Aspects of the present disclosure generally relate to hydrocarbon production using gas lift and, more particularly, to operating a gas lift unit in a wellbore based on measurements of one or more sensed parameters associated with the gas lift unit and/or the wellbore.
Several artificial lift techniques are currently available to initiate and/or increase hydrocarbon production from drilled wells. These artificial lift techniques include rod pumping, plunger lift, gas lift, hydraulic lift, progressing cavity pumping, and electric submersible pumping, for example.
Typical gas lift techniques involve pumping a lift gas down the casing-tubing annulus of a well. The lift gas travels down the casing-tubing annulus to one or more subsurface gas injection valves that enable the lift gas to enter the tubing string. The lift gas commingles with the reservoir fluids in the tubing string, lifting the reservoir fluids up the tubing string to the surface. Oil in the fluids may then be recovered.
A gas lift system may be operated on a continuous basis, in which the lift gas is continuously injected into the well, or on an intermittent basis, in which the lift gas is injected for a first period (e.g., an “on time”) and then the injection is stopped for a second period (e.g., an “off time”). The periods may be the same or different lengths. The intermittently operated gas lift system may repeat the periods, or the lengths of the periods may be adjusted one or more times per cycle.
The injection rate of the lift gas, length of time for gas injection (e.g., the on time), and length of time between stopping gas injection and restarting the gas injection (e.g., the off time) all affect the quantity of oil recovered from a well. Gas lift systems entail an investment of capital to implement and cost money to operate. Production companies prefer to maximize the return on capital investments and operating costs. Accordingly, there is a need for apparatus and methods of determining lift gas injection rates, on times, and/or off times of intermittently operated gas lift systems to operate wells using such systems more economically.
Aspects of the present disclosure generally relate to measuring one or more parameters associated with a wellbore and/or a gas lift unit and taking a course of action or otherwise operating the gas lift unit based on the measured parameters.
In one aspect, a method of operating an intermittent gas lift system operable to inject lift gas into a wellbore for hydrocarbon production is provided. The method generally includes causing, by a processing system proximate to the wellbore, injection of the lift gas into the wellbore at a first gas injection rate; obtaining, by the processing system, a first indication of a parameter associated with the wellbore, an arrival of a first fluid at a wellhead associated with the wellbore, or a composition of the first fluid; determining, by the processing system and based on the first indication, at least one of: a second gas injection rate of the intermittent gas lift system, a first period to inject the lift gas with the intermittent gas lift system, or a second period, subsequent to the first period, with no injection of the lift gas by the intermittent gas lift system; and operating, by the processing system, the intermittent gas lift system according to the determination.
In another aspect, a method of operating a gas lift system operable to inject lift gas into a wellbore for hydrocarbon production is provided. The method generally includes obtaining a first indication of a first liquid production rate of the wellbore; obtaining one or more second indications of second liquid production rates of one or more other wellbores; determining a first slope, of a first curve relating a plurality of liquid production rates of the wellbore to a plurality of gas injection rates of the wellbore, at a point on the first curve corresponding to the first liquid production rate; determining one or more second slopes, of one or more second curves, each second curve relating a plurality of liquid production rates of one of the one or more other wellbores to a plurality of gas injection rates of the one of the other wellbores, each second slope being determined at a point on the second curve corresponding to one of the second liquid production rates of the one of the other wellbores; calculating a weighted average of the first slope and the second slopes, with the weighted average weighted based on the first and second liquid production rates of the wellbore and the other wellbores, respectively; determining a first gas injection rate such that a third slope, of the first curve, at a point on the first curve corresponding to the first gas injection rate, is equal to the calculated weighted average; and causing injection of the lift gas into the wellbore at the first gas injection rate.
In another aspect, a method of operating a continuous gas lift system operable to inject a lift gas into a wellbore for hydrocarbon production is provided. The method generally includes causing, by a processing system proximate to the wellbore, injection of the lift gas into the wellbore at a first gas injection rate; obtaining, by the processing system, a first indication of a pressure at a location of the wellbore while the injection of the lift gas at the first gas injection rate is ongoing; determining, by the processing system and based on the first indication and the first gas injection rate, a second gas injection rate for the continuous gas lift system; and causing, by the processing system, the continuous gas lift system to inject lift gas into the wellbore at the second gas injection rate.
In one aspect, a non-transitory computer readable medium containing a program is provided. The program, when executed by a processing system, causes the processing system to perform operations generally including causing injection of a lift gas into the wellbore at a first gas injection rate by an intermittent gas lift system; obtaining a first indication of a parameter associated with the wellbore, an arrival of a first fluid at a wellhead associated with the wellbore, or a composition of the first fluid; determining, based on the first indication, at least one of: a second gas injection rate of the intermittent gas lift system, a first period to inject the lift gas with the intermittent gas lift system, or a second period, subsequent to the first period, with no injection of the lift gas by the intermittent gas lift system; and causing the intermittent gas lift system to operate according to the determination.
In another aspect, a non-transitory computer readable medium containing a program is provided. The program, when executed by a processing system, causes the processing system to perform operations generally including obtaining a first indication of a first liquid production rate of the wellbore; obtaining one or more second indications of second liquid production rates of one or more other wellbores; determining a first slope, of a first curve relating a plurality of liquid production rates of the wellbore to a plurality of gas injection rates of the wellbore, at a point on the first curve corresponding to the first liquid production rate; determining one or more second slopes, of one or more second curves, each second curve relating a plurality of liquid production rates of one of the one or more other wellbores to a plurality of gas injection rates of the one of the other wellbores, each second slope being determined at a point on the second curve corresponding to one of the second liquid production rates of the one of the other wellbores; calculating a weighted average of the first slope and the second slopes, with the weighted average weighted based on the first and second liquid production rates of the wellbore and the other wellbores, respectively; determining a first gas injection rate such that a third slope, of the first curve, at a point on the first curve corresponding to the first gas injection rate, is equal to the calculated weighted average; and causing injection of the lift gas into the wellbore at the first gas injection rate.
In another aspect, a non-transitory computer readable medium containing a program is provided. The program, when executed by a processing system, causes the processing system to perform operations generally including causing injection of lift gas into the wellbore at a first gas injection rate by a continuous gas lift system; obtaining a first indication of a pressure at a location of the wellbore while the injection of the lift gas at the first gas injection rate is ongoing; determining, based on the first indication and the first gas injection rate, a second gas injection rate for the continuous gas lift system; and causing the continuous gas lift system to inject the lift gas into the wellbore at the second gas injection rate.
In another aspect, a controller is provided. The controller includes a processing system configured to perform operations generally including causing injection of a lift gas into the wellbore by an intermittent gas lift system at a first gas injection rate; obtaining a first indication of a parameter associated with the wellbore, an arrival of a first fluid at a wellhead associated with the wellbore, or a composition of the first fluid; determining, based on the first indication, at least one of: a second gas injection rate of the intermittent gas lift system, a first period to inject the lift gas with the intermittent gas lift system, or a second period, subsequent to the first period, with no injection of the lift gas by the intermittent gas lift system; and causing the intermittent gas lift system to operate according to the determination.
In another aspect, a controller is provided. The controller includes a processing system configured to perform operations generally including obtaining a first indication of a first liquid production rate of the wellbore; obtaining one or more second indications of second liquid production rates of one or more other wellbores; determining a first slope, of a first curve relating a plurality of liquid production rates of the wellbore to a plurality of gas injection rates of the wellbore, at a point on the first curve corresponding to the first liquid production rate; determining one or more second slopes, of one or more second curves, each second curve relating a plurality of liquid production rates of one of the one or more other wellbores to a plurality of gas injection rates of the one of the other wellbores, each second slope being determined at a point on the second curve corresponding to one of the second liquid production rates of the one of the other wellbores; calculating a weighted average of the first slope and the second slopes, with the weighted average weighted based on the first and second liquid production rates of the wellbore and the other wellbores, respectively; determining a first gas injection rate such that a third slope, of the first curve, at a point on the first curve corresponding to the first gas injection rate, is equal to the calculated weighted average; and causing injection of the lift gas into the wellbore at the first gas injection rate.
In another aspect, a controller is provided. The controller includes a processing system configured to perform operations generally including causing injection of lift gas into the wellbore at a first gas injection rate by a continuous gas lift system; obtaining a first indication of a pressure at a location of the wellbore while the injection of the lift gas at the first gas injection rate is ongoing; determining, based on the first indication and the first gas injection rate, a second gas injection rate for the continuous gas lift system; and causing, by the processing system, the continuous gas lift system to inject the lift gas into the wellbore at the second gas injection rate.
In another aspect, a system for injecting lift gas into a wellbore for hydrocarbon production is provided. The system generally includes a pump operable to intermittently inject the lift gas into the wellbore; and a processing system coupled to the pump and configured to cause the pump to inject the lift gas into the wellbore at a first gas injection rate; to obtain a first indication of a parameter associated with the wellbore, an arrival of a first fluid at a wellhead associated with the wellbore, or a composition of the first fluid; to determine, based on the first indication, at least one of: a second gas injection rate, a first period to inject the lift gas with the pump, or a second period, subsequent to the first period, with no injection of the lift gas by the pump, and to cause the pump to operate according to the determination.
In another aspect, a system for injecting lift gas into a wellbore for hydrocarbon production is provided. The system generally includes a pump operable to inject the lift gas into the wellbore; and a processing system coupled to the pump and configured to obtain a first indication of a first liquid production rate of the wellbore; to obtain one or more second indications of second liquid production rates of one or more other wellbores; to determine a first slope, of a first curve relating a plurality of liquid production rates of the wellbore to a plurality of gas injection rates of the wellbore, at a point on the first curve corresponding to the first liquid production rate; to determine one or more second slopes, of one or more second curves, each second curve relating a plurality of liquid production rates of one of the one or more other wellbores to a plurality of gas injection rates of the one of the other wellbores, each second slope being determined at a point on the second curve corresponding to one of the second liquid production rates of the one of the other wellbores; to calculate a weighted average of the first slope and the second slopes, with the weighted average weighted based on the first and second liquid production rates of the wellbore and the other wellbores, respectively; to determine a first gas injection rate such that a third slope, of the first curve, at a point on the first curve corresponding to the first gas injection rate, is equal to the calculated weighted average, and to cause the pump to inject the lift gas into the wellbore at the first gas injection rate.
In another aspect, a system for injecting lift gas into a wellbore for hydrocarbon production is provided. The system generally includes a pump operable to continuously inject the lift gas into the wellbore; and a processing system coupled to the pump and configured to cause the pump to inject the lift gas into the wellbore at a first gas injection rate; to obtain a first indication of a pressure at a location of the wellbore while the pump is injecting the lift gas at the first gas injection rate; to determine, based on the first indication and the first gas injection rate, a second gas injection rate; and to cause the pump to inject the lift gas into the wellbore at the second gas injection rate.
So that the manner in which the above-recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to aspects, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical aspects of this disclosure and are therefore not to be considered limiting of its scope, for the disclosure may admit to other equally effective aspects.
Aspects of the present disclosure provide techniques and apparatus for measuring one or more parameters associated with a gas lift system for hydrocarbon production and operating the system based on the measured parameters.
The controller 107 may operate the gas lift system 100 by controlling the lift gas pump 112 to start and stop injection of the lift gas. In addition, the controller 107 may be operable to control a gas injection rate of the gas lift system 100 by controlling the lift gas pump 112 to operate at a rate determined by the controller and/or at an output pressure determined by the controller. The controller 107 may also control the gas injection rate by controlling the lift gas valves 122, such as partially closing one or more valves to restrict flow of the lift gas. The controller may also be operable to accept as inputs measurements of pressure at points along the wellbore, liquid levels at points along the wellbore, temperatures at points along the wellbore, and/or quantities of liquids produced from the well.
Gas lift systems may be categorized according to a number of characteristics. One such characteristic is whether a gas lift system runs continuously (e.g., continuously lifted systems) or intermittently (e.g., intermittent lift systems). Another characteristic is whether the gas lift system has constant production measurement, intermittent (e.g., well test) production measurement, or does not have production measurement. Yet another characteristic is whether the gas lift system can supply sufficient lift gas to achieve maximum fluid production from the well or if capacity of the gas lift system is not sufficient to achieve maximum fluid production from the well. For example, a gas lift system may be shared among several wells and be insufficient to achieve maximum fluid production from all of the wells simultaneously.
If practically unlimited lift gas supplies are available, the performance curve 202 shown in
In a continuously lifted well, the lift gas injection rate may be varied by adjusting a speed or power level of the lift gas pump and/or varying valves controlling the flow of lift gas into the well. Varying the lift gas injection rate typically also alters the liquid production rate of the well (see, e.g.,
According to aspects of the present disclosure, a processing system (e.g., controller 107, shown in
According to aspects of the present disclosure, performance curves similar to those shown in
According to aspects of the present disclosure, production data from monitoring systems and/or well testing systems may not be available for some gas lifted wells. A processing system (e.g., controller 107 shown in
Aspects of the present disclosure provide methods and apparatus for improving the operation of gas lift systems with processing systems proximate to the gas lift systems. Lift gas injection rates, on times, and/or off times (collectively operating parameters or setpoints) of both continuously operated and intermittently operated gas lift systems may be determined by the processing systems that respond to data regarding changes in performance of the well that may have been caused by previous changes in operating parameters. The processing systems may determine one or more responses (e.g., changes to operating parameters) to well performance data collected (e.g., at least daily) to more economically operate wells using such gas lift systems, according to aspects of the present disclosure.
According to aspects of the present disclosure, a processing system (e.g., a controller, such as controller 107) may cause lift gas to flow into a well at a first gas injection rate, may obtain data regarding fluid production from the well, and may then adjust the gas injection rate in an effort to improve the fluid production of the well. A controller may perform these operations in an iterative fashion to improve fluid production at a well for which the controller is able to obtain real-time or daily gas injection and fluid production data.
According to aspects of the present disclosure, a processing system (e.g., a controller) may cause lift gas to flow into a well at a first gas injection rate; may obtain data regarding fluid production from the well, costs of the lift gas injection, and value of the fluids; and may then adjust the gas injection rate to improve the profitability of fluid production of the well. A controller may perform these operations in an iterative fashion to improve profitability at a well for which the controller is able to obtain real-time or daily gas injection and fluid production data.
A gas injection rate corresponding to a highest liquid (e.g., oil) production rate may be determined by choosing a spread of test points for a gas lift system and finding the highest liquid production rate among the test points. The gas lift system may then be operated at that gas injection rate. However, according to aspects of the present disclosure, instead of operating at a test point having a highest liquid production rate, an adjustment of a setpoint (e.g., a gas injection rate, an on time of an intermittent gas lift system, and/or an off time of an intermittent gas lift system) may be determined based on a change in liquid production rate caused by a previous change of a setpoint. Changes to setpoints of a gas lift system may be determined based on current and/or recent production measurements and/or other parameters.
According to aspects of the present disclosure, a processing system (e.g., controller 107 shown in
In some wells, a lift gas source may not be capable of supplying lift gas at a rate high enough to determine a highest liquid production rate. According to aspects of the present disclosure, a processing system may determine a lift gas injection rate for the well that causes liquid production at a rate that is more profitable than other gas injection rates.
According to aspects of the present disclosure, a performance curve similar to curve 202 shown in
According to aspects of the present disclosure, a processing system (e.g., controller 107 shown in
According to aspects of the present disclosure, whether to change a current setpoint of a gas lift system may be determined (e.g., by a processing system) based on a slope of a line between the current setpoint and a previous setpoint, on a graph relating a liquid production rate to a lift gas injection rate. The determination may be to continue operating using a current setpoint (i.e., leaving the setpoint unchanged) if the slope of the line between the current setpoint and the previous setpoint is approximately equal to a target slope, within an allowable deviation or deadband quantity. That is, whether to change a setpoint may be determined based on how close a slope associated with a previous change is to a target slope.
In some locations, a lift gas source (e.g., machinery to supply lift gas, such as the surface machinery 106 shown in
According to aspects of the present disclosure, as a rate of gas injection into a gas lift well increases, the casing pressure and bottom-hole pressure of the well decrease until minimum values of these pressures are reached. If gas is injected into the well above the rate at which the minimum values of these pressures occur, then all of the injected gas is unable to flow through the lift gas valve and these pressures begin to rise again. Injecting gas into a well faster than the gas can flow through the lift gas valve may be referred to as “packing the casing.”
According to aspects of the present disclosure, a lift gas injection rate that minimizes casing or bottom-hole pressure of a well may be considered an optimum lift gas injection rate for that well. That lift gas injection rate may cause a maximum liquid production rate (see, e.g.,
According to aspects of the present disclosure, a processing system (e.g., a controller) may cause lift gas to flow into a well at a first gas injection rate, may obtain data regarding a casing pressure or bottom-hole pressure of the well, and may then adjust the gas injection rate to reduce the casing pressure or bottom-hole pressure (BHP) of the well. Adjusting the gas injection rate based on the casing pressure or BHP may be referred to as interpolating the casing pressure or bottom-hole pressure. A controller may perform these operations in an iterative fashion to improve fluid production at a well for which the controller is able to obtain, for example, real-time or daily casing pressure or bottom-hole pressure data.
According to aspects of the present disclosure, a processing system (e.g., a controller) may cause lift gas to flow into a well at a first gas injection rate; may obtain data regarding a casing pressure or bottom-hole pressure of the well, costs of the lift gas injection, and value of fluids from the well; and may then adjust the gas injection rate to improve the profitability of fluid production of the well. A controller may perform these steps in an iterative fashion to improve profitability at a well for which the controller is able to obtain, for example, real-time or daily casing pressure or bottom-hole pressure data.
The Thornhill-Craver orifice flow equation relates flow rate through an orifice valve to pressure, temperature, and other parameters. The equation is reproduced below:
q
g,sc=693 Cd d2 p1 √(1/(γgT1)) √(2κ/(κ+1)) √((p2/p1)(2/κ)−(p2/p1)((κ+1)/κ))
Cd=discharge coefficient
d=choke diameter, inches (in.)
p1=flowing pressure upstream of the choke, psia
p2=flowing pressure downstream of the choke, psia
γg=specific gravity of the gas
T1=absolute temperature upstream of the choke, ° R
κ=ratio of specific heats
According to aspects of the present disclosure, a processing system (e.g., a controller) may calculate pressure (e.g., flowing pressure downstream of the choke) at a location of a gas lift valve by obtaining a measurement of gas flow into the gas lift valve, discharge coefficient of the gas lift valve, choke diameter, flowing pressure upstream of the choke, specific gravity of the gas, temperature upstream of the choke, and a ratio of specific heats, and then solving the Thornhill-Craver equation for the flowing pressure downstream of the choke.
Another equation relates flow through an IPO valve to pressure, temperature, and other parameters. This equation is reproduced below:
q
sc=1241 Av Cd Y √((pi(pi−pp))/(TvZvγg))
Av=port area, sq. in.
Cd=discharge coefficient including the ratio of areas
Y=expansion factor
pi=injection pressure at valve setting depth, psia
pp=production pressure at valve setting depth, psia
Tv=valve temperature, ° R
Zv=gas deviation factor at valve setting depth
γg=specific gravity of the gas
According to aspects of the present disclosure, a processing system (e.g., a controller) may calculate pressure (e.g., production pressure at valve setting depth) at a location of a gas lift valve by obtaining a measurement of gas flow into the gas lift valve, discharge coefficient of the gas lift valve including the ratio of areas, port area of the gas lift valve, injection pressure at valve setting depth, production pressure at valve setting depth, valve temperature, gas deviation factor at valve setting depth, and specific gravity of the gas, and then solving the equation above for the gas flow rate (at standard conditions).
According to aspects of the present disclosure, a processing system (e.g., a controller 107, shown in
According to aspects of the present disclosure, a gas injection rate, an on time of an intermittent gas lift system, and/or an off time of an intermittent gas lift system may be determined (e.g., by a processing system controlling the intermittent gas lift system) based on an indication of a pressure at a location of a wellbore, for example, a bottom-hole pressure or a casing pressure.
In a well using an intermittent gas lift system, the casing-tubing annulus may be kept charged to a maximum pressure by using a lift gas injection rate high enough to detect that lift gas is flowing through the lift gas valve(s), but at a minimal rate. This may be similar to supplying gas at pressure to a bubble tube, commonly used to detect liquid level in industrial tanks. In a bubble tube, the pressure required to cause bubbles to enter the liquid at the bottom of the tube is directly related to the height of the liquid level above the bottom of the tube. Because the gas is flowing at a minimal rate, the pressure at the bottom of the bubble tube may be considered equal to the pressure at which the gas is supplied to the bubble tube. The described minimal lift gas flow may be maintained (i.e., by supplying gas at pressure) between “on times” of higher lift gas flow rates.
According to aspects of the present disclosure, a processing system may control an intermittent gas lift system to inject gas into a well at a minimal rate, as described above, to keep a casing-tubing annulus of the well charged to a maximum pressure. The processing system may determine, based on a timer, arrival of a fluid at a wellhead, or an indication of a parameter (e.g., a temperature, a pressure, a fluid composition at a wellhead) to change the gas injection rate to a higher value for an on cycle. The processing system may determine a duration of an on cycle based on past performance of the well or an indication of a parameter and may reduce the gas injection rate to the minimal rate once the determined duration of the on cycle has occurred.
According to aspects of the present disclosure, injection of lift gas into a gas lift well may cause a slug of liquid to be delivered to the wellhead. The lift gas may push liquid from the bottom of the well into the tubing, forcing the liquid up the tubing to the wellhead. The liquid may contain gases from the reservoir and/or lift gas, which may bubble through the liquid. A separator at or near the wellhead may be used to separate the liquid from the gases. In some cases, the lift gases may be recycled and used as lift gas again.
According to aspects of the present disclosure, a change in a slope (e.g., a “knee”) of a curve representing casing pressure, as shown at 662 and 666 in the casing pressure curve 660, may indicate that a lift gas injection rate is sufficient to charge a casing tubing annulus. Charging the casing-tubing annulus may be associated with starting liquid production from a well, as shown. The lift gas injection rate of the on time 604 starting at 670 may not be high enough to charge the casing tubing annulus, as indicated by the lack of a knee in the casing pressure curve 660 in the region 661.
According to aspects of the present disclosure, a processing system (e.g., controller 107 shown in
According to aspects of the present disclosure, a processing system (e.g., controller 107, shown in
At block 704, operations 700 continue with obtaining, by the processing system, a first indication of a parameter associated with the wellbore, an arrival of a first fluid at a wellhead associated with the wellbore, or a composition of the first fluid. Continuing the example, the controller 107 may obtain an indication of a casing pressure from a sensor 110.
At block 706, operations 700 continue with determining, by the processing system and based on the first indication, at least one of: a second gas injection rate of the intermittent gas lift system, a first period to inject the lift gas with the intermittent gas lift system, or a second period, subsequent to the first period, with no injection of the lift gas by the intermittent gas lift system. Continuing the example, the controller 107 may determine a first period (e.g., two hours and fifteen minutes) to inject the lift gas with the lift gas pump 112.
At block 708, operations 700 conclude with operating, by the processing system, the intermittent gas lift system according to the determination. Continuing the example, the controller 107 may cause the lift gas pump 112 to stop injecting lift gas at the end of the first period. In the example, the controller 107 may cause the lift gas pump 112 to shut down or operate one or more lift gas valves 122 to stop the flow of lift gas into the wellbore.
According to aspects of the present disclosure, the processing system determine the second gas injection rate, cause injection of the lift gas into the wellbore at the second gas injection rate, cause the injection of the lift gas to stop, determine the first period, and cause the injection of the lift gas to start during the first period.
In some aspects of the present disclosure, the processing system may obtain a liquid production rate from the wellbore, determine the second period, and cause the injection of the lift gas to stop during the second period. The processing system may start a timer upon stopping the injection of the lift gas and then restart the injection of the lift gas when the timer expires. Additionally or alternatively, the processing system may obtain an indication of a liquid level at a location of the wellbore (e.g., at a point in the casing-tubing annulus 120, shown in
According to aspects of the present disclosure, the processing system may obtain an indication of a first pressure at a location of the wellbore, determine the second period based on the indication of the first pressure, and stop injection of the lift gas during the second period. The first pressure may comprise a bottom-hole pressure (BHP) or a casing pressure of the wellbore. The processing system may then obtain a second indication of a second pressure at the location, determine to restart the injecting of the lift gas based on the second indication, and restart the injecting of the lift gas. For example, the controller 107, shown in
According to aspects of the present disclosure, the processing system may cause injection of lift gas at the first lift gas injection rate, obtain a measurement of a first liquid production rate while the injection of the lift gas at the first lift gas injection rate is ongoing, determine the second lift gas injection rate, cause injection of the lift gas into the wellbore at the second lift gas injection rate, and obtain a measurement of a second liquid production rate while the injection of the lift gas at the second lift gas injection rate is ongoing. The processing system may then determine a third lift gas injection rate based on the first lift gas injection rate, the first liquid production rate, the second lift gas injection rate, and the second liquid production rate (e.g., by determining if a slope between points corresponding to the first and the second liquid production rates on a curve relating liquid production gas injection rates is within a deadband of a target slope) and cause injection of the lift gas into the wellbore at the third lift gas injection rate.
In aspects of the present disclosure, the processing system may obtain an indication that the first fluid (arriving at the wellhead as described with reference to
According to aspects of the present disclosure, the processing system may obtain a first indication that the first fluid (arriving at the wellhead as described with reference to
In aspects of the present disclosure, the processing system may cause injection of lift gas into the wellbore at a first injection rate, obtain an indication of arrival of the first fluid at the wellhead, determine the first period based on the indication, stop the injection of the lift gas at the end of the first period, start a timer at the end of the first period, and cause injection of the lift gas to restart upon expiration of the timer.
According to aspects of the present disclosure, the processing system may cause injection of lift gas into the wellbore at a first injection rate, obtain an indication of a casing pressure associated with the wellbore, and determine the first period based on the first gas injection rate, a depth of the wellbore, and the casing pressure. The processing system may then stop the injection of the lift gas at the end of the first period.
In aspects of the present disclosure, the processing system may cause injection of lift gas into the wellbore at a first injection rate, obtain an indication of a casing pressure associated with the wellbore, and determine the second gas injection rate based on the casing pressure and a liquid production rate at the wellhead. The processing system may then cause injection of the lift gas into the wellbore at the second gas injection rate.
Operations 800 begin at block 802 with obtaining a first indication of a first liquid production rate of the wellbore. For example, controller 107, shown in
At block 804, operations 800 continue with obtaining one or more second indications of second liquid production rates of one or more other wellbores. Continuing the example, the controller 107 may obtain an indication of a liquid production rate of another wellbore, for example p2 barrels per day.
At block 806, operations 800 continue with determining a first slope, of a first curve relating a plurality of liquid production rates of the wellbore to a plurality of gas injection rates of the wellbore, at a point on the first curve corresponding to the first liquid production rate. Continuing the example, the controller 107 may determine a slope of a curve relating liquid production rates of the wellbore to gas injection rates of the gas lift system 100 (e.g., determined from previously collected production information of the wellbore), such as a curve similar to that shown in
Operations 800 continue at block 808 with determining one or more second slopes, of one or more second curves, each second curve relating a plurality of liquid production rates of one of the one or more other wellbores to a plurality of gas injection rates of the one of the other wellbores, each second slope being determined at a point on the second curve corresponding to one of the second liquid production rates of the one of the other wellbores. Continuing the example from above, the controller 107 may determine a second slope, of a second curve relating liquid production rates of another wellbore to gas injection rates of the other wellbore (e.g., determined from previously collected production information of the other wellbore), at a point on the second curve corresponding to the liquid production rate of the other wellbore (e.g., p2 barrels per day). Still in the example, the controller 107 may then determine the second slope of the second curve to be x2 barrels of oil per thousand standard cubic feet of lift gas.
At block 810, operations 800 continue with calculating a weighted average of the first slope and the second slopes, with the weighted average weighted based on the first and second liquid production rates of the wellbore and the other wellbores. Continuing the example above, the controller 107 may calculate a weighted average of the slope of the first curve and the second slope of the second curve. Using the exemplary values from above, the weighted average of the first slope and the second slope is:
((p1·x1)+(p2·x2))/(p1+p2)
Operations 800 continue at block 812 with determining a first gas injection rate such that a third slope, of the first curve, at a point on the first curve corresponding to the first gas injection rate, is equal to the calculated weighted average. Continuing the example above, the controller 107 may determine a first gas injection rate corresponding to a point on the first curve having a slope, x3, equal to the calculate weighted average, ((p1·x1)+(p2·x2))/(p1+p2).
Operations 800 conclude at block 814 with causing injection of the lift gas into the wellbore at the first gas injection rate. Continuing the example above, the controller 107 may cause the lift gas pump 112 to inject lift gas into the wellbore at the first gas injection rate, for example, by adjusting on and off times of the lift gas pump 112, a speed of the lift gas pump 112, an output pressure of the lift gas pump 112, and/or valves controlling the flow of lift gas to the wellbore and the other wellbores.
While the operations 800 are described using the example of a controller located proximate to one wellbore of two wellbore, the disclosure is not so limited, and the operations 800 may be performed by a remote controller and/or by a human operator for groups of more than two wellbores.
At block 904, operations 900 continue with obtaining, by the processing system, a first indication of a pressure at a location of the wellbore while the injection of the lift gas at the first gas injection rate is ongoing. Continuing the example, the controller 107 may obtain an indication of a bottom-hole pressure (BHP) of the wellbore from a sensor 110.
At block 906, operations 900 continue with determining, by the processing system and based on the first indication and the first gas injection rate, a second gas injection rate for the continuous gas lift system. Still in the example from above, the controller 107 may determine a second gas injection rate for the continuous gas lift system, based on the indication of the BHP and the first gas injection rate.
Operations 900 conclude at block 908 with causing, by the processing system, the continuous gas lift system to inject lift gas into the wellbore at the second gas injection rate. Continuing the example from above, the controller 107 may cause the lift gas pump 112 to inject lift gas into the wellbore at the second gas injection rate (e.g., by changing a speed of the lift gas pump 112 and/or by adjusting, opening, or closing lift gas valves 122).
According to aspects of the present disclosure, the processing system (e.g., controller 107) may cause injection of the lift gas into the wellbore at the first injection rate, obtain a first indication of a pressure at a location of the wellbore while the injection of the lift gas is ongoing, determine a second gas injection rate based on the first indication and the first gas injection rate, and cause the continuous gas lift system to inject gas into the wellbore at the second gas injection rate. The processing system may then obtain a second indication of a second pressure at the location while the continuous gas lift system is injecting lift gas at the second gas injection rate, determine a target pressure (e.g., a target pressure for the location, a target BHP), determine a third gas injection rate based on the first gas injection rate, the first pressure, the second gas injection rate, the second pressure, and the target pressure (e.g., by referring to a curve relating pressure to gas injection rate, such as curve 502, shown in
In aspects of the present disclosure, the pressure at the location of the wellbore may comprise bottom-hole pressure (BHP) of the wellbore. For other aspects of the present disclosure, the pressure at the location of the wellbore may comprise a casing pressure of the wellbore.
Any of the operations or algorithms described above may be included as instructions in a computer-readable medium for execution by a controller or any suitable processing system. The computer-readable medium may comprise any suitable memory or other storage device for storing instructions, such as read-only memory (ROM), random access memory (RAM), flash memory, an electrically erasable programmable ROM (EEPROM), a compact disc ROM (CD-ROM), or a floppy disk.
The word “exemplary” is used herein to mean “serving as an example, instance, or illustration.” Any aspect described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other aspects.
While the foregoing is directed to aspects of the present disclosure, other and further aspects of the disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.