Wells – Processes – Producing the well
Reexamination Certificate
2002-08-08
2004-03-16
Tsay, Frank (Department: 3672)
Wells
Processes
Producing the well
C166S105000
Reexamination Certificate
active
06705403
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to pumping equipment. More particularly, the invention relates to, in one embodiment, a production system for producing fluids from a well that includes a jet pump and a submersible pump.
2. Description of the Related Art
The information described below is not admitted to be prior art by virtue of its inclusion in this Background section.
As the technology for offshore deep-water exploitation becomes available at a reasonable cost, the number of sub-sea completions in deep and ultra-deep waters is expected to increase significantly. Evidence of this expected increase in deep-water production may be seen in the large number of tracts in water deeper than 5000 feet that were leased in the recently completed Gulf of Mexico Outer Continental Shelf (OCS) lease sales.
FIG. 1
presents the evolution of the tracts receiving bids in the recent lease sales and clearly emphasizes the expectations of the oil companies. (The asterisk in
FIG. 1
denotes years in which a royalty relief program was in effect.)
FIG. 2
presents a bar graph that shows the increasing production (expressed in % increase by year) from the deep and ultra-deep waters in the Gulf of Mexico. Other important evidence of increased deep-water production may be seen in the increasing activity of Petrobras. The Brazilian Petroleum Company started the exploitation of the Campos Basin offshore Rio de Janeiro, Brazil, in 1979 at water depths of 300 feet, and since then has worked continuously towards deeper waters where some important discoveries have been made. Today, high productivity wells have been producing steadily and successfully at water depths greater than 5000 feet in the Marlin and Albacore fields.
Production platforms are typically installed when producing from offshore wells. While the installation of a production platform in deep water is sometimes technically feasible, such an installation is more complicated, and thus more expensive, than installing a production platform in shallower water.
Consequently, the host production platforms in offshore petroleum production projects are usually installed in shallow water, which often requires a long flowline between the platform and the deep wells. With the wells located far from the host platform, the wellhead flowing pressures generally have to be maintained at a level sufficient to overcome high frictional losses plus the hydraulic head for the produced fluids to be able to flow back to the platform. The high wellhead pressure required to flow production back to the host platform will in turn tend to limit a pressure differential (or drawdown) that may be established at the reservoir. As a result, the production rates of the deep wells may be reduced to uneconomic levels.
A possible solution to the problem created by the installation of the host platform far from the production wells is the application of existing artificial-lift (AL) methods. AL methods supply the fluids produced from the well with sufficient energy to generate adequate drawdown at the formation while maintaining a high enough wellhead pressure to transport the fluids to the host platform at a desired flow rate. The AL method most commonly used for sub-sea offshore petroleum production is the gas lift (GL). A purpose of the GL method is to inject gas into the tubing string downhole in order to reduce the hydraulic head without increasing the friction losses so that the net result is an increase in the wellhead pressure for a fixed bottomhole pressure.
While the increase in the gas-liquid ratio (GLR) obtained with the GL method is highly beneficial for vertical multiphase flow, such an increase is not as helpful for horizontal flow. For long-distance horizontal multiphase flow, the net result of the increase in the GLR may be detrimental since the friction loss increases and there is little or no reduction in the hydraulic head. In addition, the increased GLR will create an operational problem with long-distance horizontal flow due to the instability of the slug flow that is expected to occur. Another problem with the GL method is that it requires an annulus lift-gas line, which for long distances will significantly increase the final cost of the project.
Pumping AL methods are also available for sub-sea applications. Such methods include the electrical submersible pump (ESP), the Progressing Cavity Pump (PCP), and the Jet Pump (JP). Present technology applies ESP's for pumping of liquid with small amounts of free gas (up to about 5% or so) while JP's are used to pump liquids using a liquid power fluid. An ESP typically includes a multistage centrifugal pump driven by a coupled electric motor. The pump may be installed inside the well at the end of the tubing string, and is typically situated at a certain depth below the fluid level. An electric cable connecting the surface transformer to the electric motor feeds electric power.
The JP is an AL method with no moving parts. The JP, which primarily consists of a body with a nozzle, a throat, and a diffuser, is set in a nipple inside the tubing string. Substantially clean power fluid is pumped down from the surface to the pump through the tubing. This power fluid passes through the nozzle, creating a low-pressure region connected to the pump intake so that the well fluid is suctioned into the throat region of the JP. The mixed fluid, i.e., power fluid plus produced fluids, exits the pump through the diffuser into the casing with sufficient head to overcome the hydraulic head plus the head losses.
To date, the majority of the pumping AL systems are being operated at conditions where there is a minimum of free gas present at the pump intake. As may be learned from Ref. 1 to Ref. 6, that free gas is, in many instances, detrimental to proper operation of these pumps. Consequently, it is not recommended to apply these systems without some provision for separation of the gas before reaching the pump intake. A requirement for the application of AL methods to sub-sea petroleum production is the necessity to operate relatively efficiently with a multiphase gas-liquid mixture because it is not desired, for economic reasons, to have an extra produced-gas flowline for each well. Without the annulus flowline, it is generally not possible to utilize the annular space as a downhole separator and to vent the gas at the casinghead.
The application of an ESP to a well having a high free-gas volume at the pump intake usually requires the installation of a gas separator. The use of a gas separator, however, may require the costly installation of an extra flow line to vent the separated gas to the host platform. Therefore, it would be desirable, in some embodiments, to design a production system that would allow an ESP to be used in a high free-gas well without requiring the installation of a vent line.
SUMMARY
A production system may include a submersible pump and a jet pump. The submersible pump may be arranged within the well. The jet pump may be arranged within the well downstream of the submersible pump. The jet pump may include a power fluid intake configured to receive a power fluid and a produced fluid intake configured to receive a produced fluid. The power fluid intake may be in fluid communication with the submersible pump. The produced fluid intake may be in fluid communication with gas within the well. In an embodiment, the produced fluid intake may be in fluid communication with separated gas within an annulus of the well. The system may allow, among other things, a submersible pump (possibly an ESP) to be used in high GLR wells without installing a gas vent line.
In an embodiment, the jet pump may be positioned at the discharge of the submersible pump, and may use the fluid pumped by the submersible pump as a power fluid. In addition, a gas separator may be positioned upstream of the submersible pump. The gas separator may be configured to separate gas from liquid to produce separated gas and separated liquid. The separated liquid may be drawn into the submers
Carvalho Paulo M.
Podio Augusto L.
Sepehrnoori Kamy
Howrey Simon Arnold & White , LLP
The Board of Regents The University of Texas System
Tsay Frank
LandOfFree
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