide an average density value. These values may also be subjected to statistical analysis to eliminate or reduce spurious measurements from being included in the average density value. As an alternative to using historical measurement data, density values for representative fluids may be obtained from laboratory measurements or from empirically derived correlations for fluid properties including density. 
     The Coriolis flowmeter is intended for use in any environment where multiphase flow exists, where multiphase flow is defined as flow including at least two states of mater: solid, liquid or gas. The flowmeter is especially useful in multiphase systems including gas and liquid or gas and solids. These environments are especially common in the petroleum industry where a producing oil well or gas well can flow mist, bubbles, or other multiphase fluid systems. The flowmeter is especially useful in performing flow tests upon wells to determine the volumetric flow rates of a well as to water, gas, and oil or condensate. In these situations, the meter electronics can take action to overcome the problem of gas damping directly by increasing the backpressure on the well to force gas into solution or by indicating an alarm condition to request operator intervention. 
     The invention also pertains to control software including instructions for accomplishing the objectives of the invention. Specifically, the instructions are operational when executed by a processor to direct the processor to receive drive gain inputs from a Coriolis meter and process the drive gain inputs, process the drive gain inputs to determine the existence of multiphase flow through the Coriolis flowmeter by comparing the drive gain inputs against a threshold value indicative of multiphase flow, and providing outputs including a historical density value not representative of actual density measurements for the duration of the multiphase flow. These instructions are stored on a machine readable storage medium for retrieval as needed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  depicts a Coriolis flowmeter; 
         FIG. 2  is a block diagram of the meter electronics in the Coriolis flowmeter; 
         FIG. 3  depicts a schematic diagram of a vibrating spring and weight system; 
         FIG. 4  depicts a schematic diagram of a vibrating spring and weight system like that of FIG.,  3  but additionally including a gas damper that is analogous to gas in a multiphase flow system; 
         FIG. 5  depicts a plot of transmissivity versus vibrational frequency including a comparison between a hypothetical liquid system and a hypothetical liquid system that is damped by the addition of a gas component in multiphase flow; 
         FIG. 6  depicts a plot of drive gain versus time during a transient bubble event that requires remediation; 
         FIG. 7  depicts a schematic process control diagram demonstrating a method for remediation of the transient bubble event shown in  FIG. 6 ; and 
         FIG. 8  depicts a schematic block diagram of a well test system incorporating control circuitry capable of implementing the method shown in FIG.  7 . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Coriolis Flowmeter in General— FIG. 1   
       FIG. 1  illustrates a Coriolis flowmeter  5  comprising a flowmeter assembly  10  and meter electronics  20 . Meter electronics  20  is connected to meter assembly  10  via leads  100  to provide density, mass flow rate, volume flow rate, totalized mass flow and other information over path  26 . It should be apparent to those skilled in the art that the present invention can be used by any type of Coriolis flowmeter regardless of the number of drivers or the number of pick-off sensors. 
     Flowmeter assembly  10  includes a pair of flanges  101  and  101 ′, manifold  102  and flowtubes  103 A and  103 B. Connected to flowtubes  103 A and  103 B are driver  104  and pick-off sensors  105  and  105 ′. Brace bars  106  and  106 ′ serve to define the axes W and W′ about which each flowtube  103 A and  103 B oscillates. 
     When flowmeter assembly  10  is inserted into a pipeline system (not shown) which carries the material being measured, material enters flowmeter assembly  10  through flange  101 , passes through manifold  102  where the material is directed to enter flowtubes  103 A and  103 B, flows through flowtubes  103  A and  103 B and back into manifold  102  where it exits meter assembly  10  through flange  101 ′. 
     Flowtubes  103 A and  103 B are selected and appropriately mounted to manifold  102  so as to have substantially the same mass distribution, moments of inertia, and elastic modules about bending axes W-W and W′-W′ respectively. The flowtubes extend outwardly from the manifold in an essentially parallel fashion. 
     Flowtubes  103 A-B are driven by driver  104  in opposite directions about their respective bending axes W and W′ and at what is termed the first out of bending fold of the flowmeter. Driver  104  may comprise one of many well known arrangements, such as a magnet mounted to flowtube  103 A and an opposing coil mounted to flowtube  103 B. An alternating current is passed through the opposing coil to cause both tubes to oscillate. A suitable drive signal is applied by meter electronics  20 , via lead  110  to driver  104 . 
     The description of  FIG. 1  is provided merely as an example of the operation of a Coriolis flowmeter and is not intended to limit the teaching of the present invention. The present invention is equally applicable to other types of Coriolis flowmeter including single tube meters, as well as those having multiple pickoffs or multiple drivers. 
     Meter electronics  20  receives the right and left velocity signals appearing on leads  11  and  111 ′, respectively. Meter electronics  20  produces the drive signal on lead  110  causing driver  104  to oscillate flowtubes  103 A and  103 B. The present invention as described herein, can produce multiple drive signals from multiple drivers. Meter electronics  20  process left and right velocity signals to compute mass flow rate and provide the validation system of the present invention. Path  26  provides an input and an output means that allows meter electronics  20  to interface with an operator. 
     Meter Electronics  20  in General— FIG. 2   
       FIG. 2  illustrates a block diagram of the components of meter electronics  20  which perform the processes related to the present invention. Paths  111  and  111 ′ transmit the left and right velocity signals from flowmeter assembly  10  to meter electronics  20 . The velocity signals are received by analog to digital (A/D) convertor  203  in meter electronics  20 . A/D convertor  203  converts the left and right velocity signals to digital signals usable by processor  201  and transmits the digital signals over path  213  to I/O bus  210 . The digital signals are carried by I/O bus  210  to processor  201 . Driver signals are transmitted over I/O bus  210  to path  212  which applies the signals to digital to analog (D/A) convertor  202 . The analog signals from D/A convertor  202  are transmitted to driver  104  via path  110 . Path  26  is connected to I/O bus  210  and carries signals to input and output means (not shown) which allow meter electronics  20  to receive data from and convey data to an operator. 
     Processor  201  reads instructions for performing the various functions of the flowmeter including but not limited to computing mass flow rate of a material, computing volume flow rate of a material, and computing density of a material from a Read Only Memory (ROM)  220  via path  221 . The data as well as instructions for performing the various functions are stored in a Random Access Memory (RAM)  230 . Processor  201  performs read and write operations in RAM memory  230  via path  231 . In a larger sense, meter electronics  20  include additional control instrumentation and other processors that may optionally be connected to meter electronics  20  on path  26 . Fluid Density Calculations 
       FIG. 3  depicts an undamped dynamic spring assembly  300  that operates on the same physical principles as flowtubes  103 A and  103 B of Coriolis flowmeter  5  (see  FIG. 1 ) in single phase flow. Spring  302  is connected to an anchor  304  and a mass  306 . The mass  306  reciprocates or vibrates on a path parallel to double headed arrow  308 . The natural frequency, f n  of assembly  300  is: 
               f   n     =       1     2   ⁢   π       ⁢         K   s     m                 (   1   )               
where K s  is the spring constant of spring  302  and m is the mass of mass  306 . In the case of Coriolis flowmeter  5 , m is the combined weight of the flowtubes  103 A and  103 B together with the mass of material inside the tubes.
 
     Where equation (1) is applied to a flowtube  103 A or  103 B, it becomes: 
             ρ   =       A     f   n   2       -   B             (   2   )             
 
where A and B are calibration constants determined in a conventional manner for Coriolis flowmeters, ρ is the density of the media flowing through the flowtube, and f n  is the natural frequency. Thus, by knowing the natural frequency, one can determine the density of the fluid.
 
     Coriolis flowmeters measure mass flow rates by measuring the Coriolis twisting of a vibrating sensor tube, e.g., one of flowtubes  103 A and  103 B (see FIG.  1 ). The sensor tube vibrations have the effect of changing the angular momentum of fluid or fluids flowing inside the tube. The Coriolis twisting force is relatively small, and the flowtubes are relatively stiff. In order to make the tube vibrate with sufficient amplitude to make the Coriolis twisting force detectable, the meter electronics  20  provide a drive voltage to drive coil  104  that vibrates the flowtube or tube at its natural frequency. Thus, processor  201  (see  FIG. 2 ) provides output that continuously maximizes the transmissivity ratio or drive gain in a conventional manner for Coriolis flowmeters. For example, the drive voltage is typically increased as the transmissivity ratio or drive gain decreases. At the same time, the drive voltage cannot be increased beyond some maximum limiting value, or else the voltage will eventually become too great with the result that the meter is damaged by excessive voltage or excessive vibration amplitudes. 
     The Effect of Gas Damping on the System 
       FIG. 4  depicts a damped dynamic spring and mass assembly  400  that operates on the same physical principles as flowtubes  103 A and  103 B of Coriolis flowmeter  5  (see  FIG. 1 ) in multiphase phase flow including gas and liquid. Where possible, like numbering in  FIG. 3  has been retained for identical elements in FIG.  4 .  FIG. 4  differs from  FIG. 3  by the addition of a damper  402 , which has the effect of reducing the amplitude of vibration along path  308 ′. Equations (1) and (2) still apply to the system shown in  FIG. 4 , but the overall magnitude of vibration is less due to damper  402 . 
       FIG. 5  is a plot of hypothetical data demonstrating the practical effects of gas damping on the frequency response of flowtubes  103  A and  103  B in Coriolis flowmeter  5  (see also FIG.  1 ). The log of transmissivity is plotted as a function of the frequency of alternating voltage applied to the drive coil  104 , e.g., at frequencies f 0 , f 1 , and f 2 . The transmissivity ratio T r  equals the pickoff output divided by the drive input, i.e., T r  is the drive gain: 
               T   r     =       OUTPUT   INPUT     =         V   pc     ⁢   PICKOFF   ⁢           ⁢   COIL         V   dc     ⁢   DRIVE   ⁢           ⁢   COIL                 (   3   )               
where V ac  pickoff coil is the alternating voltage on leads  111  and  111 ′ from pickoffs  105  and  105 ′ and V ac  drive coil is the alternating voltage on lead  110  to drive coil  104 . These voltages may be adjusted proportionally by a calibration constant to account for differences in scale between the drive coil  104  and pickoffs  105  and  105 ′.
 
     A first curve  500  corresponds to the undamped system of Equation (1) and  FIG. 3 , i.e., no gas is present in the fluid being measured. A second curve  502  corresponds to the damped system of Equation (3). Both curves  500  and  502  have an optimal value  504  and  504 ′, respectively, at the natural frequency f n . The region  506  of curves  500  and  502  to the left of f n , represents a situation where the flowtubes  103 A and  103 B (see  FIG. 1 ) are vibrating in phase. The region  508  of curves  500  and  502  to the right of f n  represents a situation where the flowtubes  103 A and  103 B (see  FIG. 1 ) are vibrating out of phase. The optimal point  504 ′ is more difficult to detect than optimal point  504  due to the reduced amplitude of optimal point  504 ′. As the amplitude decreases due to gas damping, the Coriolis flowmeter  5  (see  FIG. 1 ) can no longer perform effective flow measurements, depending upon the sensitivity of the flowmeter. 
     The meter electronics  20  are designed to monitor drive gain or transmissivity and to optimize the amplitude of transmissivity based upon a ratio of the voltage at the pickoff coil divided by the voltage at the drive coil. This optimization is performed based upon a slope analysis of curve  500 . For example, a first forward difference taken from new data generated by a faster frequency of vibration at the drive coil will produce a slope having a zero value (optimized condition), a negative value (region  508 ), or a positive value (region  506 ). The meter electronics then drive the vibration faster or slower, as need is indicated by the slope of the data, until an optimized transmissivity is obtained.  FIG. 6  is a plot of hypothetical data showing the relationship between drive gain and time for an event  600  where a transient bubble enters a Coriolis flowmeter  5  (see  FIG. 1 ) at time  602  and exits at time  604 . Drive gain is expressed as a percent in  FIG. 6 , and plotted as a function of time at intervals, e.g., t 1 , t 2 , and t 3 . According to the concept of the present invention, processor  201  (see also  FIG. 2 ) is programmed with a threshold value  606  based upon drive gain or transmissivity. Where the drive gain or transmissivity of curve  608  exceeds threshold  606 , processor  201  ceases to use a density value calculated in the conventional manner according to Equation (2). Processor  201  then proceeds to calculate density according to the flow chart shown ibn FIG.  7 . 
     The effects shown in  FIGS. 5-6  are similar to the effects of multiphase flow including liquids and solids, e.g., with paraffin, sand, or scale in the fluid, or with scale having actually built up on the internal flowtube walls of flowtubes  103 A and  103 B. Thus, a system capable of detecting gas and liquid multiphase flow is also capable of detecting, using the same principles, multiphase flow including gas and solids, liquid and solids or scale internal to the flowtubes. 
     Transient Bubble Remediation Mode 
     It is always preferred to use measurements obtained according to Equation (2) for meter outputs including density values; however, it is not always possible to use Equation (2) due to the deleterious effects of gas damping in multiphase flow.  FIG. 7  depicts a process P 700  for remediation of density values when a transient bubble enters Coriolis flowmeter  5  with the effect of gas damping the system. Process P 700  has been developed according to the premise that, while gas damping may create real-time measurement difficulties, the next best value for density obtainable from the Coriolis flowmeter is a recently measured density. The respective steps of process P 700  are described in the context of reference numbers also appearing in FIG.  6 . 
     In step P 702 , processor  201  determines that the drive gain has exceeded threshold  606  as a consequence of curve  608  having crossed threshold  606  at time  602 . Due to the fact that the portion of curve  608  preceding time  602  may have some noise due to a bubble that is about to enter the meter, during step P 704  processor  201  looks back over a predetermined time interval  610  to an averaging interval  612 . Averaging interval  612  may correspond to a single data point, but it preferably comprises an interval including multiple data points for the purpose of smoothing spurious measurements  614  that may spike upwards without exceeding threshold  606 . 
     In step P 706 , processor  201  determines whether any of the measurements in averaging interval  612  exceed threshold  606 . If so, in step P 708 , a multiple or fraction of look back interval  610  may be calculated used to arrive at a new averaging interval  612  through a repetition of step P 704 . If repeated attempts through step P 706  fail to arrive at an interval  612  having no points greater than threshold  606 , then spurious measurements e.g., measurement  614 , including those greater than threshold  606  can be eliminated by statistical analysis. This statistical analysis can include calculating a standard deviation and ignoring all numbers outside the standard deviation or ignoring all numbers greater than threshold  606 , so long as some measurements in averaging interval  612  are less than threshold  606 . Alternatively, the processor  201  can be programmed to output a preselected density value, such as may be obtained from laboratory measurements. 
     Step P 710  includes averaging the density values over averaging interval  612  to provide an average representative density value corresponding to averaging interval  612 . The values that are used to calculate this average may be adjusted by statistical analysis as discussed above in relation to step P 706 . In circumstances where meter diagnostics show that the flowmeter is not operating correctly to produce a mass flow rate measurement due to gas damping, the meter output for mass flow rate can also be averaged according to these same principles. 
     According to step P 712 , the processor  201  provides as a meter output the average density value obtained from step P 710  until such time as curve  608  falls below threshold  606  at time  604 . Accordingly, process P 700  concludes at step P 714  with processor  201  leaving the transient bubble remediation mode and returning to meter output consisting of measurements performed according to Equation (2). 
     The precise levels or durations for threshold  606 , look back interval  610 , and averaging interval  610  are associated with the type and size of meter, as well as the intended environment of use. For example, these values are different for meters installed on a well making one thousand barrels of oil per day versus a well making one barrel of oil. In practice, an operator determines the threshold  606  at which the Coriolis flowmeter 5 operates without bubbles. This determination is made by a combination of experience, trial and error, manufacturer&#39;s recommendations, or recording over time in the intended environment of use. The operator enters this value into the meter electronics  20  as a set value for use in process P 700 . The meter electronics continuously monitor the drive gain level. Applications of transient bubble remediation technology are not limited to petroleum industry applications, and include any situation where multiphase flow including gas and liquids may be encountered. 
     The same damping principles shown in  FIG. 5  as a comparison between curves  500  and  502  apply in situations where multiphase flow includes solids and liquids, though to a lesser degree. The multiphase flow can also include a mixture of gas, liquids, and solids. In petroleum industry environments of use, these situations arise where the flow stream includes natural gas, oil or condensate, water, paraffin, sand and/or scale. Thus, the principles of  FIGS. 6 and 7  may be used to remediate erroneous density or mass flow rate measurements due to multiphase flow including solids and liquids or gas and solids, as well as gas and liquids. 
     The above-described process elements are comprised of instructions that are stored on storage media. The instructions can be retrieved and executed by a processor. Some examples of instructions are software, program code, and firmware. Some examples of storage media are memory devices, tape, disks, integrated circuits, and servers. The instructions are operational when executed by the processor to direct the processor to operate in accord with the invention. The term “processor” refers to a single processing device or a group of inter-operational processing devices. Some examples of processors are integrated circuits, computers, and logic circuitry. Those skilled in the art are familiar with instructions, processors, and storage media. 
     Coriolis flowmeters and associated meter electronics that are equipped to implement the principles of transient bubble remediation discussed above can be used in any environment containing multiphase flow, and the meters work especially well to remediate transient mist and fine bubbles. In this context, “transient” means a flow condition that exists temporarily or periodically over time. The meters also work acceptably well to remediate gas effects in slug flow or plug flow conditions, although, the calculated volumetric flow rates are less reliable under these flow conditions than for mist flow conditions. Specific applications include chemical processes with gas genesis in a reactor or process flow line, retort processing of foods, microbiological processes with gas genesis, and any other system with multiphase fluids, such as producing wells in the petroleum industry where a separator has not been installed prior to the meter. 
     A System For Use in Petroleum Well Test Measurements 
     As shown in  FIG. 8 , a schematic block diagram, system  800  includes a manifold  802  having a plurality of electronically actuated wellhead valves  803 ,  803 ′, and  803 ″ that each provide multiphase flow including gas, liquid and solids to tubing  804 . Valves  803 ,  803 ′ and  803 ″ are preferably three-way electronically-initiated, pneumatically actuated valve, such as the Xomox TUFFLINE037AX WCB/316 well switching valve with a MATRYX MX 200 actuator. Valves  803 ,  803 ′ and  803 ″ are selectively configured to provide multiphase flow from one well at a time through manifold  802  and tubing  804  to Coriolis flowmeter  806 , which may be the same as Coriolis flowmeter  5 . Coriolis flowmeter  806  measures the volumetric flow rate of one of the wells connected to valves  803 ,  803 ′, or  803 ″. The volumetric flow rate of the well helps to determine the contribution of this particular well to total sales. The remainder of material from the other wells connected to valves  803 ,  803 ′, and  803 ″ flow through the line  808  for passage through second meter  810 , which may be a sales meter. Flow through Coriolis flowmeter  806  discharges into meter discharge line  812  and enters water cut meter  812 . The flow is thereafter combined with the flow in gathering line  808  for measurement through second meter  810 . Exemplary forms of flowmeters  806  and  810  include the ELITE Models CMF 300356NU and Model CMF300H551NU, which are available from Micro Motion of Boulder, Colo. 
     System  800  includes a computer  816  (e.g., an IBM compatible machine) that is programmed with data acquisition and programming software. A preferred form of this software is the Intellution software DMACS, which is available from INTELLUTION, a subsidiary of Emerson Electric. This software is particularly preferred because it can generate alarms that indicate abnormal well test conditions representative of mechanical failures which are potentially dangerous. Computer  816  controls the programming of remote operations controller  818 , which includes a plurality of drivers and interfaces that permit computer  816  to interact with remote components of system  800 . A preferred form of remote operations controller  818  is the Fisher Model ROC364. Controller  818  may also be programmed with software to facilitate the implementation of control instructions from computer  816 . 
     Valve control leads  820 ,  820 ′ and  820 ″ connect controller  818  with the Lead  822  connects controller  818  with pressure transmitter  824   electrically actuated valves  803 ,  803 ′, and  803 ″ for selective control of the valves. An exemplary form of transmitter  824  is the ELITE Model RFT9739, which is available from Micro Motion of Boulder, Colo. Lead  826  connects controller  818  with water-cut meter  814 . The functions of controller  818 , transmitter  824 , and computer  816  may be combined in a single processor, such as processor  201  of meter electronics  20  (see FIG.  2 ). 
     System  800  operates as follows. Manifold  802  carries a material from single valve  803 ,  803 ′, or  803 ″ to flow through Coriolis flowmeter  806  to test a well or provide mass flow rate information concerning a well connected to the single valve  803 ,  803 ′, or  803 ″. The material flowing through the remaining valves  803 ,  803 ′, or  803 ″ flow into gathering line  808  for combined sales output through second meter  810 . Coriolis flowmeter  806  provides density and mass flow rate information as meter outputs to transmitter  824  which, in turn, provides signals to controller  818  on lead  822 . One of computer  816 , controller  818 , transmitter  824  or Coriolis flowmeter  806  (typically computer  816  ) performs a calculation for total volumetric flow rate Q e  according to Equation (4): 
               Q   r     =       M   c       D   c               (   4   )             
 
wherein M e  is a Coriolis-based mass flow rate measurement obtained from the total combined oil and water flow stream; and D e  is a density of the total combined oil, gas, water and solids flow stream at a measurement temperature T.
 
     A volumetric flow rate of oil is calculated according to Equation (5):
 
Q o =Q e (1−X w )  (5)
 
wherein Q o  is a volumetric flow rate of oil; X W  is the fractional flow rate of water, and the remaining variables are defined above.
 
     A volumetric flow rate of water is calculated according to Equation (6):
 
Q w =Q e *X w   (6)
 
wherein Q w  is a volumetric flow rate of water, and the remaining variables are defined above.
         The volumetric flow rate values Q o  and Q w  can be corrected to a standard reference temperature, T ref , through multiplication of the volumetric flow rate values by the density at a measurement temperature and dividing by the density at the reference temperature, e.g., as in Equation (7): 
               Q   w     =       Q     o   .   T       =       D     0.   ⁢   T         D   0                 (   7   )             
 
wherein Q o  is a volumetric oil flow rate at a standard reference temperature T ref ; Q o,T  is a volumetric oil flow rate measured at temperature T and calculated according to Equation (5); Do is a measured density of oil from laboratory measurements at reference temperature T ref ; and D o,T  is a density of oil measured at temperature T.
       

     The fractional flow rate of water is calculated as: 
               X   w     =         D   c     -     ρ     o   .   t             ρ     w   .   T       -     ρ     o   .   T                   (   8   )             
 
wherein D e  is a density of the total combined oil (or condensate) and water flow stream at a measurement temperature T. ρ o,T  is a density of the pure oil (or condensate) phase excluding any residual water content of the segregated oil component; ρ W,T  is a density of the pure water phase; and the remaining variables are defined above.
 
     The value X W  is a ‘water-cut’ measurement, which is an important result of well test measurements. The term ‘water-cut’ is hereby defined as any ratio that represents a relationship between a volume of oil and a volume of water in an oil and water liquid mixture. Water-cut meter  814  uses capacitance, resistance, microwave radiation or other measurements to quantify the water-cut. In some circumstances, the volume of water is so great that it exceeds the limits of the instrumentation. For example, capacitance or resistance monitors provide acceptably accurate water-cut measurements only where the water volume is less than about 20% to 30% of the total flow stream. The upper 30% accuracy limit is far below the level that is observed from many producing wells. For example, the total liquid production volume of an oil well can be 99% water. Some water-cut monitors, therefore, are relegated to determining the water-cut in an oil component that has a low water content. Water-cut monitors most often cannot be used to determine the water content in the material that flows from a two phase separator because the total liquid component has a water content that exceeds the 30% upper accuracy limit. An exemplary form of water cut monitor  66  is the Drexelbrook Model CM-2 capacitance monitor. Accordingly, Equation (8) provides a method for calculating water cut and the volumetric flow rate of water and oil or condensate. The values ρ o,T  and ρ w,T  can be obtained from conventional laboratory measurements of produced fluids from a particular well. 
     Where the value X W  is within the performance and accuracy limits of water cut meter  814 , the oil density may be corrected for water content as follows: 
               ρ     o   .   t       =         ρ   t     -       ρ     w   .   T       ⁢   WC         1   -   WC               (   9   )             
 
     wherein ρ o,T  is water-corrected oil density at temperature T; ρ t  is the total density of the combined water-cut liquid as measured by the Coriolis flowmeter  806  at temperature T; ρ w  is the density of the water component established by laboratory measurement or a conventional empirical temperature-salinity correlation at temperature T; and WC is the water-cut measured by the water-cut monitor  814 . 
     In summary, it is necessary to convert meter liquid measurements from mass flow rates into volumetric flow rates for sales purposes because petroleum products are sold by volume. Density values are used to perform the conversion from mass flow rate into a volumetric flow rate. The fractional flow rates of water and oil are determinable by direct measurement of water cut, but this method does not always work due to instrumentation constraints inherent to water cut meters. The direct measurement of water cut can also be used to calibrate the meter for a changing oil density value over the life of a producing well. Water cut is determinable from the density measurement if the respective densities of water and oil are known from other sources. Gas damping on the system interferes with these calculations according to Equations (8) and (9) because damping may be so severe that the the meter ceases to provide accurate density readings of material flowing through the flowtubes or because the measured density represents a sufficient gas content to destroy the assumption of two phase flow that is inherent to Equations (8) and (9). The rate of gas flow can be determined by empirical correlations according to U.S. Pat. No. 5,029,482, which is hereby incorporated by reference to the same extent as though fully disclosed herein. 
     It follows that computer  816  or controller  818  of  FIG. 8  have the option of processing using a density or mass flow rate value obtained according to  FIG. 7  while a transient bubble is detected within flowmeter  806 . Alternatively, if use of the average value from interval  612  is not desired, alternative options include stopping the well test or indicating an alarm for operator intervention. Yet another option is for computer  816  to signal controller  818  to partially close the selected one of valves  803 ,  803 ′ or  803 ″ to increase the back-pressure on the well. In the case of an oil well, this backpressure may force liberated gas back into solution, thereby completely or partially overcoming the effects of gas damping on Coriolis flowmeter  806  by the total or partial elimination of gas from the production fluid. 
     Equations (8) and (9) specifically refer to oil and water, but the equations more broadly refer to any dual phase immiscible liquid system, e.g., any colloidal solution, that may also be affected by gas as a third phase. The deleterious effects of gas upon these systems includes more than mere damping because X W  values calculated using the density from equation (8), as corrected by Equation (9), has error due to the reduced density value D e  when the equations were developed on the assumption of dual phase immiscible liquids without taking gas into consideration. 
     Those skilled in the art will understand that the preferred embodiments described above may be subjected to apparent modifications without departing from the true scope and spirit of the invention. The inventor, accordingly, hereby states his intention to rely upon the Doctrine of Equivalents, in order to protect his full rights in the invention.