Patent Grant
11629586
The present invention relates to the separation of phases in produced hydrocarbon fluids, and in particular the downhole separation of such phases.
Concepts for downhole separation of oil/water have been under development for many years. However, none of these concepts have been materialized due to numerous uncertainties related to their robustness.
Existing concepts for downhole separation of oil/water rely on re-injection of water utilizing a well side branch and a separate water injection system (pump). Such a layout is technically complex and expensive. In addition, there is large uncertainty related to the quality of the water to be re-injected. A tiny fraction of oil contained in the water for re-injection may create problems and potentially plug the water injector.
The present invention aims to solve or at least mitigate the above described problems, and, further, to provide a simple and efficient method and system for downhole (or in-pipe) separation of fluid phases. With reference to the separation of oil and water phases, the present invention does not rely on re-injection of the water. Instead, the separate phases, e.g. oil and water phases, are lifted in separated conduits towards the well head. With reference to the separation of oil and water phases, this solution eliminates the large uncertainties related to potential re-injection of the water.
In accordance with a first aspect of the present invention there is provided a method of separating fluid phases in a well or riser, comprising: locating an inlet device at a substantially horizontal portion of the well or riser, wherein a portion of a flexible tubing extends into the well or riser and the flexible tubing terminates at the inlet device; biasing the inlet device against an inside wall of the well or riser; and extracting a stratified fluid phase from the well or riser through the inlet device and flexible tubing, wherein a shape of the inlet device matches a shape of the inside wall.
Biasing the inlet device against the inside wall of the well or riser may comprise biasing the inlet device away from an opposing inside wall of the well or riser.
The inlet device may comprise a partially tubular outer wall, wherein the shape of the inlet device is an outer curvature of the partially tubular outer wall which matches an inner curvature of the inside wall of the riser or the well, and wherein the inlet device is biased against the inside wall of the well or riser such that the inlet device is flush with the inside wall of the well or riser.
The inlet device may have an at least partially oval cross section in radial direction of the flexible tubing.
The inlet device may comprise a jet pump which draws the stratified fluid phase that is to be extracted into the inlet device.
The inlet device may be biased against the inside wall of the well or riser using a spacer arranged to urge the end of the flexible tubing and/or the inlet device against the inside wall.
The inlet device may be biased against the inside wall of the well or riser using a weight that is arranged to urge the end of the flexible tubing and/or the inlet device against the inside wall.
The inlet device may be biased against a lower inside wall of the well or riser. The extracted stratified fluid phase may be a water phase or a water-and-condensate phase.
The inlet device may be biased against an upper inside wall of the well or riser. The extracted stratified fluid phase may be an oil phase or an oil-and-gas phase.
In accordance with a second aspect of the present invention there is provided a system for separating fluid phases in a well or riser, comprising: a flexible tubing extending into the well or riser and terminating at an inlet device, wherein the inlet device is located at a substantially horizontal portion of the well or riser and is biased against an inside wall of the well or riser; wherein a shape of the inlet device is configured to match a shape of the inside wall, and wherein the inlet device and flexible tubing are configured to extract a stratified fluid phase from the horizontal portion of the well or riser.
Hydrocarbons are typically extracted from a reservoir via a production well. Produced fluids located in such a production well typically include different phases, e.g. liquid hydrocarbons, gases, water and perhaps solids. Similar phases, or more typically gaseous hydrocarbons and water/condensate phases, may be located in a production riser. In horizontal, near-horizontal or low portions of a well or riser the fluid velocity is typically low, and the fluids may naturally stratify under the influence of gravity. For example, flowing oil/water phases may be separated by gravity before reaching an inclined or vertical part of the well. These considerations also apply for horizontal portions of a flowline, riser, or riser base. This natural stratification provides an opportunity for the simple downhole (or in a pipe) separation of different fluid phases in accordance with the invention. This avoids the difficulties associated with typical phase separation processes, which are carried out in more mixed/turbulent flow regimes. In particular, in the inclined/vertical part of a well the oil/water stratified flow regime disappears and a dispersed flow regimes results. These dispersions are further transported through various chokes and process equipment before reaching topside and the process plant. Separating a heavily mixed oil/water dispersion/emulsion topside can be very challenging and costly. Thus, being able to separate oil and water under stratified downhole conditions may be advantageous. Mixing of oil and water is avoided, and issues with emulsions are thereby avoided. Any subsequent topside separation processes are therefore made simpler. The invention is suitable for field layouts with subsea or topside well heads.
The inlet device 108 is biased against a wall of the well, and away from an opposing wall of the well, and is preferably in close contact with the wall. The inlet device may be biased against a lower/bottom wall of the well under the influence of gravity. In this case, the inlet device has a weight and density sufficient to maintain biasing of the inlet device under the influence of gravity in the flow and fluid conditions within the well. A specific example of the weight of the inlet device is 100 kg for a 40 cm internal diameter well. The connection between the flexible tubing and the inlet device may be a swivel connection to allow the assembly to move past bends, or alternatively the connection may be a fixed connection. Alternatively or additionally, various mechanical means can be provided, if necessary, for urging the inlet device against the wall. One option can be a heavy weight which is attached to the end of the flexible tubing at or near the inlet device and which urges the end of the flexible tubing towards the lowest part of the well. Another example is a spacer which extends from the flexible tubing or inlet device to the opposite internal well wall to urge the flexible tubing against the well wall. Examples of spacers are simple mechanical devices such as a mechanical spring or extendable rod. Optionally, the spacers can be activated remotely but that will require communication lines and control units which will add costs to the setup.
In the specific example shown in
No jet pump may be necessary if the downhole pressure is large enough to drive fluids up the flexible tubing. In this case, the separated phase may be extracted via the inlet device and flexible tubing using natural lift provided by downhole pressure.
The urging of the inlet device against a wall of the well and the matching of the shape of the inlet device with the inner wall shape facilitates the efficient extraction of a stratified fluid phase. In particular, the location of the inlet device close to an inner wall of the well (and away from the opposite wall) in a horizontal portion of the well, and preferably within one of the stratified phases, means that one of the stratified phases (which may itself contain one or more dispersed phases) can be easily separated and extracted. In an embodiment in which a stratified water phase is separated from a stratified oil phase, the water can be lifted directly up to the water treatment topside without being mixed into the oil.
The inlet device and flexible tubing of the invention, where the inlet device includes a water-driven jet pump, could also be used to lift liquid from risers in gas dominated systems, with the purpose of mitigating flowline/riser surge wave instabilities in addition to reducing well and riser pressure drop under steady state operation.
The inlet device (optionally with jet pump) and flexible tubing could alternatively be positioned in an upper part of a well tubing cross section. With such a configuration water will flow in the annulus while the oil phase and/or the gas phase will be transported in the flexible tubing.
Although the invention has been described in terms of preferred embodiments as set forth above, it should be understood that these embodiments are illustrative only and that the claims are not limited to those embodiments. Those skilled in the art will be able to make modifications and alternatives in view of the disclosure which are contemplated as falling within the scope of the appended claims. Each feature disclosed or illustrated in the present specification may be incorporated in the invention, whether alone or in any appropriate combination with any other feature disclosed or illustrated herein.
To provide a better understanding of the present invention and for background only, an example of a system for protecting a riser and production facility against liquid surges is set out below:
Herein disclosed is a system which can be used for protecting a riser and production facility against liquid surges. The riser is used for transporting gas and liquid from a flowline located at the sea bed to a production facility. The riser contains liquid and gas and at low gas flow rates the liquid may accumulate and move in a wave-like manner downstream. Flexible tubing is provided which extends partially into the riser and which ends inside the riser. A pressure differential within the flexible tubing is provided such that any liquid in the area where the tubing ends is drawn into the flexible tubing and is transported up. The liquid can be transported to a container which is kept at a lower pressure than the area within the riser where the tubing ends. The amount of liquid which is drawn into the tubing can be controlled by a regulating valve provided between the tubing and the container. Alternatively, a pump can be provided which controls the amount of liquid drawn into the flexible tubular.
The riser will in a typical arrangement not only extend upwards continually from the flowline in a straight way, but the riser will have several areas with bends and local dips where fluids can accumulate. The end of the flexible tubular can be placed in such a bend or a local dip to draw the liquid out of that area. By removing the liquid from the riser a surge of liquid in which collected liquid suddenly moves upwards can be prevented. If the amount of liquid accumulating in one area is large enough to take up the entire cross sectional area then a liquid plug can be formed which blocks the flow of gas and causes fluctuations of pressure. The flexible tubing can be extended into the plug such that the plug of liquid can be removed by suction from the flexible tubing.
However, also without local depressions of the riser where liquid can accumulate as a plug there can be a problem of liquid surging. Gas condensate typically accumulates along the walls of the riser while the central area of the riser remains free for gas to flow through. By way of example, liquid condensate along the walls can occupy from 5% to 20% of the cross sectional area. This problem occurs also in risers which extend continuously upwards. The liquid will move upwards under the influence of the upwards gas flow through the centre of the riser. The upwards movement of the liquid is not a stable process due to the opposite forces of gravity and friction of the riser walls, and the instability causes waves of liquid and liquid surging instead of a steady flow. The flexible tubing is used to remove the liquid to reduce the cross sectional area taken up by fluid and to reduce the overall amount of fluid, thereby mitigating the liquid surging.
The end of the flexible tubing within the riser is preferably in contact with the riser walls, especially when gas flows through the centre of the riser and gas condensate is accumulated along the walls. Various mechanical means can be provided for urging the tubing against the riser inner walls. One option can be a heavy weight or inlet device which is attached to the end of the flexible tubing and which urges the end of the flexible tubing towards the lowest part of the riser. This example of a heavy weight or inlet device works best if the riser has a significant horizontal component. Another example is a spacer which extends from the flexible tubing to the opposite internal riser wall to urge the flexible tubing against the riser wall. Examples of spacers are simple mechanical devices such as a mechanical spring or extendable rod. Optionally, the spacers can be activated remotely but that will require communication lines and control units which will add costs to the setup.
In a specific example, the portion of the flexible tubing which is outside the riser is stored on a reel which can also be used to vary the length of the portion of the flexible tubing extending into the riser. The length of the portion of the tubing extending into the riser can also be actively controlled by a feedback system depending on a detected amount of fluid in the flexible tubing. When a larger amount of fluid is present, the flexible tubing can be pulled up by rolling up the reel or by any other lifting mechanism. Alternatively, the tubing can be left in place if a large amount of fluid is detected within the tubing. If a small amount of fluid or no fluid is detected inside the flexible tubing, the tubing can be extended to reach further into the riser and remove liquid at a section of the riser closer to the well. This feedback system can be automated and be controlled by a computing system, or it can be carried out manually. The active control system enables continuous lifting of the gas and liquid mixture from the riser base to the topside.
The variable length of the flexible tubing can also be utilised to initiate the flow within the flexible tubing. The pressure differential required for starting the flow of a large amount of fluid from a location low in the riser can be relatively large. The required pressure differential can be reduced by raising the intake point of the flexible tubing for starting the flow, and lowering the intake point after the flow has started to the desired location.
Different methods can be used for detecting the presence of fluids in the flexible tubing, such as standard optical or acoustic methods, or a gamma densitometer clamped onto the coiled tubing topside. Alternatively, the pressure within the flexible tubing near the control valve can be detected, and a drop in pressure will indicate an increase of the amount of gas and a decrease of the amount of fluid.
An advantage of this arrangement is that it will be efficient to implement on platforms with coiled tubing equipment already in place. At such a platform, coiled tubing is connected to an available low-pressure tank via a control valve. This allows for drawing liquid up from the riser base. The optimal pressure in the low-pressure tank depends on the depth of the riser base and the pressure within the riser. The pressure difference between riser base process and the low-pressure tank determines the driving potential for the liquid extraction.
A plurality of separators can be used in stage separation of the hydrocarbons. The first separator, called the first-stage separator, typically has the highest pressure and the operating pressure is sequentially reduced in each successive separator. The flexible tubing will be able to carry out a suction function if the pressure inside the flexible tubing is lower than the pressure inside the riser. This pressure difference can be achieved by connecting the flexible tubing to a separator which has a lower pressure than the nearest separator to which the riser is connected. In one example, the riser section is directly connected to a first-stage separator, and the flexible tubing is connected to a second-stage separator.
A variable pressure differential can be applied to the flexible tubing, for example with a pump or with pressure control facilities provided at the separator. The variable length of the flexible tubing and the variable pressure provide two controls which can be used together or independently to control the intake of fluids into the flexible tubing.
The flexible tubing can be installed for surge protection within a riser. Alternatively, the flexible tubing can be installed inside the tubing in a gas-condensate well. Gas-condensate wells may also become unstable and ultimately need to be abandoned due to liquid accumulation. The methods described herein are applicable to a well and the hydrodynamics are similar when compared to a riser. However, if the well has its well head located at the sea bed there may not be a low pressure separator or a high pressure separator available for connection to the coiled tubing well-head-end and well head tubing, respectively. In such a setup, the well-head-end of the coiled tubing could be connected to a low pressure subsea flowline, while the well tubing could be connected to a separate flowline located at a higher pressure. If the well head is located above sea level, i.e. on a well head platform, coiled tubing and well tubing could be connected to low pressure and high pressure separators respectively, as described for a riser setup. In some gas-condensate wells the major portion of liquid to be removed deep in the well is liquid which flows downwards from an upper part of the well due to condensation in the upper part of the well. In an example described in more detail below, the intake device is designed differently to capture the condensing liquid flowing downward instead of being designed to capture liquid flowing upwards from the reservoir.
One particular example of flexible tubing for gas-liquid flow is coiled tubing. A suitable coiled tubing diameter is selected to optimise the amount of liquid being extracted while minimising the amount of gas being taken into the coiled tubing. If a thin layer of liquid is present along the walls then a corresponding small-diameter coiled tubing is selected. If the tubing is connected to a low pressure tank that is not part of the regular separation process (such as a second or higher stage separator), then the extracted gas and liquid mixture is pumped back into the process using a small multiphase pump. If the gas flow rate in the flexible tubing is too high for a multiphase pump, then a small compressor is used in parallel to a separate liquid pump. If the output of the coiled tubing is connected directly to a second or third stage separator no pump or compressor will be required, but only a control valve.
The flexible tubing allows for a pigging operation by simply extracting the flexible tubing from the riser completely and returning the flexible tubing after the operation has been completed.
The fluid is pumped from the low pressure tank to a further part of the process, such as a second stage separator (not illustrated). Alternatively, low pressure tank 8 can be a separator, such as a 2nd stage, a 3rd stage or higher stage separator.
The system described herein allows for reduction of the risk of a surge wave formation. The system can be used to extend the lifetime of gas-condensate fields. Without proper methods for surge mitigation, flowlines may need to be abandoned due to severe surge instabilities. Being able to efficiently remove liquid from the flowlines by way of the present system prevents surge instabilities partly or completely, thereby enabling continued production.
In some examples it is beneficial to terminate the coiled tubing at a topside location and hang off the coiled tubing in a coiled tubing hanger arrangement placed inside the riser.
Examples are set out below in the form of numbered clauses:
1. A system for surge protection of a riser adapted to transport gas from a hydrocarbon production well or for surge protection in a well, the system comprising:
2. The system of clause 1,
wherein the surge comprises a liquid film accumulated against an inner wall of the riser or the well;
3. The system of clause 1 or 2, further comprising a reel for storing a further portion of the flexible tubing and for varying the length of said portion of the flexible tubing extending into the riser or into the well.
4. The system of any one of the preceding clauses, further comprising a pressure sensor arranged to measure the pressure in the flexible tubing.
5. The system of clause 4, further comprising a control system arranged to increase the length of said section if the pressure in the tubing is below a first threshold level and arranged to decrease the length of said section if the pressure in the tubing is above a second threshold level.
6. The system of clause 5, wherein the first threshold level and the second threshold level are the same, or wherein the second threshold level is higher than the first threshold level.
7. The system of any one of the preceding clauses, further comprising a detector arranged to detect the presence of fluid or amount of fluid in the flexible tubing.
8. The system of clause 7, further comprising a control system arranged to:
increase the length of said section if the amount of detected fluid is below a first threshold level, or if no fluid is detected; the control system further arranged to:
decrease the length of said section if the amount of detected fluid is above a threshold.
9. The system of clause 2, wherein the device with a lower pressure than the first stage separator comprises one or more of:
a low pressure tank and a valve;
a second or higher stage separator.
10. The system of any one the preceding clauses, wherein the pressure control system comprises a multiphase pump.
11. The system of any one of clauses 1 and 2 to 8, wherein the pressure control system comprises a first connection between the well and a first flowline and a second connection between the flexible tubing and a second flowline, and wherein the pressure in the first flowline is higher than the pressure in the second flowline.
12. The system of any one of the preceding clauses, further comprising a return system for returning fluid extracted by the flexible tubing back to the production process.
13. The system of clause 12, therein the return system comprises a multiphase pump.
14. The system of clause 1, wherein said pressure control system comprises a separator connected to said flexible tubing.
15. The system of clause 14, wherein the riser or well is connected to a further separator and wherein the further separator has a lower pressure than the separator connected to the flexible tubing.
16. The system of any one of the preceding clauses, further comprising a spacer arranged to urge the end of the flexible tubing against an inner wall of the riser or well.
17. The system of any one of the preceding clauses, further comprising a weight arranged to urge the end of the flexible tubing against an inner wall of the riser or well.
18. The system of clause 1, wherein the end of the flexible tubing is attached to an intake device, wherein the intake device has an at least partially oval cross section in radial direction of the flexible tubing, or wherein intake device terminates at an end portion, wherein the end portion comprises a partially tubular outer wall, wherein the outer curvature of the partially tubular outer wall matches the inner curvature of the inside wall of the riser.
19. The system of any one of the preceding clauses, wherein the end of the flexible tubing is attached to an intake device, wherein the intake device is open and able to receive fluid on the side of the intake device facing the flexible tubing, and wherein the intake device is closed on the side of the intake device facing away from the flexible tubing.
20. The system of any one of the preceding clauses, further comprising a gas flowline terminating at or near the position where the flexible tubing terminates, wherein the gas flowline is suitable for injecting gas into the flexible tubing for providing gas lift.
21. A method for protecting a riser adapted to transport gas from a hydrocarbon production well against pressure surges or for protecting a well against pressure surges, the method comprising:
22. A method according to clause 21,
wherein the surge comprises a liquid film attached to an inner wall of the riser or the well;
23. The method of clause 21 or 22, wherein the method further comprises varying the length of said portion of the flexible tubing by rolling or unrolling the flexible tubing on a reel.
24. The method of any one clauses 21 to 23, further comprising determining the pressure within the flexible tubing and varying the length depending on said determining, or adapting the pressure within the flexible tubing in response to said determining.
25. The method of any one of clauses 21 to 24, further comprising determining the amount of liquid within the flexible tubing and varying the length depending on said determining.
26. The method of any one of clauses 21 to 25, wherein said drawing of liquid comprises regulating a valve to a low pressure reservoir.
27. The method of any one of clauses 21 to 25, wherein said drawing of liquid comprising controlling a pump.
28. The method of any one of clauses 21 to 27, further comprising transporting fluid from the flexible tubing to a production facility.
29. The method of any one of clauses 21 to 28, further comprising connecting said riser or well to a first stage separator and connecting said flexible tubing to a second or higher stage separator and wherein the pressure of the further separator is lower than the pressure of the first separator.
30. The method of any one of clauses 21 to 28, further comprising connecting the flexible tubing to a first flowline and connecting the well to a second flowline.
31. The method of any one of clauses 21 to 29, further comprising urging the end of the flexible tubing against an inner wall of the riser or well.
32. The method of any one of clauses 21 to 31, further comprising starting the flow of liquid into the flexible tubing at a first depth of the riser or the well, and lowering the flexible tubing to a second depth of the riser or the well, wherein the second depth is further upstream than the first depth.
33. The method of any one of clauses 21 to 31, further comprising varying the pressure with the pressure control system.
34. The method of clause 23, further comprising cutting the flexible tubing after said step of varying, hanging off the tubing from the riser, connecting to said pressure control system.
35. The method of any one of clauses 21 to 34, further providing a gas flowline and injecting gas into the flexible tubing.
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| 1716719 | Oct 2017 | GB | national |
| 1811556 | Jul 2018 | GB | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/NO2018/050245 | 10/12/2018 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2019/074377 | 4/18/2019 | WO | A |
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| 20200332641 A1 | Oct 2020 | US |
