US20200248539A1

US20200248539A1 - Integrated Pump and Compressor and Method of Producing Multiphase Well Fluid Downhole and at Surface

Info

Publication number: US20200248539A1
Application number: US16/858,137
Authority: US
Inventors: Jinjiang Xiao; Randall Alan Shepler
Original assignee: Saudi Arabian Oil Co
Current assignee: Saudi Arabian Oil Co
Priority date: 2013-06-24
Filing date: 2020-04-24
Publication date: 2020-08-06
Also published as: US20180038210A1; CN105408581A; CN105408581B; US9915134B2; WO2014209960A2; WO2014209960A3; CA2915683A1; US11162340B2; US20200332631A1; EP3014058A2; US20140377080A1; US10677031B2

Abstract

An integrated system is disclosed to handle production of multiphase fluid consisting of oil, gas and water. The production stream is first separated into two streams: a liquid dominated stream (GVF <5% for example) and a gas dominated stream (GVF >95% for example). The separation can be done through shrouds, cylindrical cyclonic, gravity, in-line or the like separation techniques. The two streams are then routed separately to pumps which pump dissimilar fluids, such as a liquid pump and a gas compressor, and subsequently recombined. Both pumps are driven by a single motor shaft which includes an internal passageway associated with one of the pumps for reception of the fluid from the other pump, thereby providing better cooling and greater overall efficiency of all systems associated therewith. A method for providing artificial lift or pressure boosting of multiphase fluid is also disclosed.

Description

RELATED CASE

This application claims priority under 35 U.S.C. 119, 120 on applicants' Provisional Application No. 61/838,761 filed Jun. 24, 2013 which application is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a system and method for producing multiphase fluid (i.e., oil, gas and water) either downhole or at surface using artificial lift methods such as Electric Submersible Pump (ESP), Wet Gas Compressor (WGC) and Multi-Phase Pump (MPP).

2. Description of the Related Art

Downhole artificial lift or surface pressure boosting are often required to increase hydrocarbon production and recovery. The production fluids are often a mixture of gas, oil and water. In the case of an oil well, the operating pressure downhole can be below the bubble point pressure or the well can have gas produced from the gas cap together with the oil. For gas wells, the gas is often produced with condensate and water.
Electric Submersible Pump (ESP) is an artificial lift method for high volume oil wells. The ESP is a device which has a motor close-coupled to the pump body. The entire assembly is submerged in the fluid to be pumped. The ESP pump is generally a multistage centrifugal pump can be hundreds of stages, each consisting of an impeller and a diffuser. The impeller transfers the shaft's mechanical energy into kinetic energy of the fluids, and the diffuser converts the fluid's kinetic energy into fluid head or pressure. The pump's performance depends on fluid type, density and viscosity. When free gas is produced along with the oil and water, gas as bubbles can build up on the low pressure side of the impeller vanes. The presence of gas reduces the head generated by the pump. In addition, the pump volumetric efficiency is reduced as the gas is filing the impeller vanes. When the amount of free gas exceeds a certain limit, gas lock can occur and the pump will not generate any head/pressure.
To improve ESP performance, a number of techniques have been developed. These solutions can be classified as gas separation/avoidance and gas handling. Separation and avoidance involves separating the free gas and preventing it from entering into the pump. Separation can be done either by gravity in combination with special completion design such as the use of shrouds, or by gas separators installed and attached to the pump suction. The separated gas is typically produced to the surface through the tubing-casing annulus. However, this may not always be a viable option in wells requiring corrosion protection through the use of deep set packers to isolate the annulus from live hydrocarbons. In such environments, the well will need to be completed with a separate conduit for the gas. To utilize the gas lift benefit, the gas can be introduced back to the tubing at some distance from the pump discharge after pressure equalization is reached between the tubing and gas conduit. To shorten the distance, a jet pump can be installed above the ESP to “suck” in the gas. All these options add complexity to well completion and well control.
Gas handling is to change the pump stage design so that higher percentage of free gas can be tolerated. Depending on the impeller vane design, pumps can be divided into the following three types: radial, mixed and axial flow. The geometry of radial flow pump is more likely to trap gas in the stage vanes and it can typically handle gas-volume-fraction (GVF) up to 10%. In mixed flow stages, since the fluid mixture has to go through a more complex flow pass, mixed flow pumps can typically handle up to 25% free gas with some claiming to be able to handle up to 45% free gas. In an axial flow pump, the flow direction is parallel to the shaft of the pump. This geometry reduces the possibility to trap gas in the stages and hence to gas lock. Axial pump stages can handle up to 75% free gas, but have poor efficiency compared to mixed flow stages.
For gas wells, as fields mature and pressure declines, artificial lift will be needed to maintain gas production. Conventional artificial lift with ESP, Progressing Cavity Pump (PCP), and Rod pump all requires separation of gas from liquid. The liquid will be handled by pumps and the gas will flow naturally to surface. Downhole Wet Gas Compressor (WGC) is a new technology that is designed to handle a mixture of gas and liquid. Yet, at the current stage, it still has a limited capability to handle liquid.
At the surface, the conventional approach is to separate the production into gas and liquid and use a pump for the liquid and a compressor for the gas. Two motors are required with this approach, which results in a complex system. Surface MPP and WGC are costly, complex and many times still suffer from reliability issues.
There is presently a need to develop a compact system for downhole artificial lift or surface pressure boosting that works satisfactorily with a wide range of GVF. We have invented a system and method for producing such multiphase fluid downhole and at surface, with resultant overall improved efficiency.

SUMMARY OF THE INVENTION

An integrated system is disclosed to handle production of multiphase fluid consisting of oil, gas and water. The production stream is first separated into two streams: a liquid dominated stream (GVF <5% for example) and a gas dominated stream (GVF >95% for example). The separation can be done through gravity, shrouds, or cylindrical cyclonic separation techniques. The two streams are then routed separately to a liquid pump and a gas compressor, and subsequently recombined. Alternatively for downhole applications, the separate flow streams may be brought to the surface separately, if desired. The system can be used to produce artificial lift or surface pressure boosting downhole or at surface.
Both the pump and compressor are driven by a single motor shaft which includes an internal passageway associated with one of the machineries for reception of the fluid from the other machinery, thereby providing better cooling and greater efficiency of all systems associated therewith.
The pump and compressor are each designed best to handle liquid and gas individually and therefore the integrated system can have an overall higher efficiency. The present invention is compact and produces downhole artificial lift and surface pressure boosting, particularly in offshore applications. Furthermore, depending upon the specific separation technique employed, the production fluids can be arranged to provide direct cooling of the motor, as in conventional ESP applications.
A significant feature of the present invention is that the pump and compressor share a common shaft which is driven by the same electric motor. For surface applications, the drive means can also be the same diesel or gasoline engine. In one embodiment, the compressor portion of the shaft is hollow to provide a flow path for the liquid discharged from the pump. In another embodiment, the pump portion of the shaft is hollow to provide a flow path for the gas discharged from the compressor. Optionally, a gearbox can be added between the compressor or pump so the two can be operated at different speed.
The hybrid, coaxial pump and compressor system of the present invention is compact, and is particularly suitable for downhole artificial lift applications for gassy oil wells or wet gas producers. It also has applications for surface pressure boosting, especially on offshore platforms where spaces are always limited and costly.
The invention incorporates mature pump and compressor technologies, and integrates them in an innovative way for multiphase production applications where an individual device would not be suitable if it is made to handle the mixture of oil, gas and water.
The present invention does not require a specific type of pump or compressor. It is effective by integrating existing mature pump and compressor technologies in such structural and sequential arrangements, whereby unique multiphase production is facilitated with a wide range of free gas fraction. The pump and compressor are coupled onto the same shaft so that a single motor can be used to drive both devices. In one embodiment a portion of the compressor shaft is hollow to allow fluid passage.
In another embodiment, a portion of the shaft associated with the pump can be hollow to receive gas to provide a flow path for gas discharged from the compressor.
In either embodiment, a certain amount of beneficial and stabilizing heat transfer will take place.
The present invention utilizes a single motor to drive a pump and a compressor simultaneously, with particular features which direct the liquids and the gases in distinct directions. As noted, the pump and compressor can be of any design within the scope of the invention, and each embodiment can operate at its own best efficiency conditions in terms of gas or liquid tolerance. The elimination of the second motor, as well as the unique structural arrangements of the present invention, make the present system ideal for downhole and well site surface applications.
As will be seen from the description which follows, the total production stream is first separated into a liquid dominant stream and a gas dominant stream. As noted, the separation can be realized in a number ways such as gravity, centrifugal or rotary gas separator, gas-liquid cylindrical cyclonic, in-line separator. A pump is used to provide artificial lift or pressure boosting to the liquid dominant stream, and a compressor is used to provide pressure boosting for the gas dominant stream. The pump and compressor can be radial, mixed or axial flow types. The two devices are on the same shaft which is driven by the same motor or fuel engine as in the case of surface applications.
A method is also disclosed for producing multiphase fluid (oil, gas and water), either downhole or at surface. The system combines a pump for handling a liquid dominant stream and a compressor for handling a gas dominant stream. The pump and compressor share a common shaft, driven by the same electric motor or fuel engine in the case of surface applications. The portion of the shaft for the compressor is hollow, which serves as a flow path for the liquid discharged from the pump. The production fluid may be passed through a cooling jacket to provide cooling for the motor, and the separated liquid also provides cooling for the compressor, which improves the efficiency of the compressor. The compressed gas and the pumped liquid are combined at the compressor outlet, or at the pump outlet, depending upon the preferred sequential arrangement of the components of the individual system. The system has a broad Gas-Volume-Fraction (GVF) operating range and is compact for downhole and onshore/offshore wellhead uses.
The present inventive method is also effective when a portion of the shaft associated with pump is hollow to provide a flow path for gas discharged from the compressor, thereby facilitating stabilizing heat transfer throughout the system components.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention are disclosed hereinbelow with reference to the drawings, wherein:

FIG. 1 is an elevational view, partially in cross-section, of a combination liquid pump/gas compressor arrangement constructed according to the present invention, the arrangement shown in a vertical orientation and adapted to flow fluids upwardly from a well location downhole:

FIG. 2 is an enlarged elevational cross-sectional view of a liquid pump and gas compressor similar to FIG. 1, the arrangement shown in a horizontal orientation, and the single motor shown in schematic format for convenience of illustration;

FIG. 3 is an enlarged elevational cross-sectional view of an alternative embodiment of the liquid pump/gas compressor arrangement similar to FIGS. 1 and 2, with the positions of the liquid pump and gas compressor being respectively reversed, the pump portion of the shaft being hollow to provide a flow path for the gas discharged from the compressor; and

FIG. 4 is an elevational cross-sectional view of a combination liquid pump/gas compressor similar to the previous FIGS., and particularly of FIG. 1, but including an optional gearbox positioned between the liquid pump and gas compressor to facilitate operation of each unit at respectively different speeds.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

One preferred embodiment of the present invention is illustrated in FIG. 1, which is an elevational view, partially in cross-section, of a combination liquid pump/gas compressor 10 shown downhole in a vertical orientation. A typical portion of a well 12 contains a liquid/gas mixture 14, and is provided with a suitable casing sleeve 16 which extends downhole to where the liquid/gas mixture 14 exists.
Downstream of the liquid/gas supply is liquid/gas separator 18, which is shown schematically in FIG. 1, and which may be any one of several known types of separators, such as those which utilize gravity, shrouds, centrifugal or rotary gas separation, or gas-liquid cylindrical cyclonic, in-line separation technology, or the like.
Downstream of separator 18 is drive motor 20, encased in cooling jacket 22. The motor 20 can be powered from the surface by known means, including electric power or the like delivered to drive motor 20 by power cable 24. Production fluids are directed to cooling jacket 22 from separator 18 via feed line 19 if needed.
In FIG. 1, seal 26 provides an interface between drive motor 20 and liquid pump 28, which is supplied with liquid medium separated by separator 18 from the liquid/gas mixture 14, and is directed via liquid feed line 30 to pump intake 27, and then to liquid pump 32. Gas feed line 34 directs gas separated by separator 18 from the liquid/gas mixture 14 directly to compressor intake 36, and then to gas compressor 38, as shown. Both feed lines 30 & 34 are optional.
The drive shaft 40 of the drive motor 20 extends through, and drives both the liquid pump and the gas compressor, as will be shown and described in the description which follows.
The portion 40A of shaft 40 is associated with liquid pump 28, and the portion 40B of shaft 40 is associated with compressor 38. The shaft 40 is commonly driven in its entirety by motor 22.
In FIG. 1, the portion 40A of the shaft 40 associated with liquid pump 28 is solid as shown, and the portion 40B associated with gas compressor 38 is hollow to receive the flow of the liquid discharged from the pump 28 so as to provide cooling to the gas compressor 38. This cooling effect enhances compressor efficiency and reduces the horsepower requirement for operating the compressor. The flow of gas 37 from the gas compressor 38 is discharged into the outlet tube 42, where it may be combined with the liquid component as shown. As can be seen, outlet tubing 42 is surrounded by deep packer 41 positioned within the annulus 43 formed by outlet tube 42 and casing 16. In particular, FIG. 1 shows how the present invention can be effectively deployed downhole to provide artificial lift.
In FIG. 1, liquid pump blades 44 and gas compressor blades 46 are shown in a single stage format for illustration purposes. In practice, such blades may be provided in multiple stages, sometimes numbering in tens of hundreds of such stages of blades.
Referring now to FIG. 2, an enlarged elevational cross-sectional view of the liquid pump 28 and gas compressor 38 of FIG. 1 is shown, in a horizontal orientation.
Separator 18 is shown schematically in FIG. 2, but can be of any desired type as noted previously, i.e., cylindrical cyclonic, gravity, in-line, or the like. Motor 20 is shown in schematic format in FIG. 2, and is arranged to drive the common shaft 40, comprised in part of liquid pump portion 40A and gas compressor portion 40B, similar to the arrangement shown in FIG. 1.
After the separation process which takes place at separator 18, the liquid dominant stream 48 is directed via liquid feed line 30 to pump intake 27 of liquid pump 28 as shown, and then directed from liquid pump 28 to the hollow portion 40B of shaft 40 associated with gas compressor 38.
The gas dominant stream 50 is in turn directed from separator 18 via gas feed line 34 directly to compressor intake 36 and then to gas compressor 38, where it is compressed, pumped and directed to outlet tube 42 to be combined with the liquid dominant stream flowing through the hollow shaft portion 40B of gas compressor 38.
In FIGS. 1 and 2, liquid feed line 30 and gas feed line 34 are shown schematically, but can be representative of any known system to convey the respective dominant liquid or dominant gas medium from one place to another. As will be seen, the dominant liquid medium and dominant gas medium may be transferred from place to place to facilitate better heat transfer between the components of the system.
Referring now to FIG. 3, there is shown an enlarged elevational cross-sectional view of an alternative embodiment 51 of the liquid pump/gas compressor arrangement of FIGS. 1 and 2, with the respective positions of the gas compressor 52 and the liquid pump 54 in respectively reversed positions and configurations. Liquid pump blades 31 and gas compressor blades 33 are shown.
In FIG. 3, motor 56 is shown schematically to rotatably operate the drive shaft 58 which is common to both gas compressor 52 and liquid pump 54. In this embodiment the shaft portion 58A associated with gas compressor 52 is solid, and gas is pumped through the gas compressor 52 in the annular zone surrounding the solid shaft portion 58A. The gas dominant stream 61 is directed from separator 60 via gas feed line 62 shown schematically, to compressor intake 64, and then to gas compressor 52.
The liquid dominant stream 69 from separator 60 is directed via liquid feed line 66 to liquid pump intake 68, and then to liquid pump 54 where it is pumped as liquid dominant stream 69 toward outlet tube 65 to be recombined with the gas dominant stream 61 from hollow shaft portion 58B associated with liquid pump 54. It can be seen that the simultaneous flow of gas dominant stream 61 through hollow shaft portion 58B and the liquid dominant stream 69 through liquid pump 54 provides a stabilizing heat exchange between the various components, which are commonly driven by a single motor 56. This feature significantly improves the efficiency of all working components. The respective streams are combined in outlet tube 65 in FIG. 3.
As noted previously, the pump and compressor systems shown in the FIGS. respectively depict a single stage of blades, for convenience of illustration. In reality, the pump and compressor systems according to the invention incorporate multiple stages of such blade systems, occasionally numbering tens of hundreds of blade stages, sometimes including an impeller and diffuser.
Referring now to FIG. 4, there is shown an alternative embodiment 71 similar to the structural arrangement of FIG. 1, with the addition of gearbox 70 positioned between liquid pump 28 and gas compressor 38 to facilitate operation of each component at respectively different speeds so as to accommodate specific conditions for any specific environment, such as well conditions, fluid viscosity and other flow conditions.
In all other respects, the structural and functional arrangement in FIG. 4 is the same as the arrangement shown in FIG. 1.
While the invention has been described in conjunction with several embodiments, it is to be understood that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, this invention is intended to embrace all such alternatives, modifications and variations which fall within the spirit and scope of the appended claims.

LIST OF NUMERALS

- 10 Combination Liquid Pump/Gas Compressor
- 12 Well
- 14 Liquid/Gas Mixture
- 16 Casing Sleeve
- 18 Liquid/Gas Separator
- 19 Feed Line
- 20 Drive Motor
- 22 Cooling Jacket
- 24 Power Cable
- 26 Seal
- 27 Liquid Pump Intake
- 28 Liquid Pump
- 30 Liquid Feed Line
- 31 Liquid Pump Blades
- 32 Liquid Pump
- 33 Gas Compressor Blades
- 34 Gas Feed Line
- 36 Compressor Intake
- 37 Flow of Gas from Compressor 38
- 38 Gas Compressor
- 40 Drive Shaft
- 40A Liquid Pump Portion of Drive Shaft

LIST OF NUMERALS

- 40B Hollow Shaft Portion
- 41 Deep Packer
- 42 Outlet Tube
- 43 Annulus
- 44 Liquid Pump Blades
- 45 Flow of Liquid from Pump 28
- 46 Gas Compressor Blades
- 48 Liquid Dominant Stream
- 50 Gas Dominant Stream
- 51 Alternative Embodiment
- 52 Gas Compressor
- 54 Liquid Pump
- 56 Motor
- 58 Drive Shaft
- 58A Solid Shaft Portion of Compressor
- 58B Hollow Shaft Portion of Compressor
- 60 Separator
- 61 Gas Dominant Stream, FIG. 3
- 62 Gas Feed Line
- 64 Compressor Intake
- 65 Outlet Tube
- 66 Liquid Feed Line

LIST OF NUMERALS

- 68 Liquid Pump Intake
- 69 Liquid Dominant Stream, FIG. 3
- 70 Gearbox
- 71 Alternative Embodiment

Claims

1-13. (canceled)

14. A method comprising:

driving, by a first pumping device, a first phase-dominant stream in a direction;

while driving the first phase-dominant stream, driving, by a second pumping device, a second phase-dominant stream in the direction; and

flowing the first phase-dominant stream driven by the first pumping device through the second pumping device to cool the first pumping device.

15. The method of claim 14, further comprising simultaneously driving, by a common power source, the first pumping device and the second pumping device.

16. The method of claim 14, wherein the first single phase-dominant stream and the second single phase-dominant stream flow together in a multiphase fluid towards the first pumping device and the second pumping device, and wherein the method further comprises separating the multiphase fluid into the first single phase-dominant stream and the second single phase-dominant stream.

17. The method of claim 14, further comprising combining the first phase-dominant stream driven by the first pumping device and the second phase-dominant stream driven by the second pumping device.

18. The method of claim 14, wherein the first single phase-dominant stream is a gas phase-dominant stream, wherein the first pumping device comprises a gas compressor.

19. The system of claim 18, wherein the second single phase-dominant stream is a liquid phase-dominant stream, wherein the second pumping device comprises a liquid pump.

20. The method of claim 14, wherein the first single phase-dominant stream is a liquid phase-dominant stream, wherein the first pumping device comprises a liquid pump.

21. The method of claim 20, wherein the second single phase-dominant stream is a gas phase-dominant stream, wherein the second pumping device comprises a gas compressor.