WO1999044168A1 - Method for measuring and controlling the flow of natural gas from gas wells - Google Patents
Method for measuring and controlling the flow of natural gas from gas wells Download PDFInfo
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- WO1999044168A1 WO1999044168A1 PCT/US1999/004136 US9904136W WO9944168A1 WO 1999044168 A1 WO1999044168 A1 WO 1999044168A1 US 9904136 W US9904136 W US 9904136W WO 9944168 A1 WO9944168 A1 WO 9944168A1
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- 238000000034 method Methods 0.000 title claims abstract description 56
- 239000007789 gas Substances 0.000 title description 91
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Classifications
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01F—MEASURING VOLUME, VOLUME FLOW, MASS FLOW OR LIQUID LEVEL; METERING BY VOLUME
- G01F1/00—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow
- G01F1/05—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects
- G01F1/34—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects by measuring pressure or differential pressure
- G01F1/36—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects by measuring pressure or differential pressure the pressure or differential pressure being created by the use of flow constriction
- G01F1/363—Measuring the volume flow or mass flow of fluid or fluent solid material wherein the fluid passes through a meter in a continuous flow by using mechanical effects by measuring pressure or differential pressure the pressure or differential pressure being created by the use of flow constriction with electrical or electro-mechanical indication
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/12—Methods or apparatus for controlling the flow of the obtained fluid to or in wells
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B47/00—Survey of boreholes or wells
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B2200/00—Special features related to earth drilling for obtaining oil, gas or water
- E21B2200/22—Fuzzy logic, artificial intelligence, neural networks or the like
Definitions
- This invention relates to systems and methods for measuring volume and rate of gas well flow by electrical means using differential pressure with time integration. More specifically it relates to an improved methodology for resolving measurement slippage associated with intermittent or erratic flow conditions in order to enhance accurate gas well flow measurement. In addition it relates to a method for improving gas flow control, and concomitant to that, optimum gas reservoir recovery.
- the recorded data which is available can be manipulated by either the gas producers or the gas purchasers in their favor.
- these measurement errors and the inability to fairly and reliably audit or correct them are the main cause of disputes between gas producers and gas purchasers.
- the lack of audit-trail or analytical quality gas flow trending data which could provide historical profiles of gas reservoir and gas flow performance for each well prevents the gas producer from achieving effective control and optimization of the gas well.
- the lack of analytical quality trending data leads to faulty gas production practices, and as a result, most gas well reservoirs are poorly managed, and fail to allow for well production optimization.
- the most commonly used gas flow measurement system is the mechanical multi-pen chart recorder system.
- EFM electronic flow measurement
- the transducer must be unconditionally infallible, and the gas flow in an ideal condition of no turbulence.
- This ideal condition does not exist in nature, because, as the gas flow rate approaches or falls below a predetermined level, say 10 inches (of water pressure) of differential pressure, the relationship between the differential pressure and the actual flow becomes erratic.
- these systems are not reliable because they rely on a preset moving differential pressure zero (zero cut-off) reference to establish the integration or flow period.
- the accuracy of the typical EFM transducer can be in error by about 0.25% because of total accuracy and transducer drift.
- an EFM system sets the calibration of the transducer at, say exactly 1 volt for 0 inches of differential pressure, and the transducer reading can be in error by as much as say about 0.5 inches. Since the flow calculation is reliant on a differential pressure reading to establish a flow condition, this error causes problems. As a result, the 3 gas flow could be shut off, while the EFM system continues to compute about 50,000 cubic feet of gas per day, and conversely, the flow could actually be 50,000 cubic feet per day, yet the transducer might indicate 0 inches of differential pressure, with the result that the EFM system would calculate no flow.
- the current, but misguided, logic says that the accuracy of the flow computing system is based on the accuracy of the EFM flow transducers which measure line pressure, differential pressure, and temperature and the frequency and speed of the calculations.
- accuracy really depends on precise awareness of the integration period, that is, knowing when true flow/no-flow conditions occur and knowing the true differential pressure based on a dynamically adjusted true zero.
- the imposition of such a zero cut-off prematurely cuts off flow calculation while the well is still flowing. This is the major cause of measurement slippage in EFM systems.
- the zero base flow could also shift positively, and without a zero cut-off, show a difference of 20%.
- the EFM systems convert all engineering values of flow variables, calculate, and store hourly flow volumes at the well head location, which is usually remote from the central operations office. Typically the raw data of the basic flow parameters are discarded during integration, thereby eliminating the audit trail capability of this system. Consequently, the raw data needed for reintegration is unavailable. As a result, recalculation of the local hourly averaged data will not match the average of the integrated flow result because of the square-root effect in the flow formula of the American Gas Association (AGA-3).
- AGA-3 American Gas Association
- the present invention specifically overcomes the disadvantages in the prior art discussed above.
- the method in accordance with the present invention basically includes at least a "remote component system” and a "host component system”.
- the remote component system is located at the well head location, and is usually remote from the central operations office at which the host component system is located.
- the remote component system basically includes some form of electronic computer data logger, such as an electronic chart recording system.
- the electronic data logger of the remote component system is connected to transducers which measure and transmit line pressure, flow differential pressure, and temperature, all as analog data.
- the remote component system is also connected to transducers which measure and transmit the gas well casing pressure and the pressure of the tubing immediately adjacent to the well head, also as analog data.
- the remote component system electronic data logger includes software to trend the analog data accurately, and a memory system to store in a retrievable format- as a function of time, the analog data so collected.
- the memory system also stores and logs digital data of precise events, such as valve positions, to indicate the actual period of gas flow, all as a function of time.
- the remote component system also includes a mechanism for transmitting, using a data compression technique, both analog trending and event log digital data to the host component system, which is normally located at the central operations office, upon request.
- the system and method of the present invention is designed to specifically address the needs of the intermittently flowing well. It has no time span limitations.
- the well can be scanned from the host component system location in seconds for its current flow parameters, and, as a set of specific conditions are met, a control program can be caused to react to those conditions, for example under conditions of low flow pressure, by shutting down the well until certain pressure criteria are met, and then allowing the well to flow again.
- a computer program assists in the calibration of the sensors that monitor the vital temperatures and pressures of the well, thereby also minimizing maintenance cost.
- the auto-calibration and reintegration features in the system of the present invention methodology eliminate the problems due to the failure to accurately measure slippage gas, and can thereby either eliminate or provide data for use in settling disputes as to gas volume between the gas producer and the pipeline operator.
- the host software can also be loaded into a notebook computer and allows the user the portability of using the system in the field.
- FIG. 1 is a schematic representation of gas well head incorporating transducer elements of the remote component system.
- FIG. 2 is a simplified flow-chart of the remote component system of the present invention.
- FIG. 3 is a simplified flow-chart of the host component system of the present invention.
- FIG. 4 is an example of the system of the present invention Trend screen.
- FIG. 5 is a flow-chart of an alternative embodiment of the remote component system of the present invention.
- FIG. 6 is a flow-chart of an alternative embodiment of the host component system of the present invention.
- FIG. 1 a schematic representation of gas well head, generally 10, incorporating various transducer elements of the remote component system, and from which the typical blow down and separator elements have been removed for simplicity of exposition.
- Various pressure and temperature data is shown for representative purposes only.
- plunger 14 When the well is closed by valve 12, plunger 14 is normally at the bottom of the well tubing, not shown, but when valve 12 is opened, plunger 14 rises through the well tubing to the plunger arrival location 16 to push water, salt water, hydrocarbons and mixtures thereof from the tubing for disposal at blow down and separator elements, not shown. Gas can then flow through tubing 18 through to orifice 20 to provide a differential pressure reading at transducer 22, in the manner which is well known in the art.
- orifice 20 Downstream of orifice 20 are standard temperature transducer 24 and standard static line transducer 26.
- a casing pressure transducer 28 is connected to the well head at the top of the casing, not shown, and tubing pressure transducer 30 is located downstream of well head 10, but upstream of 6 orifice 20.
- Analog and digital data is transmitted from transducers 22 (differential pressure reading), 24 (temperature transducer), 26 (static line transducer), 28 (casing pressure transducer) and 30 (tubing pressure transducer) are electrically connected to input device 34, and thence transmitted to data logging manager 36 for storage on any media, and for further transmission to memory archiving data compression and data management system 38.
- the compressed data is then transmitted to the host component system, generally 40, see FIG. 3. Transmission may be by remote telemetry system 42, as shown, or by direct wiring, which is normally not practical in view of the vast distance between the gas wells and the central operations office.
- Remote telemetry system 42 may most efficiently operate by means of a wireless or conventional phone line system, although other state-of-the-art transmission means, such as satellite transmission, may be used.
- the data management system 38 can be programmed to activate control modules 44 to activate control outputs 46 to, for example, open and close valves in real time to optimize well output.
- the activation of control module 44 and control output 46 may be remotely controlled by telemetry from host component system 40.
- the remote component system of the present invention will continue to scan and save all active analog data received from transducers 22, 24, 26, 28 and 30 at a preset interval.
- the data will be compressed and stored both in short term memory archiving data compression and data management system 38, for say about a one month duration, and optionally, in preferred embodiments, in a mass storage system 48, using state-of-the-art storage devices may be used to store data from the remote component system for the life of the well.
- a mass storage system 48 is a PCMCIA card with up to 100 MB capacity or about 50 years of data storage. Event logs of digital status changes or software status changes will be time stamped and stored in Event log files.
- the host component system of the present invention includes a telemetry driver 48 for receiving data from and sending data to telemetry driver 42.
- this data is then processed through memory archiving data compression AGA-3 flow calculation processor 50 from which it can be evaluated, for example in preferred embodiments by displaying it as a graphic display on graphic display user interface report generation monitor/input device 52.
- a representative example of the trend screen of the system of the present invention is shown in FIG. 4, and is discussed in additional detail below.
- the data will be stored both in short term memory in module 50, again for say about a one month duration, and optionally, in preferred embodiments, in a host mass storage system 54, again using state-of-the-art storage devices.
- the system of the present invention host component system 40 includes a computer, say a personal computer running, for example Windows software, say versions 3.1 and higher, capable of uploading data from the system of the present invention remote component 7 system 32, as well as downloading control strategies back to the remote component system 32, again by means of a wireless or conventional phone line system, for example.
- a computer say a personal computer running, for example Windows software, say versions 3.1 and higher, capable of uploading data from the system of the present invention remote component 7 system 32, as well as downloading control strategies back to the remote component system 32, again by means of a wireless or conventional phone line system, for example.
- Specifically designed computer software a sample of which is submitted with this application, allows the host component system to splice the trending data seamlessly for the life of the well.
- the latest versions of AGA-3 and AGA-8 may be loaded along with software to handle flow calculation to determine gas flow volume.
- the system of the present invention host component system is essentially an electronic chart integrator with no retracing or human intervention required, thereby having high reproducability, and no opportunity for human error.
- the raw database is maintained as a permanent record or audit-trail of the well.
- the flow integration software is based on the event logging of the positions of valve 12, which controls the gas flow based on downloaded control strategy from the host component system 40 to determine when to start and stop flow calculation.
- the zero differential pressure i.e. the millivolt reading of raw data before the valve is open, is used to scale the differential pressure values of the cycle.
- the differential pressure span uses the latest calibrated or manually input value as it displays on the event log of the calibration table.
- This application of the event logs to determine the flow period and the establishment of the actual differential pressure zero base of each flow cycle constitutes a system that eliminates gas measurement slippage caused by differential pressure zero shifting.
- the software allows insertion of the new parameters of scaling factors, gas composition, and basic flow data, thereby providing another invention that effectively expedites the reintegration process to settle any disputes between the producer and the pipeline operator.
- the trend screen of FIG. 4 displays both analog data or process variable trends and the digital event logs along with records of calibration and control-strategy changes, provides critical historical data to effect production optimization. Time bars located at both the top and bottom of the screen can be scrolled to display data for the desired period.
- the top time bar displays the event logs by means of data blocks.
- Data blocks can be color coded for easy recognition. If more than a single event occurs at the remote location at the same time, the number of events which have occurred are displayed on a data block, i.e. "2" and "3" as shown at the top time bar.
- Icons to expand and contract the time scales are provided for the user to analyze and diagnose all the process variables on the trend screen. Markers can be inserted on the screen, and the time span thus marked can be scrolled. Analog data is shown to be displayed beneath the bottom time bar, and event data is shown to be displayed along the top time bar.
- the display feature with the dual time bars to correlate the process variable and the event logs constitute an invention.
- the well control program will be activated only after the applicable control software and all configurable control parameters are downloaded from the host component system.
- the remote component system is equipped with control capability to modify a motorized choke, not shown, or to operate a bi-stable form of a solenoid valve 12 to control the flow 8 of gas delivered to the pipeline.
- a motorized choke can be used to control a gas well production above 200 MCFD and bi-stable solenoid valve 12 is more effective for controlling a gas well with less than 200 MCFD.
- an alarm software package allowing the remote component system to initiate transmission of an alarm message to the host component system 40 is a built in feature of the system.
- a state-of-the-art telemetry package is also provided to allow data exchange with a host component system computer loaded with the system of the present invention host component system software package.
- both the tubing pressure 62 and casing pressure 64 will increase until they reach stable points.
- process variables differential pressure 60, tubing pressure 62, and casing pressure 64 show a characterization or signature of an pre-optimized well.
- the characteristic of 60, 62, and 64 show the characteristic of the well trying to stabilize after a new control parameter was installed.
- the well characteristic after 16th hour shows a stabilization of differential pressure 60, tubing pressure 62, and casing pressure 64 and this will become an optimized signature of the well. This optimized characterization will remain for a period of several months or longer.
- Tubing pressure 62 can be used to diagnose leakage between the well head 10, separator (not shown) and line pressure 26. If leakage occurs, the tubing pressure profile will show a decline after the well is shut.
- the above control strategies allow the well to produce gas at a rate that matches the ability of the reservoir and the line 18 or head 10 pressure.
- the event logs of the control strategies and the presentation of the process variable give the operator an effective tool to dete ⁇ nine the optimum production control strategy for each well.
- the trending data produced by the process of the present invention shows if the well is optimized. Most wells, if properly optimized will remain optimized for at least several months. Since most wells have their own unique signature or trending profile, a trained operator can quickly diagnose any problem well through visual inspection of its trending profile.
- FIG. 5 and 6 are flow-charts of an alternative embodiment of the remote component system and the host component system of the present invention.
- transducers at a gas well head 10 at a remote well site transducers, and more specifically at least a differential pressure transducer 22, a temperature 9 transducer 24 and a static pressure line transducer 26 are placed in analog electric signal transmission connection with a remote component system 32 installed at that remote well site.
- casing pressure transducer 28 and tubing pressure transducer 30 are also placed in analog electric signal connection with the same remote component system 32.
- Remote component system 32 is commissioned with all of the calibration, gas flow parameters, and control configurations needed to operate the process of the present invention, for example in the form of the STELA software listing submitted herewith and incorporated herein, as though set forth in its entirety.
- the input device 34 scans, monitors and receives analog electric data signals from at least the differential pressure transducer 22, temperature transducer 24 and static pressure line transducer 26, as well any other transducers associated with the well head area 10 and linked to the remote component system 32.
- the remote component system 32 also receives digital electric event data signals from associated not shown end-devices such as a state-of-the-art tank level sensor, not shown, a state-of-the-art valve position sensor, a state-of-the-art plunger arrival sensor, and the like. This data is then electrically sent to input device 34, and thence transmitted to data logging manager 36 both for short term storage, and in preferred embodiments, for further transmission to memory archiving data compression and data management system 38. As detailed below, the compressed data is then transmitted to the host component system 40, see FIG. 3, for example by remote telemetry system 42 for further processing.
- end-devices such as a state-of-the-art tank level sensor, not shown, a state-of-the-art valve position sensor, a state-of-the-art plunger arrival sensor, and the like.
- This data is then electrically sent to input device 34, and thence transmitted to data logging manager 36 both for short term storage, and in preferred embodiments, for further transmission to memory archiv
- data management system 38 is programmed to activate control modules 44 to activate control outputs 46 to, for example, open and close gas head 10 well valve 12 in real time, rather than on an arbitrary schedule, thereby optimizing gas output from the well, and thereby, increasing both well efficiency and well life.
- the activation of control module 44 and control output 46 is also managed remotely by telemetry from host component system 40.
- the remote component system 32 continuously scans, at a preset interval, and saves all active analog data received from transducers 22, 24, 26, 28 and 30, and all digital data received from digital electric event data signal transducers 12 and 16.
- That data is then compressed and stored both in short term memory archiving data compression and data management system 38, for say about a one month duration, and in preferred embodiments stored in mass storage system 48 for the life of the well.
- Event data is stored in event logs as retrievable digital data which is time stamped. The data stored in the event log is then used to build up the trend files for both the process variables and event logs, as shown in FIG. 4.
- Remote component system 32 is in electronic communication with host component system 40. However, it should be noted that the remote component system 32 is fully capable of stand-alone operation. It does not rely on the host to function, and is a typical distributed architecture system design. Referring again to flow-chart FIG.
- the telemetry driver 48 of host component system 40 receives data from and sends data to remote telemetry driver 42.
- Data communication between the host component system 40 and the remote component systems 32 is in serial format, for example via the serial data port of an off the shelf computer and modem device, similar to the Internet system. 10 Since most gas well sites do not have conventional phone outlets, wireless telemetry data is the preferred communication device.
- This data is then processed through memory archiving data compression AGA-3 flow calculation processor 50 where it is be evaluated, for example, by displaying it as a graphic display on graphic display user interface report generation monitor/input device 52, as shown in FIG. 4, and discussed in detail above.
- the data is then stored both in short term memory in module 50, and in preferred embodiments, in a host mass storage system 54.
- Host component system 40 includes a computer which is capable of uploading data from the system of the present invention remote component system 32, as well as downloading control strategies back to the remote component system 32.
- the specifically designed computer software again for example in the form of the STELA software listing submitted herewith and incorporated herein, as though set forth in its entirety allows the host component system 40 to splice the trending data seamlessly for the life of the well.
- the latest versions of AGA-3 and AGA-8 are also loaded along with software to handle flow calculation to determine gas flow volume. This allows the recalculation of gas volume for any time period using modified parameters or scaling factors, and also provides a means which may be used to settle volume disputes between producers and pipeline operators.
- the system of the present invention host component system is essentially an electronic chart integrator with no retracing or human intervention required, thereby having high reproducability, and no opportunity for human error.
- the raw database is maintained as a permanent record or audit-trail of the well.
- the flow integration software is based on the event logging of the positions of valve 12 to determine when to start and stop flow calculation.
- the zero differential pressure i.e. the millivolt reading of raw data before the valve is open, is used to scale the differential pressure values of the cycle.
- the differential pressure span uses the latest calibrated or manually input value as it displays on the event log of the calibration table.
- This application of the event logs to determine the flow period and the establishment of the actual differential pressure zero base of each flow cycle constitutes an invention that eliminates gas measurement slippage caused by differential pressure zero shifting.
- the software allows insertion of the new parameters of scaling factors, gas composition, and basic flow data, thereby providing another invention that effectively expedites the reintegration process to settle any disputes between the producer and the pipeline operator.
- communication from with the remote component system 32 to the host component system 40 is on an interrupted mode. But, for example, any alarm at the remote component system 32 is automatically reported to the host component system 40 immediately on a "report-by-exception" basis.
- the host component system 40 is normally located in a central operating office at which field personnel are present.
- the host component system 40 is programmed to scan a plurality, or effectively, all of the remote component systems 32 in the field that it is designed to control, to update the trending files of each well, to generate a field wide report of daily gas flow production data, all the related process variables, and any alarm events.
- This report normally schedule to print each morning, may be quickly reviewed by the responsible field personnel to identify wells with abnormal conditions, such as alarm situations and unusual production. Analysis of the 11 trends of these abnormal wells allows the responsible field personnel to quickly develop a corrective action plan. For example, some wells may need modified control strategies from the host component system 40 to the remote component system 32. Others may require on site visitation to correct the problems.
- the trending analysis provide by the system of the present invention also allows the responsible field personnel to take action on a preventive maintenance basis in order to prevent damaging events, such as liquid spillage or freezing pipe from occurring has been proven to be a very beneficial operating tool.
- the trending profile also provides diagnostic data to determine if the correct orifice meter size is in use.
- Both the producer and the pipeline operator can share the raw database produced by the process of the present invention.
- the host component system 40 is capable of archiving the raw and integrated flow data for the accounting system of both the producer and the pipeline operator. To optimize productivity of the gas well, reservoir trending of tubing and casing pressure profiles via casing pressure transducer 28 and tubing pressure transducer 30 are vital data for proper control strategy.
- a variable choke valve 12 may be used to control the over ranging of the differential pressure and use the energy to extend the gas flow volume.
- an on-off valve 12 controlled by a state-of-the-art bi-stable solenoid is more effective in unloading the well at a cost of over ranging the differential pressure limit in the initial opening period.
- FIG. 4 shows the display of event-logging of both the analog and digital data.
- the digital data including open and/or closed valve positions, the arrival time of the plunger, and the time-stamped record of the digital inputs are displayed along with the analog data. Unlike other solutions, this eliminates dependence on differential pressure data to determine on/off or flow/no-flow conditions.
- the system of the present invention avoids zero-shifting errors by simply stopping the flow calculation when the valve is shut-off. Therefore, the system of the present invention solves the zero shifting problem.
- the system of the present invention eliminates the costly calibration procedure of the flow measurement transducers.
- the system of the present invention achieves software calibration from the PC keyboard instead of on-site adjustment.
- the system of the present invention eliminates storage and 12 archiving limitations of the mechanical chart systems.
- the system of the present invention can store data for the life of the well. Archiving or searching the raw data trend can be easily accomplished by clicking the appropriate icons or buttons on the computer to select the desired data on the screen.
- the transducer In systems that rely on transducers for flow/no-flow determination, the transducer must be absolutely infallible, and the gas flow must be in an ideal condition with no turbulence at the low end, i.e. below 10 inches of differential pressure. These conditions cannot exist because as the gas flow rate approaches or falls below 10 inches differential pressure, the data becomes erratic and unreliable. Also, transducers may lose accuracy over time. Therefore, since the system of the present invention does not rely on transducers, but rather on event logging to indicate precisely when valves are open or closed and the exact time of flow/no-flow periods the data is neither erratic nor unreliable. e) Zero-shift correction.
- this invention provides computer software written to automatically and dynamically establish the true zero base, and therefore true differential pressure base, before opening the well to production on each intermittent cycle.
- the system of the present invention logs raw analog data of the well's flow variables of line pressure, differential pressure, and temperature. The data are retained in original unsealed millivolt values. Therefore, reintegration with a modified scaling factor and zero base, as well as conversion to engineering values can be easily achieved with software. Measurement disputes can be resolved fairly because the original data can be retrieved and used for recalculation by both parties using the established AGA formulas.
- Uncompromised audit trail Uncompromised audit trail.
- the system of the present invention does not need to retrace or manipulate data.
- the original, raw data are available for the life of the well. Any need for recalculation can be met because the raw databases of line pressure, differential pressure, and temperature are easily accessible.
- Programmed control instructions can shut in the well, in real time, when it falls below the accurate differential pressure range at about 10 inches and/or when other parameters (i.e., liquid loading problems) exist. These control actions maintain the flow at accurate ranges while maintaining a high bottom hole pressure. Exerting control over the principles of gas extraction can extend the life of the reserve while keeping the differential pressure at an accurate flowing rate.
- Event logging Event logging.
- the event log is a time-stamped record of the digital inputs; for example, the valve open and closed positions or the plunger arrival status. This eliminates the dependence on differential pressure data alone to determine the on-off or flow-no-flow conditions.
- the trend screen for example as shown in FIG. 4, displays color-coded temperature and pressure readings as a graph along the analytical time bar at the bottom of the screen. Corresponding values display in fields below the time bar. This data display provides the vital information needed 13 for flow analysis.
- color-coded blocks identify specific well events.
- Each block marks an event that is logged on the bar at the time it occurs; if multiple events occur at a single time point, the block indicates the number of events.
- Examples of well events include plunger arrival, changes in valve position, changes in the level of the storage tank that stores produced water and distillate, changes in control parameters, application of AGA-3 parameters, calibration, and others.
- a message box can be opened at an event block on the trend screen which itemizes each well event in detail. For example, the message for a selected event block might inform the user that the well was shut-in on a specific date and time. Should data require reintegration, the operator can specify the time span to be reintegrated by using a hairline marker available on the button bar. Data not visible on the screen can be accessed by a scroll button.
- the graphical presentation of temperature and pressure data and the digital information available through event log detail provide both optimum flow analysis and indisputable measurement of continuous and intermittent flow.
- the system of the present invention trend screen such as in FIG. 5, has no such time limitation and seamlessly displays all process variables, including tubing and casing pressure trending profiles which yield valuable information about the reservoir performance.
- This invention allows the operator to analyze the well's behavior to determine the best strategy for flow control and elimination of slippage. With the precise stamping of the on-off valve position, the operator does not have to rely on arbitrarily assigned timing periods of opening and closing the well to flow. Referring again to FIG.
- this basic version of the trend screen which is integral to the system of the present invention methodology and software package is used with software which is designed to duplicate the actual characteristics of analog and digital data with respect to time.
- the system of the present invention records the high and low peak values of the analog data for real time analysis.
- the system of the present invention methodology combines flow parameters of static line pressure, differential pressure, and temperature analog data, and shut-in tubing valve status as digital data, and software control operation to provide an auditable electronic flow measurement system for custody transfer of natural gas.
- the system of the present invention is capable of resolving measurement slippage associated with intermittent or erratic flow conditions.
- the system of the present invention also simplifies calibration procedure of the analog instruments because it retains the raw database for software calibration.
- the system of the present invention Trend screen provides easy to interpret and analyze color-coded well data.
- the user selects the analog data to display data such as casing pressure, tubing pressure, line pressure, or differential pressure, line or glycol temperatures, and so on, on the time line at the lower edge of the screen.
- the user can also select well events to be time stamped, i.e. records of digital inputs such as open and closed positions of the value or plunger 14 arrival status, which are displayed on the time line at the upper edge of screen.
- the user of the system of the present invention methodology has precise measurements of flow, precise knowledge of the exact flow period, the ability to auto-calibrate analog instruments, and the ability to reintegrate raw data when corrections are needed, as for example, calculations based on the wrong size orifice plate or calculations based on erroneous gas parameters, could be easily corrected with this invention. It is therefore seen that the present invention provides a highly reliable, more accurate, and more economical methodology that can be used to precisely measure flow volume without time span limitations, accurately pinpoint flow and no-flow situations, and retain raw data to ensure accurate reintegration.
- the host component system 40 of the present invention may be loaded into a notebook computer having a modem and will allow direct connection with the system of the present invention remote component system from any phone line or cell phone to interrogate or upload-download control strategies from or to the remote component system 32.
Abstract
Description
Claims
Priority Applications (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP99908478A EP1060450A4 (en) | 1998-02-25 | 1999-02-25 | Method for measuring and controlling the flow of natural gas from gas wells |
JP2000533849A JP2002505435A (en) | 1998-02-25 | 1999-02-25 | Method and apparatus for measuring and controlling the flow of natural gas from a gas well |
CA002320875A CA2320875C (en) | 1998-02-25 | 1999-02-25 | Method for measuring and controlling the flow of natural gas from gas wells |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US09/030,275 | 1998-02-25 | ||
US09/030,275 US5983164A (en) | 1997-02-25 | 1998-02-25 | Method and apparatus for measuring and controlling the flow of natural gas from gas wells |
Publications (1)
Publication Number | Publication Date |
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WO1999044168A1 true WO1999044168A1 (en) | 1999-09-02 |
Family
ID=21853418
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/US1999/004136 WO1999044168A1 (en) | 1998-02-25 | 1999-02-25 | Method for measuring and controlling the flow of natural gas from gas wells |
Country Status (5)
Country | Link |
---|---|
US (1) | US5983164A (en) |
EP (1) | EP1060450A4 (en) |
JP (1) | JP2002505435A (en) |
CA (1) | CA2320875C (en) |
WO (1) | WO1999044168A1 (en) |
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Also Published As
Publication number | Publication date |
---|---|
US5983164A (en) | 1999-11-09 |
JP2002505435A (en) | 2002-02-19 |
EP1060450A4 (en) | 2005-01-26 |
CA2320875A1 (en) | 1999-09-02 |
EP1060450A1 (en) | 2000-12-20 |
CA2320875C (en) | 2008-11-25 |
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