This invention relates in general to liquid hydrocarbon lift systems and, in particular, to a modular subsurface lift engine adapted to directly or indirectly lift liquid hydrocarbons from a cased wellbore.
Liquid hydrocarbon lift systems are well known and widely used to produce fluids from cased wellbores that lack sufficient natural well pressure to produce the fluids without a mechanical lift system. The most commonly used mechanical lift systems are downhole pumps, which include sucker rod pumps that connect to a bottom end of a production tubing, and insert pumps that are inserted into a bottom end of a production tubing string. The sucker rod pumps and the insert pumps are both driven by a “sucker rod string”, which is a jointed slim rod string that reciprocates inside the production tubing string and connects the pump to a surface drive system. The surface drive system is typically a pumpjack, sometimes referred to as a “nodding donkey” or a “rocking horse”. While such systems are both useful and reliable, they require a considerable amount of material to construct, require a complex drive system, and can be expensive to maintain. Furthermore, in highly deviated wells sucker rod strings tend to fail due to excessive wear in the curved sections of the wellbore. As well, downhole pumps have to be located above the kickoff point in horizontal well bores to prevent premature sucker rod failure and to keep the pumps in an upright orientation in which they function optimally.
There therefore exists a need for a novel cased wellbore lift system that overcomes many of the issues associated with prior art pumpjacks and associated surface and subsurface pumping equipment.
It is therefore an object of the invention to provide a modular subsurface lift engine adapted to be used to produce fluids from a cased wellbore.
The invention therefore provides a modular subsurface lift engine, comprising: an upper valve housing with an upper valve seat and an upper valve for controlling a flow of produced fluid hydrocarbons through the subsurface lift engine during a down-stroke thereof; an upper crossover sleeve connected to a bottom end of the upper valve housing; an upper transition sleeve connected to a bottom end of the upper crossover sleeve; an upper crossover tube connected to an upper travel limiter that reciprocates within the upper transition sleeve, the upper crossover tube extending through a central passage in a bottom of the upper transition sleeve; at least one subsurface lift engine module connected to a bottom end of the upper transition sleeve, respectively comprising a modular cylinder sleeve, a modular cylinder piston that reciprocates within the modular cylinder sleeve, and a modular cylinder tube connected to a lower side of the modular cylinder piston and extending through a passage in a modular cylinder sleeve bottom wall of the modular cylinder sleeve; and a lower crossover sleeve adapted to connect to a production packer that isolates an annulus of the cased well bore surrounding the modular subsurface lift engine from an annulus of a cased hydrocarbon well below the production packer.
The invention further provides a modular subsurface lift engine, comprising: an upper valve housing adapted to connect to a production tubing supported by a wellhead of a cased well bore, the upper valve housing having an upper valve seat and an upper valve for controlling a flow of produced fluid through the subsurface lift engine during a down-stroke thereof; an upper crossover sleeve connected to a bottom end of the upper valve housing; an upper transition sleeve connected to a bottom end of the upper crossover sleeve, the upper transition sleeve having an upper crossover tube that is connected to a bottom of a transition travel limiter, the crossover sleeve extending through a central passage in a bottom of the upper transition sleeve; at least one subsurface lift engine module connected to a bottom end of the upper transition sleeve and comprising a modular cylinder sleeve, a modular cylinder piston that reciprocates within the modular cylinder sleeve, and a modular cylinder tube connected to a lower side of the modular cylinder piston and extending through a passage in a modular cylinder sleeve bottom wall of the modular cylinder sleeve; and a lower crossover sleeve having a lower valve housing with a lower valve seat and a lower valve for controlling a flow of produced fluids through the subsurface lift engine during an up-stroke thereof, the lower crossover sleeve being adapted to connect to a production packer that isolates an annulus of the cased well bore surrounding the modular subsurface lift engine from an annulus of the cased well bore below the production packer.
The invention yet further provides a modular subsurface lift engine, comprising: at least one subsurface lift engine module adapted to be connected end-to-end to other subsurface lift engine modules, each subsurface lift engine module comprising: a modular cylinder sleeve having an open top end, a cylinder sleeve bottom wall with a central passage therein, and at least two cylinder sleeve ports adjacent the cylinder sleeve bottom wall to provide fluid communication through the modular cylinder sleeve with a modular cylinder lift chamber; a modular cylinder piston with a modular piston seal that provides a high-pressure fluid seal between an inner wall of the modular cylinder sleeve and the modular cylinder piston, the modular cylinder piston having an upper travel limiter and a lower travel limiter to limit travel of the modular cylinder piston in the modular cylinder sleeve; a modular cylinder tube connected to the bottom travel limiter of the modular cylinder piston and extending through a high pressure fluid seal in the central passage in the modular cylinder bottom wall, the modular cylinder tube having at least two modular cylinder tube ports that provide fluid communication through a sidewall of the modular cylinder tube with a modular cylinder pump chamber above the modular cylinder piston in an adjacent lower modular cylinder sleeve; an upper valve housing adapted to connect a production tubing supported by a wellhead of a cased well bore, the upper valve housing having an upper valve seat and an upper valve for controlling a flow of produced fluids through the subsurface lift engine during a down-stroke thereof; an upper crossover sleeve connected to a bottom end of the upper valve housing; an upper transition sleeve connected to a bottom end of the upper crossover sleeve, the upper transition sleeve having a bottom end connected to the at least one lift engine module, and further having an upper crossover tube that is connected to a bottom end of an upper transition travel limiter that reciprocates within the upper transition sleeve, the upper crossover tube extending through a central passage in a bottom of the upper transition sleeve; and a lower crossover sleeve having a lower valve housing with a lower valve seat and a lower valve for controlling a flow of produced fluid hydrocarbons through the subsurface lift engine during an up-stroke thereof, the lower crossover sleeve being adapted to connect to a production packer that isolates the subsurface lift engine from an annulus of the cased well bore below it, the production packer supporting a production tubing that extends downwardly through the cased hydrocarbon well to fluids in the cased well bore.
Having thus generally described the nature of the invention, reference will now be made to the accompanying drawings, in which:
The invention provides a modular subsurface lift engine adapted to directly or indirectly produce fluids from a cased wellbore. Subsurface lift engine modules are respectively connected end-to-end to provide a lift capacity required to lift the fluids from the cased wellbore. The number of lift engine modules required for a particular installation depends on any one or more of several factors. In the case of directly lifting the fluid from the wellbore, those factors may include: a viscosity of the fluids; a vertical lift requirement; a diameter of the wellbore production casing; a diameter of the wellbore production tubing; and, a desired rate of production. In the case of indirectly lifting the fluids from the cased wellbore, the subsurface lift engine may be connected to a downhole reciprocal pump, such as a tubing pump or an insert pump, using a subsurface sucker rod string and the factors determining the number of lift engine modules may include: a viscosity of the fluids; a vertical lift requirement; a diameter of the wellbore production casing; a diameter of the wellbore production tubing; a desired rate of production; a weight of the sucker rod string; and, power requirements of the driven pump.
In the embodiment of the modular lift engine used to directly lift liquid hydrocarbons from a wellbore, an upper valve housing connects the interconnected lift engine modules to a production tubing joint suspended from a production wellhead. An upper valve is housed in the upper valve housing. The upper valve may be any one of a ball valve, a check valve or a flapper valve. The upper valve prevents the backflow of lifted fluids during a downstroke of the lift engine. The upper valve housing is mounted to a top of an upper crossover sleeve. In one embodiment the upper crossover sleeve is elongated and a downstroke spring is inserted between a top end of the upper crossover sleeve and an upper transition travel limiter. The downstroke spring constantly urges the modular subsurface lift engine to a bottom-of-stroke condition to provide a positive downstroke when the modular subsurface lift engine is installed in a highly deviated wellbore, a horizontal wellbore, is used to produce very viscous fluid, or is used to provide a very long vertical lift. An upper transition sleeve connected to a bottom of the upper crossover sleeve supports the interconnected lift engine modules.
A lower crossover sleeve connects the interconnected lift engine modules to a production packer that isolates the modular subsurface lift engine from the cased wellbore below the production packer. A production tubing string is connected to a lower end of the production packer. The production tubing string extends down through the cased wellbore to the fluids to be produced from the cased well bore.
Each lift engine module includes a modular cylinder sleeve having an open top end and a modular cylinder sleeve bottom wall that connects the modular cylinder sleeve to a lift engine module below it. Each modular cylinder sleeve bottom wall has a central opening that accommodates a modular cylinder tube. A lower end of each modular cylinder sleeve includes at least two modular cylinder sleeve ports that provide fluid communication between an annulus of the cased well bore and a lift chamber of the modular cylinder sleeve. Each modular cylinder sleeve houses a modular cylinder piston having a piston seal that provides a high pressure fluid seal between the modular cylinder piston and an inner wall of the modular cylinder sleeve. Each modular cylinder piston has a top travel limiter that limits piston travel during an up-stroke of the subsurface lift engine. Each modular cylinder piston also has a bottom travel limiter that limits the piston travel during a down-stroke of the cylinder piston. The bottom travel limiter prevents the cylinder piston from occluding the modular cylinder sleeve ports at the bottom of a down-stroke of the subsurface lift engine. A modular cylinder tube is threadedly connected to a lower end of each piston lower travel limiter and a top end of a piston upper travel limiter of an adjacent lower module. The modular cylinder tubes provide an uninterrupted fluid path through the interconnected cylinder modules. Each modular cylinder tube has at least two modular cylinder tube ports that provide fluid communication with a modular cylinder pump chamber above the modular cylinder piston of each subsurface lift engine module. The piston upper travel limiters prevent the modular cylinder tube ports from reaching a high-pressure fluid seal in the bottom wall of an adjacent lift engine module above it.
The lower crossover sleeve includes a lower valve housing with a lower valve seat and a lower valve that controls fluid flow through the subsurface lift engine modules during an up-stroke of the subsurface lift engine. The lower valve may be any one of a ball valve, a check valve or a flapper valve.
The subsurface lift engine is driven by surface equipment assembled using components well known in the art. In one embodiment a high-pressure fluid pump pumps a lift fluid from a lift fluid reservoir. The lift fluid may be any stable, non-corrosive fluid such as, for example, corrosion inhibited water or a light oil such as diesel fuel, kerosene, hydraulic fluid, or the like. Lift fluid is supplied to the high-pressure pump through a lift fluid supply line. Lift fluid exits the high-pressure fluid pump via a pump pressure line to a pump pressure valve, for example a solenoid-controlled valve, that selectively routes the lift fluid thorough the lift fluid pressure line to the annulus of the hydrocarbon well isolated by the production packer, or to a lift fluid pressure bypass line connected to the lift fluid reservoir. The annulus of the hydrocarbon well is also connected to a lift fluid dump line, which is in turn connected to the lift fluid reservoir. A dump fluid valve controls flow through the lift fluid dump line.
In operation, the high-pressure pump continuously pumps the lift fluid at a predetermined pump rate. During an upstroke of the subsurface lift engine, the solenoid-controlled valve in the lift fluid pressure line is open and the lift fluid dump valve in the lift fluid dump line is closed. The lift fluid therefore flows into the isolated annulus of the hydrocarbon well and through the modular cylinder sleeve ports into the respective modular cylinder lift chambers, urging the respective modular cylinder pistons upwardly. The upward movement of the modular cylinder pistons forces produced fluid out of the modular cylinder produced fluid chambers through the modular cylinder tube ports, up through the respective modular cylinder tubes to the production tubing in the wellhead, and out through a hydrocarbon production pipe to a hydrocarbon production reservoir, which may be a tank, a pipeline, or the like. When the modular cylinder piston upper travel limiters contact the modular cylinder bottom wall of an adjacent lift engine module, a pressure spike occurs in the lift fluid. The pressure spike is sensed by a pressure sensor that trips the lift fluid dump valve to open the lift fluid dump line and simultaneously trips the pump pressure line control valve to shift to reroute the lift fluid through the lift fluid bypass line to the lift fluid reservoir. These valve movements drain lift fluid pressure from the subsurface lift engine and the annulus of the wellbore, and the subsurface lift engine down-strokes under its own weight and, in one embodiment, the pressure of the downstroke spring. The down-stroke closes the upper valve and opens the lower valve as the modular cylinder pistons downward movements create suction in the respective modular cylinder produced fluid chambers, which sucks produced fluid up into the respective modular cylinder produced fluid chambers. When the pressure sensor senses an absence of fluid pressure in the dump fluid line, the lift fluid dump valve is closed and the lift fluid bypass valve is shifted to reroute the lift fluid from the lift fluid bypass line to the lift fluid pressure line and another up-stroke commences. During the up-stroke, the subsurface lift engine lower valve is closed and the subsurface lift engine upper valve opens as the produced fluids flow from the modular cylinder produced fluid chambers to the hydrocarbon reservoir, as described above.
108a-b
114a-b
Connected to a bottom end of the upper transition sleeve 20 is a first subsurface lift engine module 32a. Each subsurface lift engine module 32a-32d includes a modular cylinder sleeve 34a-34d, which has a modular cylinder sleeve bottom wall 35a-35d. Just above the modular cylinder sleeve bottom wall are a plurality of modular cylinder sleeve ports 36a-36h, only two of which are shown in each modular cylinder sleeve 34a-34d. The function of the modular cylinder sleeve ports 36a-36h be explained below with reference to
A respective modular cylinder tube 46b-46d interconnects a respective piston lower travel limiter 44a-44d to a respective piston upper travel limiter 42a-42d. A respective modular cylinder tube upper seal 50a-50e provides a high-pressure fluid seal around a top end of the respective modular cylinder tubes 46a-46d where they pass through the respective modular cylinder sleeve bottom walls 35a-35d. A respective modular cylinder tube lower seal 52a-52d provides a high-pressure fluid seal around a bottom end of the respective modular cylinder tubes 46a-46d where they connect to the respective modular cylinder pistons 38a-38d.
A lower crossover sleeve 54 is connected to a lowest subsurface lift engine module, 32d in this example. A bottom end of the lower crossover sleeve 54 is connected to the production packer 66. The lower crossover sleeve 54 houses a lower valve housing 56, which reciprocates within the lower crossover sleeve 54. The lower valve housing 56 has a lower valve seat 58 and a lower valve seat seal cap 60. The lower valve seat cap 60 is connected to a lower crossover tube 55 having a top end connected to the piston lower travel limiter 44d. The lower valve seat 58 supports a lower valve fluid seal 62 that provides a high-pressure fluid seal between the lower valve housing 56 and the lower crossover sleeve 54. A lower valve, in this example lower ball valve 64 is received in the lower valve seat 58. A lower valve limiter 65 limits an upward travel of the lower ball valve 64 during a downstroke of the modular lift engine 10.
In use, the modular subsurface lift engine 10a operates as described above with reference to
The explicit embodiments of the invention described above have been presented by way of example only. The scope of the invention is therefore intended to be limited solely by the scope of the appended claims.
Applicant claims the benefit to priority under 35 U.S.C. § 119(e) of provisional patent application 62/610,323, filed on Dec. 26, 2017.
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Number | Date | Country | |
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20190195059 A1 | Jun 2019 | US |
Number | Date | Country | |
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62610323 | Dec 2017 | US |